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Departments of Petroleum and Mechanical Engineering
Separation Technology Projects(TUSTP)
JIP onDesign and Performance of
Compact Separators forMultiphase Production Systems
18th Advisory Board MeetingMay 20, 2003
TABLE OF CONTENTS
Page
Introductory Remarks (Shoham) 1-1
New DOE and NSF Proposals (Mohan) 2-1
DOE Project: Design and Performance of Multiphase Distribution Manifold (Bustamante) 3-1
DOE Project: StarCut Differential Dielectric Sensor–Experiments and Modeling (Xiang) 4-1
DOE Project: Horizontal Pipe Separator (HPS�) (Perez) 5-1
Foam Flow in GLCC� (Guzman) 6-1
DOE Project: Modeling Slug Dissipation in Helical Pipes (Di Matteo) 7-1
TU CoRE Project: Dispersion Characterization Rig (DCR) (Gomez) 8-1
Event Simulation and Diagnostics of GLCC Multiphase Metering System (Kumar) 9-1
Mechanistic Modeling and CFD Simulations of Oil-Water Dispersions
in Separation and Piping Components (Torres) 10-1
PhD Proposal: Intelligent Control of Compact Separation System (Sampath) 11-1
PhD Proposal: Interfacial Phenomena in Oil-Water Dispersions (Avila) 12-1
Evaluation of Oil-Water Flow through Different Piping Restrictions (Kuantaev) 13-1
APPENDICES
APPENDIX A: TUSTP Advisory Board Members
APPENDIX B: TUSTP Library
APPENDIX C: New DOE Proposal - Executive Summary
APPENDIX D: New NSF I/UCRC Proposal Summary
1 - 1
Departments of Petroleum and Mechanical Engineering
Separation Technology Projects(TUSTP)
JIP onDesign and Performance of
Compact Separators forMultiphase Production Systems
18th Advisory Board MeetingMay 19 and 20, 2003
Departments of Petroleum and Mechanical Engineering
Separation Technology Projects(TUSTP)
1 - 2
� Research Scope• oil/water/gas three-phase separation • suite of different compact separation units• compact separation systems• control strategies• flow conditioning• hydrodynamics of oil-water dispersion• dispersion and foam characterization
� Funding:• Additional DOE, NSF, TU-CoRE and OCAST
� Facilities:• Oil/water/gas state-of-the-art indoor facility• Gas/liquid outdoor facility • Dispersion Characterization Rig (DCR)• 12 different test sections
� Outdoor: Hydrodynamic GLCC�; Control GLCC�; Helical Pipe; Slug Damper
� Indoor: LLCC�; GLCC�; LLHC; HPS�; Distribution Manifold; Coalescing Components; Droplet Formation;Starcut Loop
TUSTP
� Personnel Development:• 26 students graduated (6 PhD and 20 MS)• 2 visiting assistant professors/research associates• Currently: 11 graduate and 5 undergraduate
students• Consulting company established (MSI)
� Important Deliverables:• GLCC, LLHC, LLCC, and Slug Damper codes• “Sizing and performance predictions are at levels
unsurpassed by any other separation technology”� Technology Transfer and Field Applications:
• About 500 GLCC applications in the field. • GLCC has gone from “Technology of Last Resort”
to “Technology of First Choice” • Technology poised for exponential growth
� Academics:
• Total 46 papers, 23 in refereed journals
• GLCC introduced in undergraduate curriculum• Compact Separation Course will be offered in
Fall 2003 by Dr. Wang at graduate level
TUSTP
1 - 3
TUSTP Activities
� TUSTP Activities:
� Slug Damper vx 1.0 code released today
� GLCC vx7.6 code released today
� Two Emulsion Short Courses scheduled for industry:- Drs. Jean Louis Salager and Johan Sjoblom
� “Dispersion Characterization Rig” (DCR) ordered following funding approval from ChevronTexaco TU-CoRE
� GLCC skid from Humble being shipped to TUSTP
� NSF-I/UCRC (Pre-proposal) funded, DOE andNSF-I/UCRC (Full) proposals submitted
� Dr. R. Mohan on sabbatical in 2003; Received 2003 College of E&NS outstanding researcher award
� TUSTP received Best Paper award in the DeepwaterChallenge Session of the 5th International PetroleumConference and Exhibition (Petrotech, India, 2003)
� Drs. O. Shoham and R. Mohan visited Shell (Holland) in January 2003 for GLCC� workshop
� 12:00 Lunch
� 1:00 Business Meeting
� 3:30 Tour of Facilities
� 6:30 TUSTP Reception/Dinner
Agenda, 5/19/2003
1 - 4
� 8:00 Continental Breakfast
� 8:30 Introductory Remarks (Shoham)
� 8:55 New DOE and NSF Proposals (Mohan)
� 9:20 Multiphase Distribution Manifold (Bustamante)
� 10:00 Starcut Differential Dielectric Sensor (Xiang)
� 10:25 Coffee Break
� 10:40 Horizontal Pipe Separator (HPS�) (Perez)
� 11:05 Foam Flow in GLCC� (Guzman)
� 11:30 Slug Dissipation in Helical Pipes (Di Matteo)
� 12:00 Luncheon
Agenda, 5/20/2003
� 1:15 Dispersion Characterization Rig (DCR) (Gomez)
� 1:40 Diagnostics of GLCC� Metering System (Kumar)
� 2:05 Modeling and CFD of Oil-Water Dispersions in Separation and Piping Components (Torres)
� 2:30 PhD Proposal: Intelligent Control of CompactSeparation Systems (Sampath)
� 2:45 Coffee Break
� 3:00 PhD Proposal: Characterization of Interfacial Phenomena in Oil-Water Dispersions (Avila)
� 3:15 Oil-Water Flow in Piping Restrictions (Kuantaev)
� 3:40 Industry Presentations
� 5:00 ADJOURN
Agenda, 5/20/2003
1 - 5
Research Team
� Faculty:� Ovadia Shoham, Petroleum Eng.� Ram Mohan, Mechanical Eng.� Shoubo Wang, Petroleum Eng.� Luis Gomez, Petroleum Eng.
� Graduate Students:� Carlos Avila (PhD PE)� Angel Bustamante (MS ME)� Carlos Di Matteo (MS PE)� Nólides Guzman (PhD PE)� Vinod Kumar (MS ME)� Erzhan Kuantaev (MS PE)� Ciro Perez (PhD PE)� Vasudevan Sampath (PhD ME)� Jose Severino (MS PE)� Carlos Torres (PhD ME)� Dong Xiang (PhD ME)
� Undergraduate Students:� Claudio Antonio� Henda Valerio� Chad Trainer� Rebbeca Lederman� Staci Morgan
Research Team� Future Students:
� Yordanka Gomez� Carolina Vielma� Eduardo Pereyra
� Graduated since November 2002:� Marcos Barboza (MS PE)� Robiro Molina (MS PE)� Carlos Avila (MS PE)� Vasudevan Sampath (MS ME)
� Administrative Assistant:Judy TealOffice: M-F 8:00 am - 4:30 pmTel: (918) 631-2048e-mail: [email protected]
1 - 6
Membership
ChevronTexaco NATCO
Ecopetrol ONGC*
Emerson PDVSA
eProduction Sol. PEMEX*
ExxonMobil SMS
MSI TotalFinaElf
DOE TUCoRE NSF
Membership
�Potential Member Companies:� Shell� Kvaerner� ABB� NorskHydro� Tru-Tec� Accuflow
� Past Member Companies:• Agar• Conoco• JGC• Jiskoot• Krebs • Petrobras• Phillips• Shell• BP/Amoco/Arco• Unocal• Westinghouse• Schlumberger• MPM
1 - 7
� Income:� 12 Companies @ $15,000 $ 180,000� In-kind Contribution (1) - $ 15,000� Initiation Fee (1) $ 25,000
TOTAL $ 190,000
� DOE $ 0
� TU-CoRE $ 256,500
� NSF $ 10,000
TOTAL INCOME $ 456,500
Budget, 9th year(2002/2003)
Budget (Cont’d)(2002/2003)
� Expenditure:� 90101 PI salary $ 19,500� 90102 Co-PI salary $ 11,400� 90104 Research Assoc. (2@50%) $ 36,000� 90700 Non-Professional $ 7,000� 91000 Graduate students (1) $ 16,200� 91100 Undergraduate students $ 0� 93101 Research Supplies $ 5,000� 93104 Software $ 0� 93201 Mail $ 2,300� 93300 Printing&Duplication $ 1,500� 93400 Telecommunication $ 1,500� 93501 Membership $ 150� 93602 Travel $ 3,000� 93700 Entertainment $ 7,000� 94100 Tuition – Students $ 0� 99002 Computers $ 0� 94803 Consultants $ 3,500� 94813 Outside Services $ 7,000� 91800 Fringe benefit (31%) $ 22,909� 95200 Indirect cost (51%) $ 45,951
� DOE Project $ 0� TU-CoRE $ 256,500� NSF Project $ 10,000
TOTAL EXPENSES $456,410� Reserve $ 90
1 - 8
� TUSTP Membership: TOTAL
• 1994/95 $ 150,000• 1995/96 $ 170,000• 1996/97 $ 180,000• 1997/98 $ 195,000• 1998/99 $ 215,000• 1999/00 $ 225,000• 2000/01 $ 228,000• 2001/02 $ 205,000• 2002/03 $ 190,000
$1,758,000
� Government/Proposals:
• DOE/BDM (1995) $ 42,500• DOE (1997-2002) $ 766,000 • OCAST (1998-2001) $ 290,475• NSF CRCD (2000–02) $ 125,000• TU-CoRE (2002, 2003) $ 306,500• NSF I/UCRC (2003) $ 10,000
$1,540,475
TUSTP Funding History
2 - 1
New DOE and NSF I/UCRC Proposals
byRam S. Mohan
The University of Tulsa
May 20, 2003
TUSTP 2003
Proposed New DOE Project
Title: Design and Development of Integrated Compact Multiphase Separation Systems (CMSS©)Principal Investigators: Drs. Ram S. Mohan, Ovadia Shoham, Shoubo Wang and Luis GomezProject Period:October 2002 – September 2008 (6 years)Project Budget:DOE - $300,000 per yearMatch - TUSTP - $100,000 per yearSubmtted: August 2002
2 - 2
DOE Project Objectives� Development of first generation compact multiphase
separation systems (CMSS©) for onshore and offshore applications integrating the already developed components.
� Develop improved individual components to ensure simple, compact, cost-effective, and high-efficient separation of clean streams of gas, oil, water and solids. Develop the second generation CMSS integrating these components.
� Adapt the developed compact separation systems for Floating Production Storage and Offloading (FPSO) systems and subsequently for subsea applications.
Fundamental CMSS Configuration Using Field Tested Components
LLHCGLCC
LLHC
Wet Gas Scrubber
CleanGas
Clean OilFor Transport
Three-Phase
Mixture
FWKOLLHC
Clean WaterFor Disposal
SSUSolids
2 - 3
Second Generation CMSS Configuration with New Components
GLCC
LLHC
Wet Gas Scrubber
CleanGas
Clean OilFor Transport
Three-Phase
Mixture
Clean WaterFor Disposal
SSUSolids
Ann. Film Extractor
LLCC
HPS
� Industry/University Cooperative Research Center
� Focus on Multiphase Transport Phenomena� 25 faculty: Engineering (Chemical,
Mechanical, Petroleum), Physics, Polymer Science, Applied Math
� $30k annual membership fee leverages more than $600K in annual research
� NSF contributes $150K annually ($50K per university)
� Univ. of Tulsa, Michigan State University, University of Akron
National Science FoundationI/UCRC
2 - 4
Mission Statement
� I/UCRC-MTP will support the combined research and education mission of the National Science Foundation in the area of CMTP by bringing together experimental, theoretical, and computational experts from industry and academia in order to
1) conduct pre-competitive leading edge research related to emerging and traditional technologies that involve multiphase phenomena
2) develop next generation MTP models3) develop next generation CMTP design tools and 4) develop innovative methods to effectively train
students and engineers in the use of CMTP tools.
NSF Requirements
� Planning Proposal – approved� Operational Proposal
� Each university must sign up 5 company members
� Members form an Industrial Advisory Board (IAB)
� Research emphasis is on pre-competitive technologies
� NSF will form the center for 5 years with a possible extension for another 5 years
2 - 5
Research Focus
� Research is conducted in 5 areas: Multiphase Fluids, Porous Media, Mixing and Reactions, Separations, and Turbulence
� Faculty, Graduate students and undergrad students work in multi-disciplinary teams
� IAB meets bi-annually to review and select projects that are funded
Multiphase Fluids
� Develop improved models and computational methods
� Predict microstructure of complex fluids in confined flows and free jets
� Composite materials with nanofibers and nanoparticles
� Strategies for manufacturing polymer matrix composites
2 - 6
Multiphase Porous Media
� Computational methods for fluid flow and heat transfer through porous media
� Development of high efficiency filters, gas phase coalescers, oil/water separators
� Evaluate natural and forced convective heat transfer in porous structures such as in fuel cells or in sediment around buried sub-sea pipelines
Multiphase Mixing and Reactions
�Computational methods to track motion of an interface between immiscible fluids
�Analysis of liquid jet breakup, mixing of oil and water, coalescence of liquid drops on fibers
�Analysis of stability of liquid/gas interfaces in molding, fuel sprays, interfacial reactions, and oil-water separations in hydrocyclone separators
2 - 7
Multiphase Separations
�Computational methods for predicting the separation of oil-water-gas mixtures
�Analysis of re-suspension of sand in oil-water-gas flows
�Evaluate sub-sea and surface oil-water-gas pipe and separator designs
�Evaluate the strategic placement and performance of sand separators
Multiphase Turbulence
� Methods to predict the mean field velocity and mean field pressure distributions
� Develop turbulence models for flows with strong streamline curvature
� Analysis of hydrocyclone separators, mixing of liquid and gases in furnace tubes, and liquid/gas sprays
2 - 8
Intellectual Property
� IP is owned by the universities� Members have 30 days to review papers for
proprietary reasons� All technologies are available to members for
internal use� Royalty free license granted to members sharing
in patent costs� If only one member wants license, member may
request exclusive royalty bearing license
Key Participants The University of Tulsa
University of Tulsa:
Dr. Ram S. Mohan, Mechanical EngineeringDr. Ovadia Shoham, Petroleum EngineeringDr. Luis Gomez, Petroleum EngineeringDr. Shoubo Wang, Petroleum EngineeringDr. Keith Wisecarver, Chemical EngineeringDr. Brenton McLaury, Mechanical EngineeringDr. Leslie Thompson, Petroleum Engineering
2 - 9
Key ParticipantsMSU and University of Akron
Michigan State University:Dr. Charles Petty, Chemical EngineeringDr. Andre Benard, Mechanical EngineeringDr. Farhad Jaberi, Mechanical EngineeringDr. A.Y. Lee, Material Science
University of Akron:Dr. George Chase, Chemical EngineeringDr. Ed Evans, Chemical EngineeringDr. G. W. Young, MathematicsDr. R. Ramsier, Physics
Target Industry Participants
AEA Technology (CFX) Ford Motor Company Bechtel General Motors CD-Adapco Los Alamos National LabCETCO HoneywellChevronTexaco NATCO Daimler-Chrysler PetrobrasDELPHI Timken Research Corp. DOE VisteoneSpin Technologies Williams InternationalExxonmobil FLUENT
2 - 10
See more information at websites
�NSF Operational Proposalwww.egr.msu.edu/mtp
�NSF CRCD Projectwww.vu.msu.edu/preview/eng-mtp
Letter of Intent
�Endorse forming the center�Endorse proposed research agenda,
indicate research has potential impact on industry
�State company intends to join the center �Signed by responsible authorized person�Contact Ram Mohan for more information
3 - 1
TUSTP 2003
By Angel Bustamante
May 20, 2003
DOE Project:Design and Performance of
Multiphase Distribution Manifold
� Introduction
� Objectives
� Experimental Program
� Manifold Design
� Future work
Topics
3 - 2
Introduction
� Wells connected to a manifold have a different liquid and gas flowrate
�Provide and guarantee equal split of gas and liquid flow for downstream separators
�Protect downstream metering equipment and provide high accuracy of metering
� Multiphase distribution manifold, as a flow conditioning device:
Objectives
� Develop a lab prototype multiphase distribution manifold
� Acquire systematic experimental data for performanceevaluation
� Develop a mechanistic model � Design tool
� Performance evaluation
� System optimization
3 - 3
Experimental Program
� Experimental Facility
� Test Matrix
� Results
�System Operational Envelope
�Manifold Operational Envelope
�Liquid and Gas Split Ratios
�Manifold Resistance Coefficient (Kl)
�Transient Performance
Experimental Facility
Liquid Outletsto Micromotion
GLCC # 1
Gas Outlets
Vortex Meter
Vortex Meter
Distribution Manifold
Slug Damper
Rotameters
Liquid line
Gas line
GLCC # 2
3 - 4
Flow Configurations
1 2 3 4L GL LCASE 1
1 2 3 4
L LL GCASE 2
1 2 3 4L GL GCASE 3
1 2 3 4L LG GCASE 4
1 2 3 4G GL LCASE 5
1 2 3 4
L GG GCASE 6
1 2 3 4G GL GCASE 7
Test Matrix
Vsg: 10.5 fts/s to 30.5 ft/s, Vsl: 1.0 ft/s to 2.75 ft/s
1 2 3 4CASE 8 L/G L/GL/G L/G
Manifold / Slug DamperLiquid Carry-Over
0.00
0.50
1.00
1.50
2.00
2.50
3.00
3.50
0.00 5.00 10.00 15.00 20.00 25.00 30.00 35.00 40.00 45.00
Vsg (ft/s)
Vsl (
ft/s)
Single GLCC
Double GLCC
Case I
Single GLCC
2 Parallel GLCC's
Manifold/Slug Damper/GLCC's
System Operational Envelope
1 2 3 4L GL LCASE 1
3 - 5
Manifold / Slug DamperLiquid Carry-Over
0.00
0.50
1.00
1.50
2.00
2.50
3.00
3.50
0.00 5.00 10.00 15.00 20.00 25.00 30.00 35.00 40.00 45.00
Vsg (ft/s)
Vsl (
ft/s)
Single GLCC
Double GLCC
Case II
Single GLCC
2 Parallel GLCC's
Manifold/Slug Damper/GLCC
's
1 2 3 4L LL GCASE 2
System Operational Envelope
Manifold / Slug DamperLiquid Carry-Over
0.00
0.50
1.00
1.50
2.00
2.50
3.00
3.50
0.00 5.00 10.00 15.00 20.00 25.00 30.00 35.00 40.00 45.00
Vsg (ft/s)
Vsl (
ft/s)
Single GLCC
Double GLCC
Case III
Single GLCC
2 Parallel GLCC's
Manifold/Slug Damper/GLCC
1 2 3 4L GL GCASE 3
System Operational Envelope
3 - 6
Manifold / Slug DamperLiquid Carry-Over
0.00
0.50
1.00
1.50
2.00
2.50
3.00
3.50
0.00 5.00 10.00 15.00 20.00 25.00 30.00 35.00 40.00 45.00
Vsg (ft/s)
Vsl (
ft/s)
Single GLCC
Double GLCC
Case VI
Single GLCC
2 Parallel GLCC's
Manifold/Slug Damper/GLCC
's
1 2 3 4L GG GCASE 6
System Operational Envelope
Manifold / Slug DamperLiquid Carry-Over
0.00
0.50
1.00
1.50
2.00
2.50
3.00
3.50
0.00 5.00 10.00 15.00 20.00 25.00 30.00 35.00 40.00 45.00
Vsg (ft/s)
Vsl (
ft/s)
Single GLCC
Double GLCC
Case VII
Single GLCC
2 Parallel GLCC's
Manifold/Slug Damper/GLCC'
1 2 3 4G GL GCASE 7
System Operational Envelope
3 - 7
Manifold / Slug DamperLiquid Carry-Over
0.00
0.50
1.00
1.50
2.00
2.50
3.00
3.50
0.00 5.00 10.00 15.00 20.00 25.00 30.00 35.00 40.00 45.00
Vsg (ft/s)
Vsl (
ft/s)
Single GLCC
Double GLCC
Case VIII Equal Flow
Single GLCC
2 Parallel GLCC's
Manifold/Slug Damper/GLC
1 2 3 4CASE 8 L/G L/GL/G L/G
THE SAME ENVELOPE APPLIES TO CASES IV AND V1 2 3 4L LG G
CASE 4
1 2 3 4G GL L
CASE 5
System Operational Envelope
Manifold Operational Envelope
Manifold Operational Envelope for Liquid Carry-Over
0.0
0.5
1.0
1.5
2.0
2.5
3.0
5 10 15 20 25 30 35
Vsg (ft/s)
Vsl (
ft/s)
Case I
Case II
Case III
Case IV
Case V
Case VI
Case VII
Case VIII Equal Flow
Manifold Operational Envelope for Liquid Carry-Over
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
5 10 15 20 25 30 35 40 45
Vsg (ft/s)
Vsl (
ft/s)
Case I
Case II
Case III
Case IV
Case V
Case VI
Case VII
Case VIII Equal Flow
Single GLCC
2 Parallel GLCC's
Manifold/Slug Damper/GLCC's
3 - 8
Liquid Split ( GLCC# 2 over Total Flow) v.s. GVF
0.40
0.50
0.60
0.70
0.80
0.90
1.00
0.75 0.8 0.85 0.9 0.95 1GVF
Liqu
id S
plit
Case I
Case III
Case VI1 2 3 4L GL LCASE 1
1 2 3 4L GL GCASE 3
1 2 3 4L GG GCASE 6
Liquid Split Ratios
Liquid Split ( GLCC# 2 over Total Flow ) v.s. GVF
0.40
0.50
0.60
0.70
0.80
0.90
1.00
0.75 0.8 0.85 0.9 0.95 1G VF
Liqu
id S
plit
C ase IV
C ase V
C ase V IIIEqual F low
1 2 3 4L LG GCASE 4
1 2 3 4
G GL LCASE 5
1 2 3 4CASE 8 L/G L/GL/G L/G
Liquid Split Ratios
3 - 9
Liquid Split ( GLCC# 2 over Total Flow ) v.s. GVF
0.40
0.50
0.60
0.70
0.80
0.90
1.00
0.75 0.8 0.85 0.9 0.95 1G VF
Liqu
id S
plit
Case II
Case V II 1 2 3 4
L LL GCASE 2
1 2 3 4
G GL GCASE 7
Liquid Split Ratios
Gas Split ( GLCC# 2 over Total F low ) v.s. G VF
0.00
0.10
0.20
0.30
0.40
0.50
0.60
0.75 0.8 0.85 0.9 0.95 1GVF
Gas
Spl
it
Case I
Case III
Case VI1 2 3 4L GL LCASE 1
1 2 3 4L GL G
CASE 3
1 2 3 4L GG G
CASE 6
Gas Split Ratios
3 - 10
Gas Split ( GLCC# 2 over Total F low ) v.s. G VF
0.00
0.10
0.20
0.30
0.40
0.50
0.60
0.75 0.8 0.85 0.9 0.95 1GVF
Gas
Spl
it
C ase IV
C ase V
C ase V IIIEqual F low
1 2 3 4L LG GCASE 4
1 2 3 4G GL LCASE 5
1 2 3 4CASE 8 L/G L/GL/G L/G
Gas Split Ratios
Gas Split ( GLCC# 2 over Total F low ) v.s. G VF
0.00
0.10
0.20
0.30
0.40
0.50
0.60
0.75 0.8 0.85 0.9 0.95 1GVF
Gas
Spl
it
Case II
Case V II
1 2 3 4L LL GCASE 2
1 2 3 4G GL GCASE 7
Gas Split Ratios
3 - 11
Liquid / Gas Split RatiosCases I / III / VI
Liquid and Gas Split ( GLCC# 2 over Total Flow) v.s. GVFCases I / III / VI
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
0.75 0.80 0.85 0.90 0.95 1.00G.V.F.
Liq
Split
0.0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1.0
Gas
Spl
it
Case I
Case III
Case VI
LIQUID SPLIT
GAS SPLIT
Resistance Coefficient (Kl) for Manifold
Manifold Resistance Coefficient
LIQ
WELLWELL
LIQ
WELLWELL
hh h h
3 - 12
� Kl is calculated using the following equation
1)(**2
2'��
VKsl
l
hg
Where V’sl is the liquid velocity in each liquid leg
Manifold Resistance Coefficient
Kl v.s . Reynolds
0
10
20
30
40
50
60
70
0 5000 10000 15000 20000 25000 30000 35000 40000 45000Re
Kl
LIQ
WELLWELL
LIQ
WELLWELL
Manifold Resistance Coefficient
3 - 13
Transient Performance
Transient PerformanceVsg=0 ft/s
0.00
0.50
1.00
1.50
2.00
2.50
0 20 40 60 80 100 120 140
t (s)
Vsl(
ft/s)
Total Flow In
Total Flow Out
Flow in GLCC # 2
Flow in GLCC # 1
Total Flow In
Total Flow Out
GLCC # 1
GLCC # 2
Transient Perform anceVsg=6.7 ft/s
0.00
0.50
1.00
1.50
2.00
2.50
0 50 100 150 200
t (s )
Vsl (
ft/s)
Tota l F low In
Tota l F low O ut
F low in G LCC # 2
Flow in G LCC # 1
Transient Performance
Total Flow In
Total Flow Out
GLCC # 1
GLCC # 2
3 - 14
Manifold Design
� Diameter
�Manifold
�Outlets
� Inlet Wells Arrangement
� Design Example
Manifold Sizing
The Design Code is based on simplified Kelvin-Helmholtzstability analysis
The stabilizing gravity force acting on the wave is,� �� � ��� gCoshh GLGG ��
'
The pressure suction force causing wave growth is given by,
� �22''
21
GGG vvPP ��� �
3 - 15
Manifold Sizing
� Two criteria were evaluated to determine the manifold diameter
�Criterion 1: Diameter is calculated only considering each section separately
Manifold Sizing
�Criterion 2: Diameter is calculated considering the effect of one well on its neighbors
3 - 16
Outlets Sizing
Liquid Outlets
12�
�
lL K
ghVL
L
VQA �
Gas Outlets
1
2
2�
�
VKg
P�
G
G
VQA �
Wells Arrangement
� Based on experimental results, two modifications were proposed to Avila-Gomez model
�Proposal 1: Make well arrangement based on ratio Qmixture/Ql
�Proposal 2: Make well arrangement locating wells with high gas flow rates in middle section of manifold.
3 - 17
Design Example
Example of manifold with seven wells connected
Design Code
Auto-arrangement considering proposal # 1
4 - 1
TUSTP 2003
By Dong Xiang
May 20, 2003
DOE Project:StarCut Differential Dielectric
Sensor — Experiments and Modeling
Topics
� Introduction� Fundamentals of Microwave Measurements� Measurement Methods of Permittivity� Proposed Solution� Future Plans
4 - 2
Introduction
� StarCut is ChevronTexaco’s meter for continuous measurement of multiphase fluid composition
� Microwave signal is used to measure dielectric properties of the fluids
� At present, no analytical model is available for StarCut
Topics
�Fundamentals of Microwave Measurements
� Waveguide
� Microwave Characterization
� S-Parameter
4 - 3
Sensor Cell of StarCut
Transmitting Antenna Receiving Antenna
Fluid
Waveguide
� Waveguide is used for efficient transfer of microwave signals from one point to another
� In StarCut, rectangular waveguide is used
4 - 4
Microwave Characterization
Incident Wave
Reflected Wave
Transmitted Wave
Sample
Why Use S-Parameter?
�It is very hard to measure total voltage and current at device ports
�S-Parameter is relatively easy to obtain at high frequency
�S-Parameter is related to familiar measurements (gain, loss, reflection coefficient)
4 - 5
S-Parameter Measurement
Topics
�Measurement Methods of Permittivity� Transmission Line Method
� Reflection/Transmission Method�Amplitude Attenuation + Phase
Shift�S-Parameter
� Transmission Line Equation Method � Cavity Resonator Method
� Full Wave Analysis Method� Perturbation Theory Method
4 - 6
Transmission Line Method
�Waveguide structure is modeled as transmission line
�Transmission line parameters are measured to determine permittivity
Amplitude Attenuation and Phase Shift
�Lookup Table Method (Hatton,Texaco, 1989)
� This patent is the theoretical foundation of StarCut currently used in North Campus
� Attenuation + phase shift + Database (lookup table)
4 - 7
Amplitude Attenuation and Phase Shift
�Analytical method (Kraszewski, 1990)
� Measurement has to be done twice using different thickness of sample
� It is difficult for dynamic measurement
� No hole-effect consideration
S-Parameter Method
�S-Parameter is measured to determine permittivity (Marrelli, ChevronTexaco, 1997)
�No hole-effect consideration
4 - 8
Transmission Line EquationMethod
�Transmission line equation and boundary condition are used to determine permittivity
� This is the theoretical foundation of Huang’s Thesis (1997)
� Polynomial fitting for hole-effect
Huang’s Model
Section 1
Section 2
Section 3
zjk
i
izjk
i
ii
ii eZbe
ZazI ��
�)(
� � zjki
zjkii
ii ebeazV ��
��
4 - 9
Cavity Resonator Method
�Resonance frequency is measured to determine permittivity
�Network analyzer is used to get resonance frequency
�Advantage: hole-effect can be considered
�Only valid for low-loss material, not useful for multiphase flow measurement
Full Wave Method
�Resonance frequency is determined by electromagnetic equation and boundary condition
�Advantage: hole-effect can be easily calculated
�This is the theoretical foundation of Janezic, NIST (Colorado, 1999)
4 - 10
Perturbation Theory
�Resonance frequency is determined using perturbation theory for material in cavity resonator
�Advantage: hole-effect can be calculated
�Disadvantage: too many assumptions affect the measurement accuracy
Topics
� Proposed Solution:
� Transmission Line Method
4 - 11
Solution: Model
�Resonator method is not good for our case
Reason: multiphase fluid has high loss
�Transmission line method is considered
Future Plans
� Develop model for StarCut, minimize hole-effect
� Hardware Improvement of StarCut
� Use StarCut to measure other parameters in multiphase flow
5 - 1
TUSTP 2003
DOE Project:
HORIZONTAL PIPE SEPARATOR (HPS©)
By
Ciro A. Pérez
May 20, 2003
v Objectives
v Physical phenomena in HPS
vModeling approach
v Experimental program
v Conclusions - Future work
Topics
5 - 2
v Study the behavior of oil-water mixtures in horizontal pipes
v Develop a mechanistic model that predicts separation efficiency for given fluids, geometry and flow rates
v Compare/refine model with data obtained in this study and from literature
v Study effects of using manifolds to install multiple separators in parallel
Objectives
v Objectives
v Physical phenomena in HPS
vModeling approach
v Experimental program
v Conclusions - Future Work
Topics
5 - 3
Zone 1 Zone 2
Zone 3
Zone 4
OilOil with Water dropletsPacked water droplets in oilPacked oil droplets in water
Water with Oil droplets
Water
Physical phenomena in HPS
Inlet Direction of flow Outlets
Oil-Water mixture enters HPS, with droplet distribution function of processes upstream. Some mixing can occur at inlet (Zone 1)Inside HPS the velocity decreases, turbulence decreases (laminar flow might be reached), settling and coalescence are promoted (Zone 2), layers begin to developUp to 6 layers can develop (Zone 3):- Pure Oil- Oil with water droplets- Packed water droplets in oil- Packed oil droplets in water- Water with oil droplets- Pure water
Eventually steady state is reached (Zone 4)
Physical phenomena in HPS
5 - 4
v Regimes of operation in HPS
v Laminar flow is desirable as it promotes segregationv Oil is more likely to flow to be in laminar flow conditions
due to higher viscosityv So, desirable flow regimes are:
- Laminar Oil Flow - Laminar Water Flow- Laminar Oil Flow - Turbulent Water Flow
v Study flow in HPS requires:- Steady state conditions: max segregation- Transient conditions: how long it will take
Physical phenomena in HPS
v Objectives
v Physical phenomena in HPS
vModeling approach
v Experimental program
v Conclusions - Future work
Topics
5 - 5
vPrevious studies
vProposed model
Modeling approach
Previous studies
a. 1D Mechanistic approach: Barnea-Brauner (1991)b. 2D Analytical approach (for laminar flows): Brauner
(1998)c. Numerical approach
- Shoham-Taitel (1984, gas-liquid)- Elseth et al. (2000, VOF method)- Gao et al. (2003, VOF method)
1D mechanistic approach leads to simple solutions, so it will be used as an initial approach
Modeling approach
5 - 6
vProposed model:
v1- 1D stratified flow pattern model is applied for given fluids and flow rates. If flow is stable, flow characteristics are given by the model
v2- If flow is unstable, following procedure applies:- An amount of the more viscous phase is assumed to
flow to the less viscous phase- For this new flow rate, properties are calculated for
mixture, segregated flow is assumed, and stability is checked. Migration stops when stability is reached
- No convergence means non segregated flow
Modeling approach
vPreliminary resultsModel tested against experimental data (Shi et al. (2000)) v Test conditions:
- Oil properties: 3 cp, 800 kg/m3
- Water properties: 1 cp, 1100 kg/m3
- Pipe: 0.1 m ID, 18m long- Mixture velocity: 0.4 to 3 m/s- Water Cut: 0.2, 0.4, 0.6, 0.8
v Trallero (1995) model used, Sheltering Factor assumed 0v Increased interfacial friction factor as mixing and waves form
at the interface
Modeling approach
5 - 7
vResults: Pure oil and water layer thickness
Modeling approach
40% WC
00.10.20.30.40.50.60.70.80.9
1
0 0.5 1 1.5
Mixture Velocity m/s
hl/D
Experimental Oil-Mix level
Experimental Mix-Water Layer
Model Oil-Mix layer
Model Mix-WaterLayer
60% WC
00.10.20.30.40.50.60.70.80.9
1
0 0.5 1 1.5
Mixture velocity m/s
hl/D
Experimental Oil-Mix level
Experimental Mix-Water layer
Model Oil-MixLayer
Model Mix-WaterLayer
v Objectives
v Physical phenomena in HPS
vModeling approach
v Experimental program
v Conclusions - Future work
Topics
5 - 8
Test Section
Experimental program
v Calibration:
vLevel: Pipe centerline leveled in +-3/32” range from horizontal
vLevel sensors: For operating conditions, level meters are able to detect continuous interface with error of 3/32”
Experimental program
5 - 9
v Typical level meter signal at interface
Experimental program
Sensor 2 signal function of dimensionless height
0
0.10.20.3
0.40.5
0.60.70.8
0.91
0 1 2 3 4 5
Voltage
hl/
D
Test 1Test 2Test 3Test 4Top of sensorBottom of sensor
Sensor stem gap:
7/32”
vPitot / Isokinetic sampling probe
Previous works: - Kohr, Mendes-Tatsis and Hewitt (1996)- Vedapuri, Bessette and Jepson (1997)- Shi, Cai and Jepson (1999)- Cai, Gopal and Jepson (2000)
Experimental program
5 - 10
vPitot / Isokinetic sampling probe
vCharacteristics - ID= 3/16”- OD= 11/32”- Operating dP: 0 to 1” H2O, accuracy dP 0.15%- Range of operation:
. Min. velocity: 0.06 m/s (error 10% )
. Max. velocity : 0.7 m/s (error 0.073% )
Experimental program
v Photo of assembled probe:
Base
Pitot
Pressure outlets
Sampling outlet
Experimental program
5 - 11
v Pitot / Isokinetic sampling probe in place
Experimental program
v Pitot / Isokinetic sampling probe- Calibration results for single phase
Experimental program
150 lbs/min oil
00.050.1
0.150.2
0.250.3
0.350.4
0.45
0 0.5 1 1.5
Distance from centerline (inches)
Vel
ocity
(m
/s)
1.71875
1.46875
1.21875
0.96875
0.71875
0.46875
0.21875
0.03125
Theoretical
Distance from wall 200 lbs/min water
0
0.05
0.1
0.15
0.2
0.25
0.3
0 0.5 1 1.5
Distance from centerline (inches)
Vel
ocity
(m/s
)
1.75
1.5
1.25
1
0.75
0.5
0.25
0
Theoretical
Distance from wall
5 - 12
vPitot / Isokinetic sampling probe- Problems when measuring oil-water flow. After flushing
with oil, water flood pitot, capillarity causes oscillations in dP while flooding
- Improved with wider pressure taps. dP values will be taken at initial plateau, before flooding occurs.
Experimental program
Signal from dP, at 0.75" from bottom
0
1
2
3
4
5
6
0 20 40 60 80
Time (1/2 sec)
Vol
tage Test 3
Test 2Test 1
Plateau Flooding
v Calibration results: Effects of oil-water flowv Pitot filled with oil, mixture flowing Vsl=0.6 m/s, WC 60%
Experimental program
Velocity Profile: Vmix=0.6 m/s, WC 60%
00.1
0.20.30.40.50.60.70.80.9
1
0 0.2 0.4 0.6 0.8 1
Velocity (m/s)
hl/D Velocity Profile
5 - 13
v Objectives
v Physical Phenomena in HPS
vModeling approach
v Experimental program
v Conclusions/ Future Work
Topics
v Initial model for all flow conditions is proposed. Actual model underpredicts thickness of pure fluid zones
vModel requires higher interfacial shear stress when mixing layers are present
v Pitot measurements for low velocities are affected by capillarity in pitot pressure taps Measurement criterion was adapted for this condition
Conclusions/Future Work
5 - 14
vMeasurement of velocity profiles for experimental matrix
vMeasurement of hold up for experimental matrixv Hold up/Interfacial friction factor adjustment with
experimental data and literature data
Future work
vQuestions
HORIZONTAL PIPE SEPARATOR (HPS©)
6- 1
TUSTP 2003
By:
Nólides Guzmán
May 20, 2003
FOAM FLOW IN GLCC ©
� Physical Phenomena
� Objectives
� Foam Characterization
� Experimental Program
� Preliminary Experimental Results
� Preliminary Modeling
� Future Work
Outline
6- 2
Qfoam
QL Free
Nozzle Region:Foam Produced
Foam Flow
Qgas
Foam Flow
Annular Flow Regime
Foam breakingSwirling LiquidFilm
Qgas
QFoamQLfree
Foam Flow
Liquid Carry-Over
� Low Gas VelocityVsg = 10 ft/s
� High Gas VelocityVsg = 40 ft/s
Physical Phenomena
Vsl = 0.4 ft/s
� Acquire experimental data to characterize foam flow behavior in the GLCC
� Develop a mechanistic model for the prediction of foam flow behavior in the GLCC
Objectives
6- 3
What is a Foam?
� Foam is a special kind of colloidal dispersion, in which gasis dispersed in continuous liquid phase
� Foam is composed of gas bubbles dispersed uniformly in continuous liquid phase
� Foam can be treated as homogeneous fluid
� Foam is probably the only known compressible non-Newtonianfluid
Foam Characterization
a) quality
Foam Descriptors b) texture
c) rheology
a) Quality
foam
gasPT V
Vx �,
liquidgasfoam VVV ��
where
6- 4
Foam structure at various qualities
Illustration of different foam textures
Foam Characterization
b) Texture
c) Rheology
Rheometers: �Couette �Circulating pipe�Single-pass pipe
Foam Characterization
6- 5
Rheology foam measurements cannot be compared directly:
1. Different measurement equipment
2. Subtle differences in data analysis methods
3. Differences in foam structures
A change in foam texture from fine and uniform to coarse andheterogeneous coincides with substantial viscosity reduction
Foam Characterizationc) Rheology
Experimental Program
�Metering Section
�Test Section
�Foam Measurement
�Test Matrix
6- 6
Metering Section
CompressorPressure Regulator50 psig
MicromotionTo test section
Centrifugal pump
From test section
Injection Pump
Back Pressure control
Orifice Meter
Turbine Meter
120 psig250cfm
Surfactant
Static mixer
section
Micromotion
PI
PI
PI TI
TIPI
Mixing Tee
Water tank
Meter
Filter
Test Section Facility
3
Purge
19”
To Foam Storage Tank
Gas Leg
Liquid Leg 8”
24”
21”
12
AFE
Foam Flow from Metering
Section
6- 7
Foam Measurement
Foam Height
Free Liquid
Free Gas
t
Foam Height
Free Liquid
Free Gas
Drainage rate
t + dt
Coalescence rate
Variables to be measured
� Quality*� Texture*� Rheology*� Coalescence rate � Drainage rate
* Measurement method to be defined
Foam Measurement
6- 8
Test Section Facility
Optical Level Meter in 1, 2 and 3
3
Foam Flow from
Metering Section
Purge
To Foam Storage Tank
Gas Leg
Liquid Leg
12
AFE
Micromotion FM-1
Micromotion FM-2
Micromotion FM-3
TURBISCAN On Line:
- Monitors and quantifies effects of process variables on dispersed system to improve process efficiency and product quality
- Operating range:0 to 60% v/v concentration 0.1 to 5,000 microns particle size
- How does it work? Multiple light scattering analysis of concentrated dispersions
Optical Level Meters
6- 9
Input Parameters
� Gas Flow rate� Liquid Flow rate� Surfactant Concentration� GLCC Liquid Level� GLCC Pressure
Tests Matrix
Variables
Superficial Gas VelocitySuperficial Liquid Velocity
Fixed parameters:� Surfactant Concentration
(Drillfoam F450 )� GLCC Liquid Level� GLCC Pressure
Operating Range
25 - 45 ft/s0.3 - 0.55 ft/s
0.01% (Vol Surf/Vol Water)
20 in.25 psia
Tests Matrix
6- 10
Preliminary Experimental Results
Operational Envelope for Foam Breaking
0.10
0.20
0.30
0.40
0.50
0.60
0.70
0.0 5.0 10.0 15.0 20.0 25.0 30.0 35.0 40.0 45.0 50.0 55.0
Vsg (ft/s)
Vsl(
ft/s)
Foam Carry-Over No foam carry-Over
Swirling Liquid Film
Drillfoam F450 [Surf]= 0.01% v/vFor the 3'' GLCC
Upstream Pipeline Foam Quality *
0.970
0.975
0.980
0.985
0.990
0.995
1.000
0.30 0.35 0.40 0.45 0.50 0.55 0.60 0.65 0.70 0.75
Vsl (ft/s)
x (-)
253035404550
Foam Breaking
Foam Breaking Region
Foam Carry-Over Region
Vsg (ft/s)
*Assuming complete gas/liquid mixture
Preliminary Experimental Results
6- 11
0
100
200
300
400
500
600
700
0.30 0.35 0.40 0.45 0.50 0.55 0.60 0.65 0.70 0.75
Vsl (ft/s)
ac/g
(-)
2530354045
50
Foam Breaking
Foam Breaking Region
Foam Carry-Over Region
Vsg (fts)
Centrifugal Acceleration Required in the Nozzle for Foam Breaking
Preliminary Experimental Results
Preliminary Modeling
�Previous Works:�Foam Hydrodynamics�Foam Rheology
�Preliminary Model�Equation-of-State for Foam�General Approach
6- 12
Previous Works:Foam Hydrodynamics
�Lord (1979). Mathematical Analysis of Dynamic and Static Foam Behavior
Objective:Prediction of static and dynamic foam properties in a wellbore
Model based on:- Equation-of-State- Mechanical energy balance considering compressibility effects
Results:- Equation-of-state for foam- Estimation of the wellhead pressure
�Blauer et al (1974). Determination of Laminar, Turbulent and Transitional Foam Flow Losses in Pipes
Objective:Prediction of friction losses in laminar, transitional and turbulent flow for flowing foam
Model based on:- Mitchell study about viscosity of foam (1969)- Set of experimental correlations
Results:- f = f (�e ,�f , V, Dp )- Relationship between Re and f for foam is the same as singlephase pipe flow
Previous Works:Foam Hydrodynamics
6- 13
� Bonilla and Shah (2000). Experimental Investigation on the Rheology of Foams
Objectives:- Experimental investigation of aqueous and gelled foam
rheology utilizing a pipe type viscometer - Development of empirical correlations to predict foam fluid
apparent viscosity
Results:- Correlations that predict foam rheology as a function of
liquid phase properties and foam quality, applicableto the foam systems tested
Previous Works:Foam Rheology
Preliminary Model:Equation-of-State for Foams
Equation of State
MTRzVP G /~����
Basis: a unit mass of foam
Mass ratio of liquid to gas is constant throughoutthe system from mass balance consideration
constmm
G
L�
Mass fraction of gasLG
GG mm
mx
�
�
(1)
(2)
6- 14
Volume of foam per unit mass LGGGF VxVxV ~)1(~~�����
(4)
(5)
(3)
LGGGF xx ��
�/)1(/
1��
�Solving for foam density yields
PbaP
F��
��In terms of pressure
where LG
G
xbMTRzxa
�/)1(/
��
����
Equation (5) gives
Preliminary Model:Equation-of-State for Foams
),( TPF�
� Lord mathematical developments
� Blauer results for friction factor
� Characterization of foam quality, bubbles size distribution
(texture) and rheology
� Input parameters
Obtain:
� Efficiency of separation in terms of foam carry-over and gas
carry-under
� Foam flow behavior in GLCC at different conditions
Preliminary Model:General Approach
6- 15
Future Work
� Select and install Optical Level Meters in sample sections
� Select and install Micromotions at the inlet and at the gas and liquid legs of the GLCC
� Adapt a static model for sample sections
� Develop a mechanistic model for the separation process
� Evaluate the GLCC efficiency of separation when foam is flowinginto the system
7-1
Slide # 7-1
by
Carlos Di Matteo
May, 2003
DOE Project:Mechanistic Modeling of
Slug Dissipation in Helical Pipes
TUSTP 2003
Slide # 7-2
Outline
� Introduction� Objectives� Experimental Program� Mechanistic Model� Comparison Study� Future Work
7-2
Slide # 7-3
Introduction
TUSTP Approach for Inlet Flow Conditioning: � Slug Damper (Completed)
� Helical Pipe
Slide # 7-4
Introduction
Liquid Outlet
Gas Outlet
Gas/Liquid Mixture Inlet
Inlet
Top View
GLCC
GLCCHelical
Pipe
7-3
Slide # 7-5
Objectives
� Develop a mechanistic model for slug dissipation in helical pipes
� Test and refine model against TUSTP helical pipe data (Ramírez, 2000)
� Develop design criteria and design procedure
Slide # 7-6
� Experimental Facility
� Experimental Results
Experimental Program
7-4
Slide # 7-7
Experimental FacilitySchematic
Electrical Air Compressor
Water Pump
Orifice Metter
Mass Flow Meter
TT Temperature Transducer
PG Absolute Pressure Transducer
DPG Differential Pressure Transducer
Pressure Regulating Valve
Control Valve
Check Valve
Ball Valve
Conductance Probe
Air Tank
PG
TT
Water Tank
DPG
Water
Air
Data Acquisition System
Slug Generator
Helical Pipe
Slide # 7-8
Outlet
Inlet SectionSlugGenerator
2” Transparent Flexible Pipe
Experimental FacilityPhotograph
7-5
Slide # 7-9
Experimental Facility Conductance Probes
Inlet Transparent Section
Helix Diameter 0.74 –1.95 m
Turn 01Turn 02Turn 03Turn 04Turn 05Turn 06Turn 07
DPGPG
Conductance Probes
2-in Transparent Pipe
Hei
ght 2
.5m
Outlet
Two-phase Flow
Slide # 7-10
Experimental ProgramHelixes Configurations
� Helixes Configurations:
� Number of Turns: 7
Designation Helix Diameter (m)
Helical Pitch (m)
Helical Angle (Deg)
Pipe Length per Turn (m)
Helix # 1 1.95 0.28 4.10 6.13
Helix # 2 1.33 0.28 6.00 4.18
Helix # 3 0.74 0.28 10.70 2.32
Table 1 - 1. Helical Pipe Configuration Characteristics.
7-6
Slide # 7-11
vSG = m/s
1
5
10
vSL = m/s
0
0.05
0.1
0.5
1
Helix # 1
Helix # 2
Helix # 3
� Slug length: 10 (0.5m) – 420 (21 m) Pipe Diameters
Experimental Program Data Matrix
Slide # 7-12
Experimental ResultsSlug Dissipation
Slug Length Dissipation
0.0
0.2
0.4
0.6
0.8
1.0
Inlet
Turn
01
Turn
02
Turn
03
Turn
04
Turn
05
Turn
06
Turn
07
l S/l S
i
Legend:vSG = 5.0 m/svSL = 0 m/sDh = 1.95 m
Point Labels = lSi (dp) 22 dp
44 dp191 dp
7-7
Slide # 7-13
Experimental ResultsRepeatability
Helix # 1
Helix # 2
Helix # 3
Similar Operating Conditions Repeatability
Slide # 7-14
Experimental Results Repeatability
Helix # 1
0.00
0.20
0.40
0.60
0.80
1.00
1.20
0 1 2 3 4 5 6 7 8Turn #
Rel
ativ
e Sl
ug L
engt
h (L
/Li)
Li = 8.86 m (L/dp = 176)
Li = 9.90 m (L/dp = 196)
Legend:VSG = 10.0 m/sVSL= 0 m/sdp = 2 indh = 1.95 m�h = 4.1 deghL = 0 %ac = 10.46 g
7-8
Slide # 7-15
Experimental ResultsSlug Dissipation
0
50
100
150
200
250
300
350
400
450
0 50 100 150 200 250 300 350 400 450Initial Slug Length (lSi/dp)
Fina
l Slu
g Le
ngth
(lSF
/dp)
PARTIAL DISSIPATION
ONLY PARTIAL DISSIPATION
TOTAL DISSIPATION
Slide # 7-16
Experimental ResultsDissipation Length vs Initial Slug Length
Dh = 1.95 m
1
10
10 100 1000lSi/dp
l DIS
S (tu
rn)
Vm = 1, 1.05, 1.1 m/s
10.110.05 5.05
10.05.0
Total Dissipation Before Turn No.1
1.5
Vm = 5 to 10.1 m/sPartial Dissipation (PD)
Total Dissipation (TD)
Label points = Mixture Velocity (m/s)
7-9
Slide # 7-17
Experimental ResultsDissipation Length vs Initial Slug Length
Dh = 1.33 m
1
10
10 100 1000lSi/dp
l DIS
S (tu
rn)
Vm = 1, 1.05, 1.1 m/s
1.5
10.010.05
5.05 5.05.1
Total Dissipation (TD)
Total Dissipation Before Turn No.1
Vm = 5 to 10.1 m/s Partial Dissipation (PD)
Label points = Mixture Velocity ( m/s)
Slide # 7-18
Experimental ResultsDissipation Length vs Initial Slug Length
Dh = 0.74 m
1
10
10 100 1000lSi/dp
l DIS
S (tu
rn)
Vm = 1, 1.05, 1.1 m/s
1.5
10.0
10.05
5.05
5.0
10.110.5
Total Dissipation (TD)
Total Dissipation Before Turn No.1
Partial Dissipation (PD)
1.05
5.1
5.5
Label points = Mixture Velocity (m/s)
7-10
Slide # 7-19
� One-Dimensional Flow
� Initial Conditions: Stable Stratified Flow
� Not Normal Slug Flow
� Neglect Secondary Flow
� Neglect Radial Pressure Gradient
� Constant vSL and vSG
Mechanistic ModelAssumptions
Slide # 7-20
� Gravitational Force Mechanism:�Low Superficial Gas Velocities�Larger Helical Diameter�Larger Equivalent Dissipation Length
� Centrifugal Force Mechanism:�High Superficial Gas Velocities�Smaller Helical Diameter�Smaller Equivalent Dissipation Length
� Slug Front Stability Mechanism:�Low Slug Velocities
Mechanistic ModelDissipation Mechanisms
7-11
Slide # 7-21
Mechanistic ModelGeneral Approach
vF1
Approach:
� Slug Tracking: Track Front and Tail of Slug
lS
vT1
vT2vS
�
vF2
Slide # 7-22
Mechanistic ModelNomenclature
vF1Nomenclature:vT1,T2 : Velocity of the Slug Front/Tail InterfacesvS : Velocity of the Liquid SlugvF1,F2 : Velocity of the Film Ahead/Behind the SlugHF1,F2: Liquid Holdup in the corresponding FilmHS : Liquid Holdup in the Liquid Slug� : Angle of Inclination respect to horizontallS : Length of the Liquid Slug Body
lS
vT1
vT2vS
�
vF2
7-12
Slide # 7-23
Mechanistic ModelSlug Dissipation Equations
Slug Tail Velocity
DFS
FFSS1T v
HHvHvHv �
�
���
�
Dissipation Velocity
Slug Dissipation Length
Average Translation Velocity
DISS
S12TDISS v
lvl ���
2vvv 1T2T
12T�
�
tlvvv S
1T2TDISS�
����
Slug Front Velocity
DS2T vvCov ���
Slide # 7-24
Mechanistic ModelClosure Relationships
Drift Velocity� � � �� �������� sin35.0cos54.0dpgvEFFD
Slug Liquid Holdup)Re1048.2exp(0.1H SL6
S �����
Slug Body VelocityMS vv �
90.0Co � Empirical Factor
Effective Gravity���
�
���
�
���
�
� ��
2C
EFF ga1gg
Centrifugal Acceleration� �Dhv2a
2M
C�
�
7-13
Slide # 7-25
Comparison StudyvSL = 0 m/s , Dh = 1.95 m
vSG= 1 m/s vSG = 5 m/s vSG = 10 m/s
lDISS (Pred) vs. lDISS (Meas) for Dh = 1.95 m and vSL = 0 m/s
2917 73
101
191
504422
12
59 66
198177
0.0
2.0
4.0
6.0
8.0
10.0
12.0
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0
lDISS (turn) - Meas
l DIS
S (tu
rn) -
Pre
d
Point Labels = lSi/dp
+30%
-30%
Slide # 7-26
Comparison StudyvSL = 0.05 m/s , Dh = 1.95 m
lDISS (Pred) vs. lDISS (Meas) for Dh = 1.95 m and vSL = 0.05 m/s
9432
36
4932
71
196
81
22
195
70
42
0.0
2.0
4.0
6.0
8.0
10.0
12.0
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0
lDISS (turn) - Meas
l DIS
S (tu
rn) -
Pre
d +30%
-30%
Point Labels = lSi/dp
vSG= 1 m/s vSG = 5 m/s vSG = 10 m/s
7-14
Slide # 7-27
Comparison StudyvSL = 0.1 m/s , Dh = 1.95 m
vSG= 1 m/s vSG = 5 m/s vSG = 10 m/s
lDISS (Pred) vs. lDISS (Meas) for Dh = 1.95 m and vSL = 0.1 m/s
6033113
39
197
62109
71
22
47
0.0
2.0
4.0
6.0
8.0
10.0
12.0
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0
lDISS (turn) - Meas
l DIS
S (tu
rn) -
Pre
d
+30%
-30%
Point Labels = lSi/dp
Slide # 7-28
Comparison StudyvSL = 0.5 m/s , Dh = 1.95 m
vSG= 1 m/s vSG = 5 m/s vSG = 10 m/s
lDISS (Pred) vs. lDISS (Meas) for Dh = 1.95 m and vSL = 0.5 m/s
646080.0
2.0
4.0
6.0
8.0
10.0
12.0
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0
lDISS (turn) - Meas
l DIS
S (tu
rn) -
Pre
d
+30%
-30%
Point Labels = lSi/dp
7-15
Slide # 7-29
Comparison StudyvSL = 0 m/s , Dh = 1.33 m
vSG= 1 m/s vSG = 5 m/s vSG = 10 m/s
lDISS (Pred) vs. lDISS (Meas) for Dh = 1.33 m and vSL = 0 m/s
673452
52
33
232
44
50
12
94161
6068
42
9
0.0
2.0
4.0
6.0
8.0
10.0
12.0
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0
lDISS (turn) - Meas
l DIS
S (tu
rn) -
Pre
d
+30%
-30%
Point Labels = lSi/dp
Slide # 7-30
lDISS (Pred) vs. lDISS (Meas) for Dh = 1.33 m and vSL = 0.05 m/s
11958
3658
243
121
50
2623 41
196
191
0.0
2.0
4.0
6.0
8.0
10.0
12.0
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0lDISS (turn) - Meas
l DIS
S (tu
rn) -
Pre
d +30%
-30%
Point Labels = lSi/dp
Comparison StudyvSL = 0.05 m/s , Dh = 1.33 m
vSG= 1 m/s vSG = 5 m/s vSG = 10 m/s
7-16
Slide # 7-31
lDISS (Pred) vs. lDISS (Meas) for Dh = 1.33 m and vSL = 0.1 m/s
46
7769
117
905682
23
198
5241
0.0
2.0
4.0
6.0
8.0
10.0
12.0
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0
lDISS (turn) - Meas
l DIS
S (tu
rn) -
Pre
d
+30%
-30%
Point Labels = lSi/dp
Comparison StudyvSL = 0.1 m/s , Dh = 1.33 m
vSG= 1 m/s vSG = 5 m/s vSG = 10 m/s
Slide # 7-32
Comparison StudyvSL = 0.5 m/s , Dh = 1.33 m
vSG= 1 m/s vSG = 5 m/s vSG = 10 m/s
lDISS (Pred) vs. lDISS (Meas) for Dh = 1.33 m and vSL = 0.5 m/s
1165862
0.0
2.0
4.0
6.0
8.0
10.0
12.0
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0
lDISS (turn) - Meas
l DIS
S (tu
rn) -
Pre
d
+30%
-30%
Point Labels = lSi/dp
7-17
Slide # 7-33
lDISS (Pred) vs. lDISS (Meas) for Dh = 0.74 m and vSL = 0 m/s
11262
15
28
115
227
2324
53
94
54
277273
0
2
4
6
8
10
12
14
0 1 2 3 4 5 6 7
lDISS (turn) - Meas
l DIS
S (tu
rn) -
Pre
d
+30%
-30%
Point Labels = lSi/dp
Comparison StudyvSL = 0 m/s , Dh = 0.74 m
vSG= 1 m/s vSG = 5 m/s vSG = 10 m/s
Slide # 7-34
lDISS (Pred) vs. lDISS (Meas) for Dh = 0.74 m and vSL = 0.05 m/s
8268
110
83
150144
264262
52
311
270
68
39
0.0
2.0
4.0
6.0
8.0
10.0
12.0
14.0
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0
lDISS (turn) - Meas
l DIS
S (tu
rn) -
Pre
d
+30%
-30%
Point Labels = lSi/dp
Comparison StudyvSL = 0.05 m/s , Dh = 0.74 m
vSG= 1 m/s vSG = 5 m/s vSG = 10 m/s
7-18
Slide # 7-35
lDISS (Pred) vs. lDISS (Meas) for Dh = 0.74 m and vSL = 0.1 m/s
28
38
82
137
285
319
97
5145
129
0.0
2.0
4.0
6.0
8.0
10.0
12.0
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0
lDISS (turn) - Meas
l DIS
S (tu
rn) -
Pre
d +30%
-30%
Point Labels = lSi/dp
Comparison StudyvSL = 0.1 m/s , Dh = 0.74 m
vSG= 1 m/s vSG = 5 m/s vSG = 10 m/s
Slide # 7-36
lDISS (Pred) vs. lDISS (Meas) for Dh = 0.74 m and vSL = 0.5 m/s
6489
89
129
86127 333
608
423138
132184
0.0
2.0
4.0
6.0
8.0
10.0
12.0
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0
lDISS (turn) - Meas
l DIS
S (tu
rn) -
Pre
d
+30%
-30%
Point Labels = lSi/dp
Comparison StudyvSL = 0.5 m/s , Dh = 0.74 m
vSG= 1 m/s vSG = 5 m/s vSG = 10 m/s
7-19
Slide # 7-37
Comparison StudyModel Performance
9 11 10
11
52
1625
1711
05
10152025303540
30 45 60 100 235lSi/dp
Test
s
Error > (+/-) 30% Error <= (+/-)30%
Slide # 7-38
Comparison StudyModel Performance
9 11 10
11
52
1625
1711
05
10152025303540
30 45 60 100 235
Test
s
42%35%31%20%11%Abs (Rel. Error)
-0.9%
28%
25%8%-11%-17%-9%Rel. Error
Tot.Avg
7-20
Slide # 7-39
Future Work
� Determine Uncertainty of Data and Model
� Develop Design Procedure and Code
Slide # 7-40
Thanks for your attention!
May 20, 2003
TUSTP 2003
DOE Project:Mechanistic Modeling of
Slug Dissipation in Helical Pipes
8 - 1
TUCoRE Project:Dispersion Characterization Rig
(DCR)
byLuis E. Gomez
May 20, 2003
TUSTP 2003
Overview
� Background� Technical Goals� Basic Features and Capabilities of DCR� Project Status
8 - 2
Why Dispersion Characterization?
� Heavy oil dispersions are problematic� Cold oil-water dispersion flow from deepwater
� Emulsion viscosity� Effect of chemicals
� Processing and separation� Emulsion� Foaming� Separation time� Compact - platform, FPSO, or subsea
Technical Goals
� Scale Up: geometry and fluid properties� Quantification of bench test results� Droplet dynamics
• Formation, Breakup, Coalescence
• Settling Velocities vs, d, C, ��������e
• Rheology (Effective Viscosity)
� Foam and Emulsions � Inversion point� Multi-emulsion tendencies� Stabilization effect of gas, solids, chemicals
8 - 4
DCR Capabilities
StatOil Facility
clear oil
clear w ater
sedimentation zone
dense-packed zone
coalescing interface
sedimenting interface
� Working Pressure: Up to 6000 psi
� Working Temperature: -20 to 150°C
� Range �: 0.1 cp to 2000 cp
� Fast connections
Capillarity Viscometer
8 - 5
2003 Status� Feasibility Study (Phase I) completed
� Visited Several Labs� Phillips (USA), Norsk Hydro (Norway), Statoil (Norway),
NTNU (Norway)� Discussed Collaborations
� Selected Commercial DCR� French supplier – Sanchez� Selected basic unit
� Phase II Approved - activities initiated � Purchase Order Placed on Sanchez Technologies
� Delivery Expected in May/June 2003� Visit Norway and France to incorporate
Design Improvements of Statoil in Sanchez DCR Rig� Received training in February, 2003
Initial Testing
� Model Fluids � Low Pressure and Temperature� Scale Up of Lab Tests� O/W Droplet Breakup through Chokes
8 - 6
Hebron Ben Nevis Emulsion ViscosityInversion at 37 % Water Cut
0.0
2000.0
4000.0
6000.0
8000.0
10000.0
12000.0
0 20 40 60 80 100 120
Water Cut, %
App
aren
t Vis
cosi
ty, c
P
-2 C0 C10 C20 C30 C40 C60 C85 C
Range of data measured for emulsion model
Conditions which can occur during shut-ins
Impa
ct o
f Em
ulsi
o n R
heol
ogy
on
Dee
p wa t
e rS u
bsea
S yst
e m
Ope
r at io
n s
Typical DCR Study Results
8 - 7
2003 Major Milestones
� Purchase, Install and Commission Equipment� Safety Training: Process Hazard Analysis (done)� DCR Testing
� Comparative tests on chokes etc.• Compare to batch separator data and models
� Develop Test Program for Model Fluids• Salager and Sjoblom “Recipes”
� Cooperation between NTNU (Norway) – TUSTP� Cooperation between ULA (Venezuela) – TUSTP
9-1
TUSTP 2003
byVinod Kumar
May 20, 2003
Event Simulation & Diagnostics of GLCC� Multiphase Metering System
Overview
� Background� Objectives� Process Hazard Analysis� Need of a Diagnostic System for GLCC©
� Development of Diagnostic System for GLCC©
� Simulate Field Conditions� Future Activities
9-2
Background
� GLCC Multiphase Configurations:� Metering� Bulk Separation� Pre-Separation /
Debottlenecking� Gas-Knockout
Objectives
� Process Hazard Analysis for GLCC System� Develop a Diagnostic System for Possible Hazard Events
� Simulate Various Problems Encountered in Field Operation (start up, shut down, hardware failure, severe slugging, system upset, etc.) for GLCC�
� Identify the Critical Issues
� Make Specific Recommendations
9-3
� LCV Failed at North Campus-TUSTP� LCV Failed at Minas LOSF Area-1� Level Control Failure Due to Improper
Installation/Selection of dp Transducer
Problems Reported
Diagnostics
� LCV Failure (TUSTP)
� Moisture in the Instrumentation Air Line
� Loss of Data
� LCV Failure (Minas)
� Don’t Know the Reason of LCV Failure
� Cause of Oil Relief to Environment (Control configuration)
� Level Control Failure
� Non-usage of Isolation Diaphragm for the dp Cell
9-4
� Answer is YES!!!!� We Should have Process Hazard Analysis for GLCC
System!
Can there be more Probable Events?
Process Hazard Analysis of GLCC
Hazard and Operability Study
What-If Check List
Preliminary hazard Analysis
Failure Modes and Effect Analysis
Human Reliability Analysis
Cause – Consequence Analysis
Fault Tree
Event Tree
PHA
9-6
� Nodes of the System� Liquid Control Valve� Gas Control Valve� Single Phase Meters� GLCC Upper & Lower Sections� Gas and Liquid Legs� Control System� Differential Pressure Sensor� Level Transducer
Identification of Sections of GLCC
� A consistent Strategy is considered for the risk criteria employed in a risk assessment, in order to minimize risk levels, as far as is reasonably possible
� Risk Levels Concerned� Risk to Personnel (safety)� Risk to Environment� Risk to the Public� Financial Risk
Risk Acceptance Criteria - PHA
9-7
Risk Matrix
33333IV
33221
III
32211
II
32111I
EDCBA
�Probability DefinitionsA - Possibility of Repeated
Incidents B - Possibility of Isolated IncidentsC - Possibility of Occurring
SometimeD - Not Likely to OccurE - Practically Impossible
� Consequence Definition(Personnel)I- Fatalities II – Serious Injury to PersonIII – Medical Treatment for
PersonnelVI - Minor impact on Personnel,
First aid only
Definition of Probability and Consequence
9-8
� Need for a Diagnostic System� Notification of the Specific Failure� Check if Sub System Working Fine� Safety
Diagnostics System for GLCC
Probable Events of Malfunctioning of Sub System
� LCV Failure� No Signal from LCV � Action of LCV is as Expected
� GCV Failure� No Signal from GCV� Action of GCV as Expected
� Pressure in Pneumatic Line is High/ Low� Level Shoot-Up in GLCC – Might Upset the Gas System if
Connected to the Gas Leg� No Signal from Controller and � Probable Failures Related to Sensors, Transducers
9-9
Working of a Diagnostic System
Link Diagnostic System to Process Control
Is GLCC Sub-Syst.Working as Expected?
Show Green Light for the Sub-System
Buzz Beep, Show Red Light
Stop
NO YES
Diagnostic System Layer for GLCC
9-10
Diagnostics of LCV
� Check for Signal from LCV� If signal not present – Buzz a Beep� If Signal Detected – Check if LCV Opens and Closes in the
Right Direction as per the Liquid Level in GLCC� If Yes! - Show Green Light on Diagnostic Board� If No! -Red Light, Buzz a Beep , Stop the System and
Display Related Error Message
View of a Diagnostic Board
�LCV Working Fine �LCV Malfunctioning
9-11
Lab View –Checks LCV
Event Simulation
� Simulate the Field Conditions on Lab View:� Start-up Conditions
� Shut-down Conditions
� Hardware Failure
� Combine Simulator with Diagnostic System
9-12
Start-up
� Simulate Start up Flow Conditions:� Flow Increases from Zero to a very high Quantity
� Nature of Behavior of Control Valves to this Variation of Flow in Short Time
� Nature of Change in Liquid Level in GLCC
� Response of Diagnostic System to Sudden Rise in Liquid Level in GLCC
Shut-Down
� Simulate Shut Down Flow Conditions:� Flow Decreases from a very high value to zero
� Nature of Behavior of Control Valves to this Variation of Flow in Short Time
9-13
Hardware Failure
� Simulate Hardware failure Conditions:� Failure of Control Valves
� Wrong / No Connection of Hardware Used
� Malfunctioning / Failure of Meters / Transducers
� Diagnostic System to Detect Such Events and Response to Avoid Hazard
Future Activities – Summer 2003
� Complete the PHA Analysis of the GLCC System� Develop the Simulator with Specific Hardware
Failure Events� Integrate the Diagnostic System with the Process
Layer to Detect Such Events and Response to AvoidHazard
� Test the Diagnostic System Under Real FailureConditions
10 - 1
Mechanistic Modeling and CFD Simulations of Oil-Water Dispersions
in Separation Components
TUSTP 2003
byCarlos F. Torres
May 20, 2003
Background
Objectives
Particle Tracking Model
Preliminary Results
Universal Dispersion Model
Topics
10 - 2
Knowledge of particle motion and phase distribution will enhance performance evaluation of separation equipment
TUSTP has used the Eulerian-Lagrangian technique to design and analyze performance of separation devices such as GLCC, LLCC and LLHC
Existing models carry out simulations considering mainly the following forces acting on a particle: drag and buoyancy
Additionally, these models assume particle local equilibrium
Background
The general objectives of this study are to develop models capable of characterizing hydrodynamics of multiphase dispersion flow in separations and piping components
Initially, study focuses on dilute and dense dispersed flow
Develop a mechanistic model for calculating droplet motion, considering the different acting forces
Determine dispersed phase void fraction
Validate and extend the three way coupling approach proposed by Gomez 2001
Objectives
10 - 3
General approach
Simplified approach
Future improvements
Particle Tracking Model
Particle Tracking:General Approach
Gomez 2001 presented a new Eulerian – Lagrangian mechanistic model:
Local equilibrium assumed for dispersed phase
Forces used: drag, lift, body force, added mass and pressure gradient
Model is one way coupling between continuous and dispersed phase, considering variation of interfacial area
10 - 4
Lagrangian Equation
0rrrrrrr
r
=+++++= otherpmbldp FFFFFFdtVdm
Forces on particle
Effects of continuous phase turbulence on particle:
Behzadi et al (2001) presented an averaging approach for effects of fluid turbulence on particles
Iliopoulos et al. (2003) presented a stochastic model for effects of turbulence in dispersed flow
Particle Tracking:Simplified Approach
Modifications of Gomez model (2001):
Forces considered: drag, lift and body force
Main goal is calculation of particle trajectory
Parametric technique (function of time) allows determination ofparticle’s residence time (integration 2nd order accuracy)
Particles are spherical and non-deformable, particle to particle interaction not considered (dilute dispersion)
One way coupling
3D solution developed for Cartesian and Cylindrical coordinate systems
10 - 5
Modified Gomez Model
Particle Position
bld FFFrrrr
++=0
∫∫∫+
+
+
+
+
+ +=+=+=1ti
tizii
1ti
tiyii
1ti
tixii dtVzzdtVyydtVxx 111
Forces on Particle
Particle Tracking:Future Improvements
Extend model capability to include:
Added mass force
Pressure gradient force (hydrodynamic)
Fluid turbulent effects
Particle transients effect
Develop mechanistic model for estimation of void fraction using stochastic approach
Explore limits of dilute flow assumption, and extend to dense flow
10 - 6
Preliminary Results
Particle Tracking in Pipe Flow
Particle Tracking in Conventional Separators
Particle Tracking: Pipe Flow
Mixing Length Velocity Profile
0 0.2 0.4 0.6 0.8 10
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
Laufer, J. 1951, (Re = 40000)U+ Inner LayerU+ Outher Layer
Dimensionless Velocity Profile
U+/Umax+
y+/R
et
τ
+
Rey
++ maxUU
10 - 7
θ = 0o, d = 5in, Vcont = 0.01 m/s. Water Continuous (1000 kg/m3, 1cp). Dispersed phase Oil (850 kg/m3), dp = 100 microns
Particle Tracking:Pipe Flow
Pipe length [m]
Pip
ehe
ight
[m]
0 0.5 1 1.5 2 2.5
-0.06
-0.04
-0.02
0
0.02
0.04
0.06
With lift force. Residence time = 161.53 sWithout lift force. Residence time = 99.35 s
X [m]
Y[m
]
-1 -0.5 0 0.5 1 1.5 2 2.5 30
0.5
1
1.5
2
2.5
Velocity Magnitude2.600E+002.463E+002.326E+002.189E+002.053E+001.916E+001.779E+001.642E+001.505E+001.368E+001.232E+001.095E+009.579E-018.211E-016.842E-015.474E-014.105E-012.737E-011.368E-010.000E+00
Fluent 6.0
Oildensity = 850 kg/m3
viscosity = 30 cp
Velocityat the inlet = 2 m/sat the interphase = 0.2 m/s
Diameterat the inlet = 0.1 mat the outlet = 0.1 m
Vesselliquid level = 1 m
Reynolds Numberat the inlet = 5666.7in the vessel = 5666.7
Fluent 12 Mar 2003 title
x [m]
Y[m
]
0 0.5 1 1.5 2 2.5 3 3.5 40
0.5
1
1.5
2
2.5
Vel2.600E+002.463E+002.326E+002.189E+002.053E+001.916E+001.779E+001.642E+001.505E+001.368E+001.232E+001.095E+009.579E-018.211E-016.842E-015.474E-014.105E-012.737E-011.368E-010.000E+00
Vessel 2D v1.0
Oildensity = 850 kg/m3
viscosity = 30 cp
Velocityat the inlet = 2 m/sat the interphase = 0.2 m/s
Diameterat the inlet = 0.1 mat the outlet = 0.1 m
Vesselliquid level = 1 m
Reynolds Numberat the inlet = 5666.7in the vessel = 5666.7
Vessel 2D 12 Mar 2003 Vessel
Particle Tracking:Conventional Separators
10 - 8
x [m]
Y[m
]
0 0.5 1 1.5 2 2.5 3 3.5 40
0.5
1
1.5
2
2.5
Vel2.600E+002.463E+002.326E+002.189E+002.053E+001.916E+001.779E+001.642E+001.505E+001.368E+001.232E+001.095E+009.579E-018.211E-016.842E-015.474E-014.105E-012.737E-011.368E-010.000E+00
Vessel 2D v1.0
Oildensity = 850 kg/m3
viscosity = 30 cp
Velocityat the inlet = 2 m/sat the interphase = 0.2 m/s
Diameterat the inlet = 0.1 mat the outlet = 0.1 m
Vesselliquid level = 1 m
Reynolds Numberat the inlet = 5666.7in the vessel = 5666.7
Vessel 2D 12 Mar 2003 Vessel
X [m]
Y[m
]
-1 -0.5 0 0.5 1 1.5 2 2.5 30
0.5
1
1.5
2
2.5
Velocity Magnitude2.600E+002.463E+002.326E+002.189E+002.053E+001.916E+001.779E+001.642E+001.505E+001.368E+001.232E+001.095E+009.579E-018.211E-016.842E-015.474E-014.105E-012.737E-011.368E-010.000E+00
Fluent 6.0
Oildensity = 850 kg/m3
viscosity = 30 cp
Velocityat the inlet = 2 m/sat the interphase = 0.2 m/s
Diameterat the inlet = 0.1 mat the outlet = 0.1 m
Vesselliquid level = 1 m
Reynolds Numberat the inlet = 5666.7in the vessel = 5666.7
Fluent 12 Mar 2003 title
Particle Tracking:Conventional Separators
Particle Tracking: Conventional Separators
Particle Residence Time = 2.63 s
Particle Density = 2500 kg/m3
Particle Diameter = 500 micron
10 - 9
Particle Tracking: Conventional Separators
X
Y
0 1 2 3 40
0.5
1
1.5
2
2.5
Frame 001 12 Mar 2003 Particle Tracking
Particle Residence Time = 2.362 s
Particle Density = 2500 kg/m3
Particle Diameter = 500 micron
Universal Dispersion Model
Gomez Model (2001)
The Eulerian field is known (average velocities, turbulent kinetic energy and energy dissipation)
Solve Lagrangian field using the proposed equation, to calculate slip velocity within flow fieldSolve diffusion equation using slip velocity information, to predict void fraction distributionCalculate bubble or droplet diameter using Eulerian turbulent quantities and void fraction distributionRepeat non-linear process until convergence is reached
10 - 10
Phase Coupling Model
Definition of Phase Coupling
One-way Coupling: Fluid flow affects particle while there is no reverse effect.
Two-way Coupling: Fluid flow affects particle and vice versa.
Four-way Coupling: Additionally from above, there are hydrodynamic interactions between particles, and turbulent particle collisions.
Three-way Coupling
Phase Coupling Model
( ) ( ) iiiji
j
j
i
jij
iji sisouuxu
xu
xxP
xuu
tu
TMP1++
′′−
∂
∂+
∂∂
∂∂
+∂∂
−=∂
∂+
∂∂
νρ
Dispersed phase momentum equation (average)
Continuous phase momentum equation (N- S Equation)
otherturbulencepmbldp
p FFFFFFFdtVd
mrrrrrrr
r
++++++=
Particle Source Term, MPso is estimated by coupling mass and momentum balances over control volume.
10 - 11
Two-way Coupling: Solution Scheme
PSI – Cell technique, Crowe et al. (1977)
Huber &Sommerfelt (1997).
Air continuousPhase. θ = 0o, d = 80 mm,V = 24 m/s,
Dispersed phaseρd = 2500 kg/m3
dp = 40 micron
Model Potential
LLCCDispersion of Oil in Water
with Water Layer at the BottomVm = 0.6 m/s W.C = 67%
11-1
TUSTP 2003
byVasudevan Sampath
May 20, 2003
Intelligent Control of
Compact Separation System
OverviewObjectivesLiterature ReviewCompact Separation SystemReview of Control System DevelopmentFuzzy Logic SystemArtificial Neural Network SystemFuture Plans
11-2
ObjectivesConduct a detailed study on advanced control systems like fuzzy logic, neural network etc. and study their suitability for compact separation system.
Develop an intelligent control strategy for compact separation system and conduct dynamic simulation and experimental investigation on the developed strategy.
Literature Review
Control System Studies:Wang (2000) : Dynamic Simulation, Experimental Investigation and Control System Design of GLCC
Dorf & Bishop (1998): Modern Control SystemsGrimble (1994): Robust Industrial Control Friedland (1996): Advanced Control System Design
11-3
Fuzzy Logic and Neural Networks:McNeill and Thro (1994): Fuzzy LogicLeondes (1999): Fuzzy Theory Systems –Techniques and Applications Terano, Asai and Sugeno (1994): Applied Fuzzy SystemsPassino and Yurkovich (1998): Fuzzy ControlReznik (1997): Fuzzy Controllers
Literature Review
Compact Separation System 1
Clean
Water Rich
Oil Rich
GLLCC (3-phase)
Pipe Type Separator
GLCC (Scrubber)
LC
PC
LC
WCC
WCC FC
Pump
Clean OilOil
Water Rich
Oil Rich
GLLCC (3-phase)
Pipe Type Separator
GLCC (Scrubber)
ManifoldSlug Damper
LCLC
PCPCClean GasClean GasLCLC
WCCWCC
WCCWCC
Hydrocyclones
LLCCPRC
PRC
Hydrocyclones
LLCC
FCFC PRCPDC
PDC
PumpPump
Clean Water
LC-Level Control
PC-Pressure Control
WCC-Water cut Control
FC-Feed Control
PDC-Press. Diff. Control
11-4
Compact Separation System 2
PCPC
LCLC
Clean Gas
LCLC
Hydrocyclones
LLCCPRC
PRC
Hydrocyclones
LLCC
FCWC PRCPDC
PDC
PumpPump
WCCWCCGLCC (Scrubber) Pipe Type
Separator
Clean OilOil
ManifoldSlug Damper
GLCC
Liquid Stream
Gas Stream
Clean Water
LC-Level Control
PC-Pressure Control
WCC-Water cut Control
FC-Feed Control
PDC-Press. Diff. Control
No.
APPLICATION CLASSES
Pass
ive
Con
trol
Sys
tem
Liqu
id L
evel
Con
trol
with
LC
V O
nly
Liqu
id L
evel
Con
trol
with
GC
V O
nly
Hyb
rid L
CV
and
GC
V Le
vel C
ontr
ol
Pres
sure
Con
trol
with
GC
V
Liqu
id L
evel
Con
trol
with
LC
V an
d Pr
essu
re C
ontr
ol w
ith G
CV
Flow
Rat
e C
ontr
ol w
ith L
CV
and
GC
V
Pred
ictiv
e C
ontr
ol o
f GLC
C
usin
g Sl
ug D
etec
tion
GLC
C O
ptim
al a
nd A
dapt
ive
Con
trol
- M
ovin
g Se
t poi
nt
Wat
ercu
t Con
trol
Sys
tem
GVF
Con
trol
Sys
tem
Rob
ust C
ontr
ol W
ith
Gai
n Sc
hedu
ling
Mod
ern
Con
trol
- Fu
zzy
Logi
c C
ontr
ol
Inte
llige
nt C
ontr
ol -
Art
ifici
al N
eura
l Net
wor
k
Dow
nStr
eam
ON
/OFF
Pu
mp
Con
trol
GLC
C D
ual I
nlet
Con
trol
GLC
C V
aria
ble
Are
a In
let C
ontr
ol
1 Remote Powerless GLCC Operation X2 Remote GLCC Operation With Power X X X X X X X X X X X3 Well Testing (Recombined Flow) X X X X X X X X X X X X4 Bulk Separation (Separator Stand Alone) X X X X X X X X X X5 DownStream Surge Tank Control X X6 Separation of Wet Gas (raw Gas Lift) X X X X X X X X X X X
7Separation of Low-Medium GOR (Liquid Dominated) X X X X X X X X
8 Separator subjected to Severe Slugging X X X X X
9Integrated Separation systems - 2 Stage GLCCs X X X X X X X X
10 GLCC with Liquid Hydrocyclones X X X X X X X X X11 GLCC Upstream of pumps X X X X X X X X12 GLCC with Conventional Separators X X X X X X X X X X X13 Subsea Application X X X X X X X X X14 Downhole Applications X X X X X
15Non-Petroleum Application - Liquid Metering X X X X X
16Non-Petroleum Application - Gas Metering X X X X X X
17 FREE-WATER Knockout with LLCC X X X X X X X X X18 GLCC/LLCC Integrated System Control X X X X X X X X X X X X X X X19 GLCC for Environmental Applications X X X X X X
CONTROL STRATEGIES
11-5
Control System Development Stages
1st Stage: Frequency –response design methods for scalar systems by Nyquist, Bode
2nd Stage: The state-space approach to optimal control and filtering theory
3rd Stage: Multivariable systems by frequency-domain design methods (MIMO)
4th Stage: Robust design procedures - H∞ design philosophy
5th Stage: Advanced techniques – Fuzzy Logic, Neural Networks, Artificial Intelligence.
Adaptive Versus Robust Control
Adaptive Control – Estimates parameters and calculates the control accordingly. Involves online design computations, difficult to implement.
Robust Control – This allows for uncertainty in the design of a fixed controller, thus, producing a robust scheme, which is insensitive to parameter variations or disturbances. H∞ robust control philosophy provides optimal approach to improve robustness of a controlled system.
11-6
Limitations of Conventional Controllers
Plant non-linearity: Nonlinear models are computationally intensive and have complex stability problems.
Plant uncertainty: A plant does not have accurate models due to uncertainty and lack of perfect knowledge.
Uncertainty in measurements: Uncertain measurements do not necessarily have stochastic noise models.
Temporal behavior: Plants, Controllers, environments and their constraints vary with time. Time delays are difficult to model.
Fuzzy Logic Control
Crisp man Fuzzy man
How are you going to park a car ?
It’s eeeeassy……!
Just move slowly back and avoid any obstacles.
You have to switch to reverse, then push an accelerator for 3 minutes and 46 seconds and keep a speed of 15mph and move 5m back after that try………..
11-7
Benefits of Fuzzy Logic Controller
Can cover much wider range of operating conditions than PID and can operate with noise and disturbance.
Developing a fuzzy logic controller is cheaper than developing a model-based controller.
Fuzzy controllers are customizable. Since it is easier to understand and modify their rules.
Operation of Conventional Controller
PID Controller
PLANTInput Output
Feedback Signal
11-8
Operation of Fuzzy Logic Controller
OutputF u
z zif i
c ati o
n
Def
uzzi
ficat
ion
Inference mechanism
Rule-base
PLANT
Reference Input r(t) Input u(t)
Fuzzy Controller Operation
Choosing Inputs
Measuring Inputs
Scaling Inputs
Fuzzification
Fuzzy Processing
Defuzzification
Scaling Outputs
PLANT
InputscalingfactorsInputs membership functions
Fuzzy rules
OutputsMembership functionsOutputs Scaling factors
11-9
Neural Network Process Control Loop
Sensing System
Neural Network Analysis System
Neural Network Decision System
Plant Operating SystemInput Output
Basic Artificial Neural Network
11-10
Basic Artificial Neural Network
Feed forward ANN – a,b
Feed back ANN - c
Advantages of Neural Network
Simultaneous use of large number of relatively simple processors, instead of using very powerful central processor.
Parallel computation enables short response times for tasks that involve real time simultaneous processing of several signals.
Each processor is an adaptable non linear device.
11-11
Neuro Fuzzy Systems
Neural Networks are good at recognizing patterns, not good at explaining how they reach that decision
Fuzzy logic are good at explaining their decision but they cannot automatically acquire the rules they use to make those decisions
Central hybrid system which can combine the benefits of both areused for intelligent systems
Complex domain like process control applications require such hybrid systems to perform the required tasks intelligently
In theory neural network and fuzzy systems are equivalent in that they are convertible, yet in practice each has its own advantages anddisadvantages
Applications
Fuzzy Logic and Neural Network applications to compact separation system:
Dedicated control system for each component, like GLCC or LLCC
Sensor fusion – improvement in reliability and robustness of sensors
Supervisory control – intelligent control system with diagnostics capabilities.
11-12
Future Plans
1. Develop dedicated control systems for each component using neural network or adaptive control system.
2. Develop sensor fusion modules using neural networks to improve the quality of measured signal.
3. Develop intelligent supervisory control system for overall control, monitoring and diagnostics of the process.
12 - 1
TUSTP 2003
Carlos Avila
May 20, 2003
DOE Project:
Interfacial Phenomena in Oil - Water Dispersions
�Introduction�Objectives�Modeling Approach�Proposed Experimental Program�Future Work
Overview
12 - 3
Objectives
�Study fundamental oil-water interfacial phenomena (small-scale). Based on fundamental phenomena, develop models capable of predicting oil-water dispersion flow behavior (large-scale)
� Include studies on coalescence and break-up, segregation and droplet size distribution
�Validate developed models against current applications measurements
Mathematical Approach
• Hafskjold (1997)• Haugen & Søntvedt (1999)• Jeelani & Hartland (1998)
�Interfacial Phenomena:
�Droplet Size Distributions:• Simmons & Hanratty (2000)• Karabelas (1978)
�Coalescence & Break-up:• Gomez (2001)
12 - 4
Mathematical Approach
General Model
• Electrostatic Coalescer
• Batch Separator
• Oil Slugs in GLCC
++++++
++++
------
----
Proposed Experimental Program
• GLCC underflow watercut oscillations for different inlet tangential velocities and inlet watercut
• Oil slugs creation due to GLCC watercut gradient
� 3-Phase GLCC behavior:
12 - 5
Proposed Experimental Program
• DCR
• GLCC©
Future Work
�Fundamental oil-water interfacial behavior research and development
� Include effects due to molecular interaction (steric repulsion, hydrodynamic effects, electro-kinetic effects and others)
�Develop models for large scale phenomena prediction
12 - 6
Future Work
�Data acquisition to validate models in specific applications
�Cooperate with other institutions for data gathering and model validation
13-1
TUSTP 2003
byErzhan Kuantaev
May 20, 2003
Evaluation of Oil-Water Flow through
Piping Restrictions
Outline
�Introduction�Objectives�Experimental Results�Conclusion�Future Work
13-2
Introduction
• Flow conditioning upstream of compact separators can improve their performance and separation efficiency
• Study of water-oil mixture flow through different piping restrictions can help reduce droplet breakup and promote coalescence
Objectives
�Compare oil-water separation in Batch Separator for different restrictions
�Improve design of restrictions for more efficient oil-water separation
13-3
Experimental Program
�Experimental Facility
�Experimental Results
By pass valve
Batch Separators
Flow Restrictions
Floor Level
5’
1.5’
2’
15’ - 20’
Inlet Outlet
Experimental Facility
13-5
Batch Separator
Experimental Results
�Text matrix:
- Orifices – square and circular
- Rectangular venturi and channel
- Water cut (25%, 50%, 75%)
- Mixture velocities (1 - 5 ft/s)
13-6
Orifice ResultsVm=1.5 ft/s, WC=50%
0.00
5.00
10.00
15.00
20.00
25.00
30.00
35.00
40.00
45.00
0 200 400 600 800 1000
Time (sec.)
WH, O
H (cm
) WH (Circular)OH (Circular) WH (Square)OH (Square)
Orifice Results
0
200
400
600800
1000
1200
1400
10.0 20.0 30.0 40.0 50.0
Orifice Mixture Velocity (ft/s)
95%
Sep
arat
ion
Tim
e (s
ec.)
WC=25% (Circular) WC=50% (Circular) WC=75% (Circular)WC=25% (Square) WC=50% (Square) WC=75% (Square)
13-7
Orifice Results
100200300400500600700800900
1000110012001300
0.00 2.00 4.00 6.00 8.00
DP, psid
95%
Sep
arat
ion
Tim
e, s
ec
WC=75% (Square) WC=50% (Square) WC=75% (circular)WC=50% (circular) WC=25% (Square) WC=25% (circular)
Orifice ResultsPressrue Drop Comparison
1.00
2.00
3.00
4.00
5.00
6.00
7.00
8.00
0.0 5.0 10.0 15.0 20.0 25.0 30.0 35.0 40.0 45.0
Orifice Mixture Velocity, ft/s
Pres
sure
dro
p, p
sid
WC=75% (Square) WC=50% (Square)
WC=25% (Square) WC=75% (Circular)
WC=50% (Circular) WC=25% (Circular)
13-8
Venturi ResultsVm=2.5 ft/s, WC=75%
28.00
30.00
32.00
34.00
36.00
38.00
40.00
42.00
44.00
0 50 100 150 200 250 300 350 400 450 500
Time (sec.)
WH,
OH
(cm
)
"OH - Rectangular""WH - Rectangular""OH - Venturi""WH - Venturi"Final separation time
Venturi Results
0200400600800
10001200
0.0 10.0 20.0 30.0 40.0 50.0Nozzle Mixture Velocity, ft/s
95%
Sep
arat
ion
time,
sec
WC=25% (Venturi) WC=25%(Rectangular) WC=50% (Venturi) WC=75% (Venturi)WC=50% (Rectangular) WC=75% (Rectangular)
13-9
Venturi Results
00.5
11.5
22.5
33.5
44.5
0.0 10.0 20.0 30.0 40.0 50.0
Nozzle Mixture Velocity (ft/s)
DP (p
sid)
WC=25% (Venturi) WC=50% (Venturi)WC=75% (Venturi) WC=25%(Rectangular)WC=50%(Rectangular) WC=75%(Rectangular)
Conclusions
� Orifice
- Separation time less for flow through circular geometry as compared to rectangular geometry
- Pressure drop almost the same for both geometries
13-10
Conclusions
�Venturi
- Separation time less for venturi geometry as compared to rectangular channel
- Venturi exhibits less pressure drop than rectangular channel
Future Work
�More data needs to be acquired for higher pressure drop
�More studies needed to understand effect of different restriction geometries on droplet breakup/coalescence
�Improve instrumentations (Laser/Fiber Optic)
� Develop model for prediction of droplet size distribution through piping restrictions
A-1
TUSTP ADVISORY BOARD MEMBERS 2002/2003
Gene Kouba, Ph.D. Sr. Staff Research Scientist Advanced Production Tech. CHEVRONTEXACO Room 4107c 2811 Hayes Rd. Houston, TX 77082 Ph.: 281-596-2485 Fax: 281-596-2620 or 3009 e-mail: [email protected] www.chevrontexaco.com Jack Marrelli, Ph.D. Research Associate Production & Facility Optimization CHEVRONTEXACO Room #4141 2811 Hayes Road Houston, TX 77082-6696 Ph.: 281-596-2604 Fax: 281-596-2150 Cell: 713-826-9619 (7AM to 7PM) [email protected] www.chevrontexaco.com Ing. Horacio Gamboa Florez Jefe Tecnologias Complementarias Edelmira Afanador ECOPETROL Instituto Colombiano Del Petroleo Centro De Investigacion Y Desarrollo Autopista Bucaramanga Piedecuesta Km. 7, Santander A.A.4185 Bucaramanga, COLOMBIA Ph.: 011-57-76-445-420 x 7201 Fax: 011-57-76-445-444 Edelmira/Secretary: 011-57-76-740-226/264 e-mail: [email protected] e-mail: [email protected] www.ecopetrol.com.co
Joey Raskie Applications Specialist Coriolis Oil & Gas EMERSON PROCESS MANAGEMENT Micro Motion, Inc. 9720 Old Katy Road Houston, TX 77055 Ph.: 713-827-3356 Fax: 713-827-4360 [email protected] Denman Cloudt G. Joel Rodger, P.E. Manager of Metering Systems eProduction Solutions 10801 Hammerly, Suite 232 Houston, TX 77043 Ph.: 713-461-7995 Fax: 713-461-2675 Mobile: 832-755-2055 e-mail: [email protected] [email protected] www.eproductionsolutions.com John Lievois Ph.D. P.E. eProduction Solutions, Inc. Ph.: 713-461-7995 Cell: 281-851-3603 Fax: 713-461-2675 e-mail: [email protected] Emil J. Klein Jim Bennett Gas and Facilities Division EXXONMOBIL UPSTREAM RESEARCH COMPANY P.O. Box 2189 Houston, TX 77252-2189 Ph.: 713-431-6233 (EK) Ph.: 713-431-7811 (JB) Fax: 713-431-6387 [email protected] [email protected]
A-2
Ted Frankiewicz Vice President Liquid Process Solutions NATCO Group-US Brookhollow Central 111 2950 N. Loop West, 7th Floor Houston, TX 77092 Ph.: 713-685-8012 Fax: 713-975-9611 e-mail: [email protected] www.natcogroup.com/index2.html Mike Brown Senior Development Engineer Gary Sams Director, R&D NATCO-Group 10910 E. 55th Place Tulsa, OK 74146 Ph.: 918-660-7151 (GS) Ph.: 918-660-7152 (MB) Fax: 918-622-8058 e-mail: [email protected] e-mail: [email protected] www.natcogroup.com/index2.html A.K. Sah Deputy General Manager (P) Anand Gupta Superintending Engineer (P) Vineet Singhal Superintending Engineer (P) OIL AND NATURAL GAS CORPORATION LTD. (ONGC) IOGPT/ONGC ONGC Complex, Phase II Panvel, Raigad, Maharastra- 410221 INDIA Ph.: 91-(22) 7451148 (office) Fax: 91-(22) 7451690 e-mail: [email protected] e-mail: [email protected] e-mail: [email protected] www.ongcindia.com Jose Luis Trallero, Ph.D. E&P Technology Leader Dtto. Punta de Mata Exploration & Production PDVSA/INTEVEP Los Teques, Edo. Miranda Apdo 76343 Caracas 1070A
VENEZUELA Ph.: 011-58-2-908-6775 Fax: 011-58-2-908-7818 e-mail: [email protected] www.pdvsa.pdv.com Faustino Fuentes-Nucamendi, Ph.D. Gerencia de Sistemas de Produccion Subdireccion do Tecnologia y Desarrollo Profesional PEMEX EXPLORACION Y PRODUCCION Primer Piso, Edif. Piramide Av. Adolfo Ruiz Cortinez 1202 Villahermosa, Tabasco, 86030 MEXICO Ph.: 52-93-101-765 Fax: 52-93-10-18-89 e-mail: [email protected] Margarita Avila (Adm. Sec.) www.pemex.com Robert Smith, CEO SYSTEMS MEASUREMENT SERVICES (SMS) INC. 7000 Meany Ave. Bakersfield, CA 93308 Ph.: 661-589-7686 800-588-7686 Fax: 661-589-6883 e-mail:[email protected] www.systemsmeasurement.com Emile Leporcher TOTALFINAELF Centre de Recherche Jean Feger Avenue Larribau Pau, 64018 FRANCE e-mail: [email protected] Chris Roger TotalFinaElf Services, Inc. Research Center AtoFina 900 First Avenue King of Prussia, PA 19406 e-mail: [email protected] Contacts: [email protected] [email protected]
A-3
[email protected] [email protected] [email protected] [email protected] www.totalfinaelf.com/ho/en/index.html [email protected] Rick Todd Underbalanced Drilling Services, R&D WEATHERFORD INTERNATIONAL 11909 Spencer Road FM 529 Houston, TX 77041 Ph.: 713-983-5323 Fax: 713-983-5061 Mobile: 832-566-2576 Paul West Project Manager James L. Barnes Project Manager Rhonda Lindsey Senior Project Manager NETL/DOE Williams Center Tower One One West Third St., Suite 1400 Tulsa, OK 74103 Ph.: (PW) 918-699-2035 Ph.: (JB) 918-699-2076 Ph.: (RL) 918-699-2037 Fax: 918-699-2005 e-mail: [email protected] e-mail: [email protected] e-mail: [email protected]
A-4
TUSTP FACULTY AND STAFF Ovadia Shoham, Ph.D. Professor of Petroleum Engineering Director, TUSTP L109 KEH, The University of Tulsa 600 South College Avenue Tulsa, OK 74104-3189. USA Ph.: 918-631-3255 Fax: 918-631-2059 e-mail: [email protected] Ram S. Mohan, Ph.D. Associate Professor of Mechanical Engineering Associate Director, TUSTP L169 KEH, The University of Tulsa 600 South College Avenue Tulsa, OK 74104-3189. USA Ph.: 918- 631-2075 Fax: 918-631-2397 e-mail: [email protected] Luis Gomez, Ph.D. Visiting Assistant Professor Department of Petroleum Engineering Research Associate, TUSTP The University of Tulsa 600 South College Avenue Tulsa, OK 74104-3189. USA Ph.: 918- 631-2972 Fax: 918- 631-2059 e-mail: [email protected] Shoubo Wang, Ph.D. Visiting Assistant Professor Department of Petroleum Engineering Research Associate, TUSTP The University of Tulsa 600 South College Avenue Tulsa, OK 74104-3189. USA Ph.: 918-631-3041 Fax: 918-631-2059 e-mail: [email protected]
Judy Teal Administrative Assistant, TUSTP L111 KEH, The University of Tulsa 600 South College Avenue Tulsa, OK 74104-3189. USA Ph.: 918-631-2048 Fax: 918-631-2059 e-mail: [email protected]
A-5
PROSPECTIVE MEMBERS/FRIENDS K.T. Liu General Manager ACCUFLOW, INC. 3566 Dartmouth Lane Rowland Heights, CA 91748 Ph.: 562-691-5343 Fax: 562-691-5643 e-mail: [email protected] Jeffery P. Henning, M.S.(ChE) Project Manager, CFD Consulting Services AEA TECHNOLOGY 2000 Oxford Drive, Suite 610 Bethel Park, PA 15102 Ph.: 412-833-4820 Fax: 412-833-4580 e-mail: [email protected] www.aeat.com/cfx Shauna L. Wilson Senior Production Engineer Thermal Recovery Business Unit AEC OIL & GAS 3900, 421 – 7th Avenue S.W. Calgary, Alberta, Canada T2P 4K9 Ph.: 403-298-2855 Fax: 403-231-3697 Cell: 403-813-9525 e-mail: [email protected] www.aec.ca Michael O. Bridges Chief Engineer ANADARKO 1201 Lake Robbins drive The Woodlands, TX 77380 P.O. Box 1330, Houston, TX 77251-1330 Ph.: 832-636-3287 Fax: 832-636-8209 e-mail: [email protected] Andy Bennett BP Exploration, Deepwater Technology Unit, 1st Floor, Compass Point, 79-87 Kingston Road, Staines, Middlesex, TW18 1DY, UK Ph.: 44-1932-774816
Fax: 44-1932-774833 e-mail: [email protected] Donald D. Uphold, Ph.D. Senior Facilities Engineer, NFDT CALTEX PT Caltex Pacific Indonesia Minas 28885 Riau, Indonesia Ph.: (0761) 99-3155 Fax: (0761) 99-3440, 99-1226 e-mail: [email protected] Charles Britton Senior Staff Engineer CEESI Colorado Eng. Experiment Station, Inc. 54053 WCR 37 Nunn, CO 80648 Ph.: 970-897-2711 Fax: 970-897-2710 e-mail: cbritton@ceesi,com www.ceesi.com Robert (Bob) Chin President CDS SEPARATION TECHNOLOGIES 1500 S. Dairy Ashford, #441 Houston, TX 77077 Ph.: 281-589-8325 Fax: 281-589-8393 Cell: 281-788-6948 e-mail: [email protected] www.cds-separation.com Joe W. Westmoreland CHEVRONTEXACO Energy Research and Technology Co. Safety Engineer 4800 Fournace Place, Room 320L BOB Bellaire, TX 77401 Ph.: 713-432-6528 Cell: 832-794-0427 Fax: 713-432-2234 [email protected]
A-6
Mike Choi Senior Staff Engineer Infrastructure Structure Technology CONOCO, INC. Dubai, 2092 Post Office Box 2197 Houston, TX 77252-2197 Ph.: 281-293-1207 Fax: 281-293-2158 e-mail: [email protected] Paul Gillis, Research Leader Fluid Mechanics and Mixing Group DOW CHEMICALS 2301 N. Brazosport Blvd, B-1225 Freeport, TX 77541 Ph.: 409-238-1384 Fax: 409-238-0401 e-mail: [email protected] Bambang N. Gyat Director ENERKON ENGINEERS AND CONSTRUCTORS PT. Erraenersi Konstruksindo Ciladak Apartment, Ground Floor JL. T.B. Simatupang, Jakarta 12430 Ph.: 62-21-750 4963 Ext 105-115 Fax: 62-21-765 4984 e-mail: [email protected] Martin Tallett Principal ENSYS YOCUM INC. P.O. Box 2320 Flemington, NJ 08822 Ph.: 908-788-7332 Fax: 908-782-3768 e-mail: [email protected] Barbara Hutchings, Director Ahmad H. Haidari Strategic Partnerships FLUENT INC. 10 Cavendish Court Lebanon, NH 03766 Ph.: 603-643-2600 x 312 Fax: 603- 643-3967 e-mail: [email protected] (Barbara) e-mail: [email protected] (Ahmad) www.fluent.com
Daniel R. Sweet Director Business Development South THE FOXBORO COMPANY P.O. Box 597 Cypress, TX 77410 Ph.: 281-655-4999 Fax: 281-655-7109 Cell: 281-684-7557 e-mail: [email protected] www.foxboro.com Robbie Lansagan The Foxboro Company Ph.: 281-599-7832 832-794-3430 Miguel Gazzaneo Invensys Process Systems, Inc. THE FOXBORO COMPANY 10707 Haddington Dr. Houston, TX 77043 Ph.: 713-722-5371 Fax: 713-722-5753 e-mail: [email protected] Ferhat Metin Erdal Engineering Specialist/Project Engineer INTEC ENGINEERING, INC. 15600 JFK Boulevard Ninth Floor Houston, TX 77032 Ph.: 281- 925-2435 Fax: 281-925-2379 e-mail: [email protected] www.intec-hou.com Mark Hoyack Vice President, Industrial Division KREBS ENGINEERS 5505 West Gillette Road Tucson, AZ 85743 Ph.: 520-744-8200 Fax: 520-744-8300 e-mail: [email protected] Hank Rawlins, P.E. Technology Manager Jo Jernsletten Ove F. Jahnsen KVAERNER PROCESS SYSTEMS US 7909 Parkwood Circle Drive
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6th Floor Houston, TX 77036 Ph.: 713- 271-7086 (HR) Ph.: 713- 369-5344 (JJ) Fax: 713- 271-7091 (HR) Fax: 713- 685-5838 (JJ) e-mail: [email protected] e-mail: [email protected] e-mail: [email protected] Chip Letton, Ph.D. Principal LETTON HALL GROUP 5822 Tanglewood Park Houston, TX 77057 Ph.: 713- 974-7328 e-mail: [email protected] Charles A. Petty Professor MICHIGAN STATE UNIVERSITY Chemical Engineering Department East Lansing, MI 48824-1326 Ph.: 517-353-5486 Fax: 517- 432-1105 e-mail: [email protected] Bob Curcio Executive Vice President of Technology NATCO Brookhollow Central III 2950 North Loop West Houston, TX 77092 Ph.: 713- 685-8014 Fax: 713- 683-6768 e-mail: [email protected] Kevin Juniel NATCO-Group Brookhollow III, Suite 700 2950 N. Loop West Houston, TX 77092 Ph.: 713- 685-8041 Fax: 713- 683-6768 e-mail: [email protected] Andrew Hall National Engineering Laboratory (NEL) East Kilbride Glasgow G75 0QU United Kingdom
Ph.: 44 - 1355 272541 Fax: 44 - 1355 272290 e-mail: [email protected] Bill Bowers President PEAK PROCESS INC. 25351 Borough Park Drive The Woodlands, TX 77380 Ph.: 281- 364-8804 Fax: 281- 364-7590 e-mail: [email protected] Ken Fewel Vice President - Research and Technology Services PEERLESS MANUFACTURING COMPANY Research and Technology Services Post Office Box 540667 Dallas, Texas 75354 Street address: 2819 Walnut Hill Lane Dallas, TX 75229 Ph.: 214- 353-5545 Fax: 214- 351-0914 e-mail: [email protected] James Chen Technology Director PETRECO INTERNATIONAL INC. 14990 Yorktown Plaza Drive Houston, TX 77040 Ph.: 713- 934-4266 Fax: 713- 934-4102 e-mail: [email protected] Alexandre M. Freitas PETROBRAS Cenpes/Diplot/Seprot Cidade Universitaria, Q-7 Rio de Janeiro, RJ 21949-900 BRAZIL Ph.: 55-21-865-6555 Fax: 55-21-865-6796 e-mail: [email protected] Parviz Mehdizadeh, Ph.D. Consultant PRODUCTION TECHNOLOGY INC. 14225 N. 99th Street Scottsdale, AZ 85260
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Ph.: 480- 661-4076 Fax: 480- 661-7512 e-mail: [email protected] Ali H. Dorgu General Supervisor SAUDI ARAMCO Tech. Development Division E& P Facilities & Technology Dept. P.O.Box 1320 Dhahran, 31311 Saudi Arabia Ph.: (966) 3-874-7420 Fax: (966) 3-873-4652 e-mail: [email protected] Rajkumar Mathiravedu Product Engineer-REDA SCHLUMBERGER 509 W. Hensley P.O. Box 1181 Bartlesville, OK 74005 Ph.: 918- 661-2917 Fax: 918- 661-2885 e-mail: [email protected] Bertrand Theuveny Business Development Manager SCHLUMBERGER c/o 3Phase Measurement AS, POB 174 Sandsli N-5862 Bergen, Norway Ph.: 47- 55 52 64 20 Cell: 47- 907 79 432 e-mail: [email protected] Gérard Ségéral Scientific Advisor SCHLUMBERGER 1, rue Becquerel 92140 Clamart, France Ph.: (33) 1 45 37 21 79 Fax: (33) 1 45 37 23 27 e-mail: [email protected] Tom Chen, Ph.D. Systems Development Shell Int'l Exploration & Production Inc. 200 N. Dairy Ashford Houston, TX 77079, USA Tel: 281 544 4089 Fax: 281 544 2740
e-mail: [email protected] Keith Oxley SHELL WESTERN E&P INC. 701 Poydras St New Orleans, LA 70139-6001 Ph.: 504-728-6161 main number Ph.: 504-728-4429 Fax: 504-728-0239 e-mail: [email protected] James F. Langer, P.E. Staff Chemical Engineer SHELL GLOBAL SOLUTIONS Process Engineering Team Westhollow Technology Center 3333 Highway 6 South Room:WTC E-2210 Houston, Texas 77082 Ph.: 281-544-7726 Fax: 253-736-9373 Cell: 713-539-5191 [email protected] Yehuda Taitel Dept. of Fluid Mechanics and Heat Transfer Faculty of Engineering TEL AVIV UNIVERSITY Ramat Aviv, Tel Aviv 69978 ISRAEL Ph.: 972-3-640-8220 972-3-640-8930 Fax: 972-3-642-9540 e-mail: [email protected] George G. Chase Professor THE UNIVERSITY OF AKRON Department of Chemical Engineering Microscale Physiochemical Eng. Center Akron, OH 44325-3906 Ph.: 330-972-7943 Fax: 330-972-5856 e-mail: [email protected]
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Randy Crawford TRU-TEC SERVICES 11005 West Fairmont Parkway La Porte, TX 77572-1005 Ph.: 281-471 8715
800-288 8970 e-mail: [email protected] William Mixon TRU-TEC SERVICES 8181 GSRI Road Baton Rouge, LA 70820 Ph.: 225-761 0621 e-mail: [email protected] Frank Kenyery Director, Graduate School of Mech. Eng. Universidad Simon Bolivar USB P.O. Box: 89000 Laboratorio de Conversión de Engergia Mecánica, Caracas 1080, Venezuela Ph.: 58-2 906 41 34/906 41 35 Fax: 58-2 906 41 32 e-mail: [email protected] Dr. Manuel Avila Professor of Mechanical Engineering Universidad de Los Andes ULA Facultad de Ingeniería Avenida Don Tulio Mérida, Estado Mérida 5101. VENEZUELA Ph.: 58 074 402948 Fax: 58 074 402806 e-mail: [email protected] Joe Clemens Dave Hopgood UNOCAL CORPORATION Technology & Operations Support 14141 Southwest Freeway Sugar Land, TX 77478-3435 Ph.: (JK) 281- 287-5229 Ph.: (DH) 281-287-5226 Fax: (JK) 281-287-7335 Fax: (DH) 281-287-5389 e-mail: [email protected] e-mail: [email protected]
Grant Young VORTEX FLUID SYSTEMS, INC. 6324 S. 69th E. Place Tulsa, OK 74133 Ph.: 918- 492-1688 Fax: 918- 492-1688(same as above) Cell: 918- 810-7798 e-mail: [email protected] Jim Roncace WESTINGHOUSE ELECTRO- MECHANICAL DIVISION 1000 Cheswick Avenue Cheswick, PA 15024-1300 Ph.: 724-275-5727 Fax: 724-275-5100 e-mail: [email protected]
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TUSTP
REFERENCE LIST
TUSTP Dissertations, Theses and Reports – May 13, 2003
1. Prado, Mauricio G.: “A Block Implicit Numerical Solution Technique for Two-Phase
Multidimensional Steady-state Flow,” Ph.D. Dissertation, The University of Tulsa, 1995.
2. Arpandi, Inta A.: “A Mechanistic Model for Two-Phase Flow in Gas-Liquid Cylindrical
Cyclone Separators,” M.S. Thesis, The University of Tulsa, 1995.
3. Joshi, Ashutosh R.: “Two-Phase Flow in Gas-Liquid Cylindrical Cyclone Separators-
Experiments and Modeling,” M.S. Thesis, The University of Tulsa, 1995.
4. Arpandi, Inta A. and Joshi, Ashutosh R.: “1st Year Report on Experimental Program and
Mechanistic Modeling of GLCC Separators,” TUSTP Report, November 1995.
5. Erdal, Ferhat M.: “CFD Simulation of Single-Phase and Two-Phase Flow in Gas-Liquid
Cylindrical Cyclone Separator,” M.S. Thesis, The University of Tulsa, 1996.
6. Motta-Filho, Brenno R.: “Rotational Two-Phase Flow in Gas-Liquid Cylindrical
Cyclone Separators,” Ph.D. Dissertation, The University of Tulsa, 1997.
7. Movafaghian, Shaya: “The Effects of Geometry, Fluid Properties and Pressure on the
Flow Hydrodynamics in Gas-Liquid Cylindrical Cyclone Separators,” M.S. Thesis, The
University of Tulsa, 1997.
8. Wang, Shoubo: “Control System Analysis of Gas-Liquid Cylindrical Cyclone
Separators,” M.S. Thesis, The University of Tulsa, 1997.
9. Gomez, Luis E.: “A State-of-the-Art Simulator and Field Application Design of Gas-
Liquid Cylindrical Cyclone Separators,” M.S. Thesis, The University of Tulsa, 1998.
10. Mantilla, Ivan: “Bubble Trajectory Analysis in Gas-Liquid Cylindrical Cyclone
Separators,” M.S. Thesis, The University of Tulsa, 1998.
11. Chirinos, Williams: “Liquid Carry-over in Gas-Liquid Cylindrical Cyclone Compact
Separators,” M.S. Thesis, The University of Tulsa, 1998.
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12. Afanador, Edelmira: “Oil-Water Separation in Liquid-Liquid Cylindrical Cyclone
Separators,” M.S. Thesis, The University of Tulsa, 1999 (CD-ROM).
13. Wang, Shoubo: “Dynamic Simulation, Experimental Investigation and Control System
Design of Gas-Liquid Cylindrical Cyclone Separators,” Ph.D. Dissertation, The
University of Tulsa, 2000 (CD-ROM).
14. Ramirez, Reyes: “Slug Dissipation in Helical Pipes,” M.S. Thesis, The University of
Tulsa, 2000 (CD-ROM).
15. Caldentey, Juan: “A Mechanistic Model for Liquid Hydrocyclones (LHC),” M.S. Thesis,
The University of Tulsa, 2000 (CD-ROM).
16. Gomez, Luis E.: “Dispersed Two-Phase Swirling Flow Characterization for Predicting
Gas Carry-Under in Gas-Liquid Cylindrical Cyclone Compact Separators,” Ph.D.
Dissertation, The University of Tulsa, 2001, (CD-ROM).
17. Gomez, Carlos: “Oil-Water Separation in Liquid-Liquid Hydrocyclones (LLHC) –
Experiment and Modeling,” M.S. Thesis, The University of Tulsa, 2001, (CD-ROM).
18. Erdal, Ferhat: “Local Measurements and Computational Fluid Dynamics Simulations in a
Gas-Liquid Cylindrical Cyclone Separator,” Ph.D. Dissertation, The University of Tulsa,
2001 (CD-ROM).
19. Oropeza, Carlos-Vazquez: “Multiphase Flow Separation in Liquid-Liquid Cylindrical
Cyclone and Gas-Liquid-Liquid Cylindrical Cyclone Compact Separators,” Ph.D.
Dissertation, The University of Tulsa, 2001 (CD-ROM).
20. Earni, Bhavani Shankar: “Predictive Control of Gas-Liquid Cylindrical Cyclone Compact
Separators Using Slug Detection,” M.S. Thesis, The University of Tulsa, 2001 (CD-
ROM).
21. Mathiravedu, Rajkumar S.: “Control System Development and Performance Evaluation
of LLCC Separators,” M.S. Thesis, The University of Tulsa, 2001 (CD-ROM).
22. Reinoso, Antonio: “Design and Performance of Slug Damper,” M.S. Thesis, The
University of Tulsa, 2002 (CD-ROM).
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23. Contreras, William: “The Effect of Inlet Gas Void Fraction on the Performance of
Liquid-Liquid Cylindrical Cyclone (LLCC©) Separator,” M.S. Thesis, The University of
Tulsa, 2002. (CD-ROM)
24. Barboza, Marcos: “Oil-Water Dispersion Flow in Piping Components,” M.S. Thesis, The
University of Tulsa, 2002. (CD-ROM)
25. Molina, Robiro: “Wet Gas Separation in Gas-Liquid Cylindrical Cyclone (GLCC)
Separator,” M.S. Thesis, The University of Tulsa, 2003. (CD-ROM)
26. Avila, Carlos: “Modeling and Control Systems Development for Integrated Three-Phase
Compact Separators,” M.S. Thesis, The University of Tulsa, 2003. (CD-ROM)
27. Sampath, Vasudevan: “Design and Development of Adaptive Control for Gas Liquid
Cylindrical Cyclone Separators,” M.S. Thesis, The University of Tulsa, 2003. (CD-
ROM)
28. TUSTP Publications CD-ROM, Vol. 1 (June 1995 – October 1999), released November
19, 1999.
29. TUSTP ABM Brochures
a) 2nd ABM, May12, 1995. b) 3rd ABM, November 17, 1995. c) 4th ABM, May 17, 1996. d) 5th ABM November 22, 1996. e) 6th ABM May 16, 1997. f) 7th ABM November 21, 1997. g) 8th ABM May 15, 1998. h) 9th ABM November 20, 1998. i) 10th ABM May 14, 1999. j) 11th ABM November 19, 1999. k) 12th ABM May 23, 2000 (CD-ROM). l) 13th ABM November 17, 2000 (CD-ROM). m) 14th ABM May 22, 2001 (CD-ROM). n) 15th ABM November 13, 2001 (CD-ROM). o) 16th ABM May 21, 2002 (CD-ROM). p) 17th ABM November 19, 2002 (CD-ROM).
30. TUSTP Chevron Drawings (ASME Coded GLCC AutoCAD Drawings – May 1, 1999
(CD-ROM).
31. TUSTP, GLCC Separator Simulator, GLCC vx6.0 – November 19, 1999 (CD-ROM).
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32. TUSTP, GLCC Separator Simulator, GLCC vx6.3 – May 23, 2000 (CD-ROM).
33. TUSTP, GLCC Separator Simulator, GLCC vx7.0, Excel 7.0, MS-Office ’97, November
17, 2000 (CD-ROM).
34. TUSTP Simulators, GLCC vx7.2, LLHC vx1.0, Excel 7.0, MS-Office ’97, May 22, 2001
(CD-ROM).
35. TUSTP Simulators, GLCC vx7.3, LLHC vx1.0, Excel 7.0, MS-Office ’97, Nov 13, 2001
(CD-ROM).
36. TUSTP Simulators, GLCC vx7.4, LLHC vx1.0, LLCC vx1.0�, Excel 7.0, MS-Office ’97,
May 21, 2002 (CD-ROM).
37. TUSTP Simulators, GLCC vx7.5, LLHC vx1.1, LLCC vx 1.0, SlugDamper vx 1.0-Beta
Excel 7.0, MS-Office ’00, November 19, 2002 (CD-ROM).
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TUSTP Publications Listing – April 3, 2003
1. Amey, M.J., Benard, A., Chase, G.G., Evans, E.A., Jayaraman, K., Mohan, R.S., Parks,
S.M., Petty, C.A., Shoham, O., Shirazi, S.A., Wisecarver, K.D., and Zhuang, M.: “NSF
Combined Research and Curriculum Development on Multiphase Transport
Phenomena,” Session 1712, proceedings of the 2002 American Society for Engineering
Education (ASEE) Annual Conference & Exposition, Montreal, Canada, June 16-19,
2002.
2. Arpandi, I.A., Joshi, A.R., Shoham, O., Shirazi, S.A. and Kouba, G.E.: “Hydrodynamics
of Two-Phase Flow in Gas-Liquid Cylindrical Cyclone Separators,” SPE 30683,
presented at SPE 70th Annual Meeting, Dallas, TX, Oct. 22-26, 1995, SPE Journal, vol.
1 (Dec. 1996), 427-436.
3. Caldentey, J., Gomez, C., Wang, S., Gomez, L., Mohan, R. and Shoham, O.: “Oil-Water
Separation in Liquid-Liquid Hydrocyclones (LLHC) – Part 2: Mechanistic Modeling,”
SPE 71538, presented at the SPE ATCE, New Orleans, LA, September 30 – October 3,
2001, SPE Journal, vol. 7, December 2002, pp.362-372.
4. Chirinos W.A., Gomez L.E., Wang, S., Mohan R.S., Shoham, O. and Kouba, G.E.:
“Liquid Carry-over in Gas-Liquid Cylindrical Cyclone (GLCC) Compact Separators,”
SPE 56582, proceedings of the 1999 SPE Annual Technical Conference and Exhibition,
Houston, TX, Oct. 3-6, 1999, SPE Journal, 5 (3), (Sep. 2000), 259-267.
5. Earni, S., Wang, S., Mohan, R.S., Shoham, O., and Marrelli, J.D.: “Slug Detection as a
tool for Predictive Control of GLCC Compact Separators,” ETCE2001-17136,
proceedings of ASME Engineering Technology Conference on Energy, Houston, TX,
Feb. 5-7, 2001, to be published in ASME Transactions, Journal of Energy Resources
Technology, vol. 125 (1), June 2003.
6. Erdal, F.M. & Shirazi, S.A.: “Effect of Inlet Configuration on Flow Behavior in a
Cylindrical Cyclone Separator,” ETCE2002/MANU-29110, proceedings of ASME
Engineering Technology Conference on Energy, Houston, TX, Feb. 4-5, 2002.
7. Erdal, F.M. & Shirazi, S.A.: ‘‘Local Velocity Measurements and Computational Fluid
Dynamics (CFD) Simulations of Swirling Flow in a Cylindrical Cyclone Separator,”
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ETCE2001-17101, proceedings of ASME Engineering Technology Conference on
Energy, Houston, TX, Feb. 5-7, 2001.
8. Erdal, F.M., Mantilla, I., Shirazi, S.A. and Shoham, O.: “CFD Study of Bubble Carry-
Under in Gas-Liquid Cylindrical Cyclone Separators,” SPE 49309, presented at the SPE
73rd Annual Meeting, New Orleans, LA, September 27-30, 1998, SPE Production
Engineering and Facilities, v. 15 (4), 217-222, Nov. 2000.
9. Erdal, F.M., Mantilla, I., Shirazi, S.A. and Shoham, O.: “Simulation of Free Interface
Shape and Complex Two-Phase Flow Behavior in a Gas-Liquid Cylindrical Cyclone
Separator,” ASME FEDSM98-5206, proceedings of the 1998 ASME Fluids Engineering
Division Summer Meeting, Washington D.C., June 21-25, 1998.
10. Erdal, F.M., Shirazi, S.A., Shoham, O. and Kouba, G.E.: “CFD Simulation of Single-
Phase and Two-Phase Flow in Gas-Liquid Cylindrical Cyclone Separators,” SPE 36645,
presented at the SPE 71st Annual Meeting, Denver, CO, Oct. 6-9, 1996, SPE Journal,
vol. 2, 436-446, Dec. 1997.
11. Gomez, C., Caldentey, J., Wang, S., Gomez, L., Mohan, R. and Shoham, O.: “Oil-Water
Separation in Liquid-Liquid Hydrocyclones (LLHC) – Part 1: Experimental
Investigation,” SPE 71538, presented at the SPE ATCE, New Orleans, LA, September 30
– October 3, 2001, SPE Journal, vol. 7, December 2002, pp. 353-361.
12. Gomez, L.E, Mohan, R.S., Shoham, O. and Kouba, G.E.: “Enhanced Mechanistic Model
and Field Application Design of Gas-Liquid Cylindrical Cyclone Separator,” SPE 49174,
proceedings of the SPE 73rd SPE Annual Meeting, New Orleans, LA, Sep. 27-30, 1998,
SPE Journal, vol. 5 (2), 190-198, June 2000.
13. Gomez, L.E., Mohan, R.S., Shoham, O. Marrelli, J. and Kouba, G.E.: “A State-of-the-art
Simulator for Field Applications of Gas-Liquid Cylindrical Cyclone Separators,” SPE
56581, proceedings of the 1999 SPE Annual Technical Conference and Exhibition,
Houston, TX, Oct. 3-6, 1999.
14. Gomez, L.E., Shoham, O. and Taitel, Y.: “Prediction of slug liquid holdup: horizontal to
upward vertical flow,” International Journal of Multiphase Flow 26 (2000), vol. 26, No.
3, March 2000, pp. 517-521.
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15. Gomez, L., Shoham, O., Schmidt, Z., Chokshi, R., and Northug, T.: “A Unified
Mechanistic Model for Steady-State Two-Phase Flow – Horizontal to Vertical Upward
Flow”, presented at the SPE 74th Annual Meeting, Houston, October 3-6, 1999, SPE
Journal, vol.5 (3), 339-350, September 2000.
16. Gomez, L.E., Wang, S., Mohan, R.S., Shoham, O., Kouba, G.E., and Marrelli, J.:
“Design and Performance of Dual Inlet for Gas-Liquid Cylindrical Cyclone Compact
Separators,” presented at the ASME ETCE-2001-17138, Houston, TX, Feb. 5-7, 2001.
17. Gomez, L.E., Mohan, R.S., Shoham, O., Marrelli, J. and Kouba, G.E.: “Aspect Ratio
Modeling and Design Procedure for GLCC Compact Separators,” presented at the ASME
Energy Resources Technology Conference and Exhibition, ETCE, Houston, TX, Feb. 1-
2, 1999, ASME Transactions, Journal of Energy Resources Technology, vol. 121 (1),
March 1999, 15-23.
18. Gomez, L.E., Wang, S., Mohan, R.S., and Shoham, O.: “Performance of a Large Tank
Separator: Fluid Flow Phenomena and Droplet Size Distribution along the Spreader
System,” Presented at the 15th Annual Technical Conference and Exhibition, American
Filtration and Separation Society, Galveston, TX, April 9-12, 2002.
19. Kouba, G.E. and Shoham, O.: “A Review of Gas-Liquid Cylindrical Cyclone (GLCC)
Technology,” presented at the “Production Separation Systems” International
Conference, Aberdeen, England, April 23-24, 1996.
20. Kouba, G.E., Shoham, O. and Shirazi, S.A.: “Design and Performance of Gas-Liquid
Cylindrical Cyclone Separators,” proceedings of the BHR Group 7th International
Meeting on Multiphase Flow, Cannes, France, June 7-9, 1995, 307-327.
21. Kouba, G.E.: “A Slug Damper for Compact Separators,” ETCE2002/PROD-29116,
Proceedings of ASME Engineering Technology Conference on Energy, Houston, TX,
Feb. 4-5, 2002.
22. Lansangan, R. M. and Huffman, M.: “Gas-Liquid Separation Using a GLCC in Sodium
Bicarbonate Solution Mining Operation,” ETCE2001-17161, proceedings of the ASME
ETCE-2001, Houston, TX, Feb. 5-7, 2001.
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23. Mantilla, I., Shirazi, S.A. and Shoham, O.: “Flow Field Prediction and Bubble Trajectory
Model in Gas-Liquid Cylindrical Cyclone (GLCC) Separators,” presented at the ASME
Energy Resources Technology Conference and Exhibition, ETCE, Houston, TX, Feb. 1-
2, 1999, ASME Transactions, Journal of Energy Resources Technology, vol. 121, March
1999, 9-14.
24. Marrelli, J.D., Mohan, R.S. & Wang, S.: “Use of Multiphase Meters in Process Control
for Oil Field Well Testing: Novel Level Controls and Resulting Performance
Enhancement", Proceedings of 20th International NorthSea Flow Measurement
Workshop, NSCE, Oslo, Norway, October 25-28, 2002.
25. Marrelli, J. D., Mohan, R.S., Wang, S., Shoham, O., Gomez, L.E.: “Use of Multiphase
Meters in Process Control for Oil Field Well Testing: Performance Enhancement
through GVF Control,” Proceedings of 57th Annual Instrumentation Symposium for the
Process Industries, College Station, Texas, January 22-24, 2002.
26. Marrelli, J.D., Mohan, R.S., Wang, S., Gomez, L.E., and Shoham, O.: “Use of
Multiphase Meters in Process Control for Oil Field Well Testing: Novel Level Controls
and Resulting Performance Enhancement,” ETCE2002/MANU-29102, proceedings of
ASME Engineering Technology Conference on Energy, Houston, TX, Feb. 4-6, 2002.
27. Marrelli, J.D., Tallet, M., Yocum, B., Dunbar, D., Mohan, R.S. & Shoham, O.:
“Enhanced Performance Multiphase Metering: Optimal matching of Separation and
Metering facilities for Performance, Cost, and Size. Practical examples from Indonesia
Duri Area 10 Expansion Project", Proceedings of 17th International NorthSea Flow
Measurement Workshop, NSCE, Oslo, Norway, October 25-28, 1999.
28. Marrelli, J.D., Tallet, M., Yocum, B., Dunbar, D., Mohan, R.S., Shoham, O. and Rubel,
M.T.: “Methods for Optimal Matching of Separation and Metering Facilities for
Performance, Cost, and Size: Practical Examples from Duri Area 10 Expansion,”
ETCE00-ER-10165, Proceedings of ASME ETCE 2000 ASME Energy Sources
Technology Conference and Exhibition, Houston, TX, Feb. 14-17, 2000.
29. Marti, S., Erdal, F.M., Shoham, O., Shirazi, S.A. and Kouba, G.E.: “Analysis of Gas
Carry-Under in Gas-Liquid Cylindrical Cyclones,” presented at the “Hydrocyclones
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1996” International Meeting, St. John College, Cambridge, England, April 2-4, 1996,
399-421.
30. Mathiravedu, R., Wang, S., Mohan, R.S., Shoham, O. & Marrelli, J.D.: “Performance and
Control of Liquid-Liquid Cylindrical Cyclone Separators,” ETCE2002/MANU-29103,
proceedings of ASME Engineering Technology Conference on Energy, Houston, TX,
Feb. 4-6, 2002. Awarded “The Jacobson Best Paper Award” (Selected best among 170
National and International papers presented)
31. Mohan, R.S. and Shoham, O.: “Technologies Under Development: Design and
Development of Gas-Liquid Cylindrical Cyclone Compact Separators for Three-Phase
Flow,” paper presented at the 1999 Oil and Gas Conference-Technology Options for
Producers’ Survival, Co-Sponsored by DOE and PTTC, Dallas, TX, June 28-30, 1999.
32. Mohan, R.S., Wang, S., Shoham, O. and Kouba, G.E.: “Design and Performance of
Passive Control System for Gas-Liquid Cylindrical Cyclone Separators,” proceedings of
the ASME Energy Sources Technology Conference and Exhibition, ETCE’ 98, Houston,
TX, Feb. 2-4, 1998, ASME Transactions Journal of Energy Resources Technology, vol.
120 (1) March 1998, 49-55.
33. Motta, B.R.F., Erdal, F.M., Shirazi, S.A., Shoham, O. and Rhyne, L.D.: “Simulation of
Single-Phase and Two-Phase Flow in Gas-Liquid Cylindrical Cyclone Separators,”
FEDSM97-3554, proceedings of the ASME Summer Meeting, Fluid Eng. Division,
Vancouver, Canada, 1-8, June 22-26, 1997.
34. Movafaghian, S., Jaua-Marturet, J., Mohan, R.S, Shoham, O. and Kouba, G.E.: “The
Effect of Geometry, Fluid Properties and Pressure on the Hydrodynamics of Gas-Liquid
Cylindrical Cyclone Separators,” International Journal of Multiphase Flow, vol. 26, no.
6, June 2000, 999-1018.
35. Severino, J.G., Gomez, L.E., Mohan, R.S. and Leibrandt, S.: “Performance of a Large
Tank Separator: Fluid Flow Phenomena and Droplet Size Distribution along the Spreader
System,” ETCE2002/MANU-29107, Presented at the ASME Engineering Technology
Conference on Energy, Houston, TX, Feb. 4-5, 2002.
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36. Severino, J.G.: “Two-Phase Flow Performance of Coriolis Mass Flowmeters,” SPE
Undergraduate Student Paper Contest, presented at the 2000 SPE Annual Meeting,
Dallas, TX, Oct. 1-4, 2000.
37. Shoham, O. and Kouba, G.E.: “The State-of-the-Art of Gas-Liquid Cylindrical Cyclone
Compact Separation Technology,” Journal of Petroleum Technology, July 1998, 54-61.
38. Torres, C.F. and Gomez, L.E.: “CFD Simulation of Gas-Liquid Mist and Oil-Water Flow
Through Coalescing Elbow Configurations,” ETCE2002/MANU-29111, Presented at the
ASME Engineering Technology Conference on Energy, Houston, TX, Feb. 4-5, 2002.
39. Wang, S., Mohan, R. & Shoham, O.: “Performance Improvement of Gas Liquid
Cylindrical Cyclone Separators Using Passive Control System,” presented at 1998 ASME
Energy Sources Technology Conference ETCE ’98, Houston, TX, Feb. 2-4, 1998.
Awarded “The Jacobson Best Paper Award” (Selected best among 220 National and
International papers presented).
40. Shoubo, W., Gomez, L., Mohan, R., Shoham, O., Kouba, G. and Marrelli, J.: “The State-
on-the-Art of Gas-Liquid Compact Separator Control Technology-From Lab to Field,”
proceedings of 8th International Symposium on Gas-Liquid Flows: ASME/JSME Join
Fluids Engineering Division Summer Meeting, July 6-10, 2003, Honolulu, Hawaii.
41. Wang, S., Gomez, L.E., Mohan, R.S., Shoham, O., and Kouba G.E.: “Gas-Liquid
Cylindrical Cyclone Compact Separators for Wet-Gas Applications,” ETCE2001-17137,
Proceedings of ASME Engineering Technology Conference on Energy, Houston, TX,
Feb. 5-7, 2001, ASME Transactions, Journal of Energy Resources Technology, vol. 125,
March 2003, pp.43-50.
42. Wang, S., Gomez, L.E., Mohan, R.S., Shoham, O. and Kouba, G.E.: “High Pressure
Testing of Wet Gas GLCC Separators,” ETCE2002/MANU-29107, presented at the
ASME Engineering Technology Conference on Energy, Houston, TX, Feb. 4-5, 2002.
43. Wang, S., Gomez, L.E., Mohan, R.S., and Shoham, O.: “The State-of-the-Art of GLCC©
Compact Separator Control Technology – from Lab to Field,” Presented at the 15th
Annual Technical Conference and Exhibition, American Filtration and Separation
Society, Galveston, TX, April 9-12, 2002.
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44. Wang, S., Mohan, R.S., Shoham, O. and Kouba, G.E.: “ Dynamic Simulation and
Control System Design for Gas-Liquid Cylindrical Cyclone Separators,” SPE 49175,
presented at the SPE 73rd SPE Annual Meeting, New Orleans, LA, Sep. 27-30, 1998, SPE
Journal, 6 (2), 236-247, June 2001.
45. Wang, S., Mohan, R.S., Shoham, O. Marrelli, J.D. and Kouba, G.E.: “Control System
Simulators for Gas-Liquid Cylindrical Cyclone Separators,” proceedings of the ASME
Energy Resources Technology Conference and Exhibition, ETCE, New Orleans, LA,
Feb. 14-17, 2000, ASME Transactions, Journal of Energy Resources Technology, v. 122,
177-184, Dec. 2000.
46. Wang, S., Mohan, R.S., Shoham, O., Marrelli, J.D. and Kouba, G.E.: “Performance
Improvement of Gas-Liquid Cylindrical Cyclone Separators Using Integrated Level and
Pressure Control Systems,” proceedings of the ASME Energy Resources Technology
Conference and Exhibition, ETCE-2000, New Orleans, LA, Feb. 14-17, 2000, ASME
Transactions, Journal of Energy Resources Technology, v. 122, 185-192, Dec. 2000.
47. Wang, S., Mohan, R.S., Shoham, O., Marrelli, J.D., and Kouba, G.E.: “Optimal Control
Strategy and Experimental Investigation of Gas-Liquid Cylindrical Cyclone Compact
Separators,” SPE 63120, presented at the SPE 74th Annual Meeting, Dallas, TX, Oct. 1-4,
2000, SPE Journal, vol. 7, No. 2, June 2002, pp. 170-182.
48. Wang, S., Gomez, L.E., Mohan, R.S., Shoham, O. and Kouba, G.E.: “Gas-Liquid
Cylindrical Cyclone (GLCC) Compact Separators For Wet Gas Applications,” Journal of
Energy Resources Technology, vol. 125, March 2003, pp. 43-50.
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General Library – April 3, 2003
1. Agar, G., Clewis, P. and Spencer, C.: “Energy Absorption Probes Control Oily-Water
Discharges,” Hydrocarbon Processing, August 1993, pp. 55-59.
2. Ali, S.K. and Petty C.A.: “MSU Sampling Flow Loop,” Hydrocyclone Development
Consortium, Michigan State University, Supplemental Report No. HDC-S4, Fall 1995.
3. American Filtration & Separations Society (AFS) 15th Annual Technical Conference and
Exposition, Abstract Book, Galveston, TX, April 9-12, 2002.
4. Angeli, P. and Hewitt, G.F.: “Drop Size Distributions in Horizontal Oil-Water Dispersed
Flows,” Chem. Eng. Science, vol. 55 pp. 3133-3143.
5. Arato, E.G. and Barnes, N.D.: “In-Line Free Vortex Separator Used for Gas/Liquid
Separation within a Novel Two-Phase Pumping System,” Hydrocyclones-Analysis and
Application. Editors: L. Svarovsky, Thew, M.T. and Brookfield, V.T, Kluwer-Academic,
1992, pp. 377-396.
6. Aretz, H.J., Burgess-Manning GmbH, and Stell, J.D., Burgess-Manning Inc.: “Evaluation
of the Performance of a New Upflow Design,” SPE 26590, presented at the SPE 68th
Annual Meeting, Houston, TX, October 3-6, 1993.
7. ASME/JSME Joint Fluids Engineering Conference & FED Summer Meeting/Exhibition,
Proceedings, San Francisco, California, July 18-22, 1999.
8. Atkinson, D.I., Berard, M. and Segeral, G.: “Qualification of a Nonintrusive Multiphase
Flow Meter in Viscous Flows,” SPE 63118, presented at the 2000 SPE Annual
Conference and Exhibition, Dallas, TX, 1-4 October 2000.
9. Atkinson, D.I., Berard, M., Hanssen, B-V and Segeral, G.: “New Generation multiphase
Flowmeters from Schlumberger and Framo Engineering AS,” 17th International North
Sea Flow Measurement Workshop, Oslo, Norway, 25-28 October 1999.
10. Baker, A.C. and Entress, J.H.: “VASPS (Vertical Annular Separation Pumping System)
Subsea Separation and Pumping System,” Trans. IChemE., vol.70, Part A, January 1992,
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pp.9-16, Paper presented at the Institution of Chemical Engineers Conference, “Subsea
Separation and Transport III,” London, May 23-24, 1991.
11. Bandopadhyay, P.R. and Gad-el-Hak, M.: “Rotating Gas-Liquid Flows in Finite
Cylinders: Sensitivity of Standing Vortices to End Effects,” Experiments in Fluids, 21
(1996), pp. 124-138, Springer-Verlag, 1996.
12. Bandopadhyay, P.R., Pacifico, G.C. and Gad-el-Hak, M.: “Sensitivity of a Gas-Core
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Prototyping Division, Naval Undersea Warfare Center Division, Newport, Rhode Island,
1994.
13. Bandopadhyay, P.R., Pacifico, G.C., and Gad-el-Hak, M.: “Gas-Core Configurations in a
Cyclone-Type Gas-Liquid Separator,” NUWC-NPT Technical Report 10, 308, January 3,
1994.
14. Baran, O. and Thew, M.T.: “Voidage Distribution in a Down-Flow Boiler Drum
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15. Barrientos, A., Sampaio, R. and Concha, F.: “Effect of the Air Core on the Performance
of a Hydrocyclone,” XVIII International Mineral Processing Congress, Sydney, May 23-
28, 1993, pp. 267-270.
16. Beuscher, U.: “Investigations on the Maximum Stable Drop Size in Turbulent Pipe
Flows,” Hydrocyclone Development Consortium, Michigan State University, Technical
Report No. HDC-R7, December 1991.
17. Boyson, F., Ayers, W.H. and Swithenbank, J.: “A Fundamental Mathematical Modeling
Approach to Cyclone Design,” Trans. IChemE., July 1982, vol. 60, No.4, pp. 222- 230.
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United Kingdom Atomic Energy Authority, Research Group Report, Harwell, Berkshir,
April 1962.
19. Bradley, D. and Pulling, D.J.: “Flow Patterns in the Hydraulic Cyclone and Their
Interpretation in Terms of Performance,” presented at the Midlands Branch of the
Institution in Derby, October, 1958, Trans. Instn Chem. Engrs, vol. 37, 1959, pp. 34-45.
B-14
20. Brauner, N. and Ullmann, A.: “Modeling of phase inversion phenomenon in two-phase
pipe flows,” International Journal of Multiphase Flow, 28 (2002), pp. 1177-1204.
21. Bringedal, S., Ingebretsen, T. & Haugen, K.: “Subsea Separation and Reinjection of
Produced Water,” OTC 10967, presented at the 1999 Offshore Technology Conference,
Houston, TX, May 3-6, 1999.
22. Campbell, B., Harrison, B. and Rodwell, G.: “Surface Hydrocyclone System Cuts
Produced Water Volume,” Hart’s Petroleum Engineer International, pp. 35-43, May
1998.
23. Carter, H.R. and Prueter, W.P.: “Evaluation and Correlation of the Effects of Operating
Conditions on the Moisture Carryover Performance of Centrifugal Steam and Water
Separators,” Babcock & Wilcox Company, R&D Division.
24. Chang, F. and Dhir, V.K.: “Mechanisms of Heat Transfer Enhancement and Slow Decay
of Swirl in Tubes Using Tangential Injection,” Int. J. Heat and Fluid Flow, vol. 16, No.
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25. Chien, K.H., Chen, T.T., Pei, B.S. and Lin, W.K.: “Void Fraction Measurement by
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26. Coker, A.K.: “Computer Program Enhances Guidelines for Gas-Liquid Separator
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27. Collins, R.L. and Lovelace, R.B.: “Experimental Study of Two-Phase Propane Expanded
through the Ranque-Hilsch Tube,” Transactions of the ASME, vol. 101, May 1979, pp.
300-305.
28. Cowie, D.: “Vertical Caisson Slugcatcher Performance,” presented at the Institution of
Chemical Engineers Conference “Subsea Separation and Transport III,” London, May
23-24 May, 1991, Trans. IChemE., vol. 70, part A, January 1992, pp. 25-31.
29. Danyluk, T.L. and Chachuls, R.C.: “Field Trial of the First Desanding System for
Downhole Oil/Water Separation in a Heavy-Oil Application,” SPE 49053, proceedings of
the 1998 ATCE, New Orleans, Louisiana, September 27-30, 1998.
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30. Davies, E.E. and Watson, P.: “Miniaturized Separators for Offshore Platforms,”
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31. Davies, E.E.: “Compact Separators for Offshore Production,” proceedings of the 2nd
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32. Devulapalli, B. and Rajamani, R. K.: “A Comprehensive CFD Model for Partical-Size
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33. Dombrowski, N., Foumeny, E.A. and Riza, A.: “Know the CFD Codes,” University of
Leeds; Chemical Engineering Progress, September 1993, pp. 46-48.
34. Dyakowski, t. Hornung, G. and Williams, R.A.: “Simulation of Non-Newtonian Flow in
a Hydrocyclone,” publication March 16, 1994.
35. Dyakowski, T. and Williams, R.A.: “Prediction of Air-Core Size and Shape in a
Hydrocyclone,” International Journal of Mineral Processing, June 1994, pp. 1-25.
36. Economides, M. and Oligney, R.: The Color of Oil, Round Oak Publishing Company,
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37. ETCE-2000 Subsea Processing the New Field Development Enabler, ABB Offshore
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38. Fekete, L.A.: “Vortex Tube Separator May Solve Weight/Space Limitations,” World Oil,
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39. Ferriss, D.H. and Hall, C.: “Numerical Solution of a Steady, Viscous, Axisymmetric
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February 1979, NPL Report, DNACS, 12/79.
40. Fewel, K.J. and Kean, J.A.: “Vane Separators in Gas/Liquid Separation,” ASME
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41. Fin’ko, V.E.: “Cooling and Condensation of Gas in Vortex Flow,” American Institute of
Physics, 1984, pp. 1089-1093.
42. Flores, J.G., Clifford, P.J., Castro, V.M. and Loveland, R.K.: “Determining Intervals of
Lean Gas Breakthrough in a Gas Condensate Producer Using an Optical Holdup Meter,”
proceedings of ASME ETCE 2000/OMAE 2000 Joint Conference, New Orleans, LA,
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43. Forsyth, R.A.: “Cyclone Separation in Natural Gas Transmission Systems-the Design
and Performance of Cyclones to Take Debris out of Natural Gas,” Chemical Engineer,
London, June 1984, pp. 37-41.
44. Fraser, S.M. and Abdullah, M.Z.: “LDA Measurement on a Modified Cyclone,”
proceedings of ASME Fluid Eng. Division, Conference and Exhibition, Hilton Head
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45. “Galifa-Separator Simulator,” Research for Industrial Development, Christian Michelsen
Research, Norway.
46. Garg, A.K.: “Structure and Stability of Some Swirling Flows,” Ph.D Dissertation,
Cornell University, 1993.
47. Gauthier et al.: “Co-Current Cyclone Separator and its Applications,” United States
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48. Genceli, H., Kuenhold, K., Shoham, O. and Brill, J.P.: “Dynamic Simulation of Slug
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1988.
49. Green, A.J., Reade, A.T. and Ashton, K.: “Gas Production Improvements Using
Ejectors,” SPE 26684, presented at the Offshore European Conference held in Aberdeen,
September 7-10, 1993.
50. Griffiths, A.J., Yazadabadi, P.A. and Syred, N.: “Alternate Eddy Shedding Set Up by the
Nonaxisymmetric Recirculation Zone at the Exhaust of a Cyclone Dust Separator,”
Journal of Fluids Engineering, vol. 120, pp. 193-199, March 1998.
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51. Gomez, L.E., Severino, J., Leibrandt, S. and Hammond, F.: “Performance of a Large
Tank Separator: Fluid Flow and Droplet Size Distribution Along Spreader System,”
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52. Grossel, S., S.: “An Overview of Equipment for Containment and Disposal of
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Containment, London UK, September 12-14, 1989.
53. Guha, A.: “A Simple Analytical Theory for Interpreting Measured Total Pressure in
Multiphase Flows,” ASME Journal of Fluids Engineering, vol. 120, pp. 385-389, June
1998.
54. Gündogdu, M.Y. and Carpinlioglu, M.O.: “A Multi-tube Pressure Probe Calibration
Method for Measurements of Mean Flow Parameters in Swirling Flows,” Flow
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55. Guo, Z. and Dhir, V.K.: “An Analytical and Experimental Study of a Swirling Bubbly
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56. Guo, Z. and Dhir, V.K.: “Flow Reversal in Injection Induced Swirl Flow,” ASME, vol.
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58. Hallanger, A., Soenstaboe, F. and Knutsen, T.: “Simulation Model for Three-Phase
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October 6-9, 1996.
59. Hansen, R.L. & Rickey, W.P.: “Evolution of Subsea Production Systems: A Worldwide
Overview,” SPE 29084, Journal of Petroleum Technology, August 1995, pp. 675-680.
60. Hargreaves, H.H. and Silvester, R.S.: “Computatuional Fluid Dynamics Applied to the
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1990, pp.365-383.
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61. Hekimian, N.H., Jumonville, J.M. and Scott, S.L.: “Experimental Investigation of the
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62. Henkes, R., Haandrikman, G. and Vreenegoor, L.: “The Slug Suppression System; Field
Data and Dynamic Simulations,” BHR Group 2001 Multiphase Technology, pp. 347-360.
63. Hills, J.H., Azzopardi, B.J. and Barhey, A.S.: “Spatial Unsteadiness-A Way Towards
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64. Hoffmann, A.C., de Groot, M. and Hospers, A.: “The Effect of the Dust Collection
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65. Hoffmann, A.C., de Jonge, R., Arends, H. and Hanrats, C.: “Evidence of the ‘Natural
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66. Hsieh, K.T. and Rajamani, R.K.: “Mathematical Model of the Hydrocyclone Based on
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67. Hubred, G.L, Mason, A.B., Parks, S.M. and Petty, C.A.: “Dispersed Phase Separations:
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68. Proceedings of the IBC Conference, Production Separation Systems, November 17th -
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69. Additions to the IBC Conference.
70. International Vocabulary of Basic and General Terms in Metrology, Second Edition,
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71. Ito, S., Ogawa, K and Kuroda, C.: “Decay Process of Swirling Flow in a Circular Pipe,”
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72. Janssen, P.H. and Noik, C.: “Emulsion Formation in a Model Choke-valve,” SPE
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73. Jones, P.S.: “A Field Comparison of Static and Dynamic Hydrocyclones,” SPE
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74. Journal of Energy Resources Technology, Transactions of the ASME, published quarterly
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75. Junichi K. and Tsutomo, O.: “Gas-Liquid Flow Characteristics and Gas-Separation
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76. Kanyua, J.F. and Freeston, D.H.: “Vertical Flow Centrifugal Separator - Effects of
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77. Karamanev D.G. and Nikolov, L.N.: “Free Rising Spheres Do Not Obey Newton’s Law
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79. Karlsen, A. & Gustavsson, K.: “Muxcom – A New Subsea Control Concept for Very
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80. Keller, Jacob J.: “On Tornado-Like Vortex Flows,” Department of Aeronautics and
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81. Kimmitt, R.P., Rhinesmith, R.B. and Root, C.R.: “Proven Methods for Design and
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82. King, N.W. and Purfit, G.L.: “Experiments on Oil/Gas Separation in Helical Passages,”
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83. Kolpak, M.: “GLCC Level-Pressure Sensitivity, Level Control and Turbulent Diffusion,”
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84. Kouba, G.E.: “A New Look at Measurement Uncertainty of Multiphase Flow
Meters,” ETCE98-4661, Energy Sources Technology Conference & Exhibition,
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85. Krebs Petroleum Technologies Brochures
86. Kumar, R., Conover, T. and Pan, Y.: “Three-Dimensional Turbulent Swirling Flow in a
Cylinder: PTV Experiments and Computations,” ASME Fluid Measurement and
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87. Kutepov, A.M., Nepomnyashchil, I.G., Pashkov, V.P. and Konovalov, G.M.:
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88. Kurokawa, J. and Ohtaik, T.: “Gas-Liquid Flow Characteristics and Gas-Separation
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89. Kynch, G.J.: “A Theory of Sedimentation,” Transactions of the Faraday Society, vol. 48,
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90. Letton W., Svaeren, J.A. & Conort, G.: “Topside and Subsea Experience with the
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91. List of NPTO Publications, 2000.
92. Liu, K.T. and Kouba, G.E.: “Coriolis-Based Net Oil Computers Gain Acceptance at the
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93. Liu, K.T. and Revus, D.E.: “Net-oil computer improves water-cut determination,” Oil &
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94. Loken, K.-P., Vangen, G. and Nordstad, K.: “Field Test of Separator Internals for Oil
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95. Malhotra, A., Branion, R.M.R. and Hauptmann, E.G.: “Modeling the Flow in a
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96. Manual of Petroleum Measurement Standards, Chapter 5-Metering, Section 6-
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97. Manual of Petroleum Measurement Standards, Chapter 10-Sediment and Water, Section
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98. Martin, A.M., Vidal, A. and Kenyery, F.: “Efficiency Consideration in Multiphase
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99. Maruyama, T., Mizushina T., and Watanabe, F.: “Turbulent Mixing of Two Fluid
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100. Matonis, D., Gidaspow, D. and Bahary, M.: “CFD Simulation of Flow and Turbulence in
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102. McLelland, W.G. and Garcia, M.: “Investigation into Oil/Water Separation Problems
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103. Mehdizadeh, P., Marrelli, J. and Ting, V.C.: “Wet Gas Metering: Trends in Applications
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104. Mehdizadeh, P.: “Better net oil monitoring,” Hart’s E&P, August 2000, pp. 135-136.
105. Mehdizadeh, P.: “Multiphase Meters: Delivering Improved Production Measurements
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106. Milin, L., K.T. Hsieh and Rajamani, R.K.: “The Leakage Mechanisms in the
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107. Millington, B.C. and Thew, M.T.: “LDA Study of Component Velocities in Air-Water
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112. NATCO, “Gasunie Cyclone Separator, The Problem-Solver for Liquid/Solid Extraction,”
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122. Pauley, J.C., Wheeler, M.C. and Schrodt, J.L.G.: “The SpliTigator: Enhancing the Value
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124. Petroleum Technology Transfer Council, PTTC, Network News, vol. 8, No. 1, 1st Quarter
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133. Priestman, G.H. and Tippetts, J.R.: “Application of Power Fluidics to Level Control in
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150. Small, D.M., Fitt, A.D. and Thew, M.T.: “The Influence of Swirl and Turbulence
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Compact Liquid-Gas Partial Separation: Downhole and Surface Installations for
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Dallas, Oct. 22-25, 1995.
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182. Wesson, G.D. and Petty, C.A.: “Bibliography,” Hydrocyclone Development Consortium,
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OIL/WATER EMULSION
1. Bernal, A. and Zheng, G.: “Improved Emulsion Viscosity Correlation for Pipephase
Simulator,” Report No. 93-037, Texaco E&P Technology Department.
2. Cai, X. D.: “A Method to Supply user-Defined Oil-Water Emulsion Viscosity Equations
to Pipephase Simulator,” Report No. 94-0222, Texaco E&P Technology Department.
B-31
MICROGRAVITY
1. Yeh, T.W., Agrawal, A.K. and Griffin, D.W.: “Gravitational Effects on Near Field Flow
Structure of Low Density Gas Jets, American Institute of Aeronautics and Astronautics
2001-0761.
FPSO PAPERS
1. Kreke, M.H. and Kaminski, M.L.: “FPSOs: Design Considerations for the Structural
Interface Hull and Topsides,” OTC 13996, presented at the 2002 Offshore Technology
Conference, Houston, TX, May 6-9, 2002.
2. Wang, M.: “A Rational Approach to FPSO Hull Configuration Selection,” OTC 13997,
presented at the 2002 Offshore Technology Conference, Houston, TX, May 6-9, 2002.
3. Soeters, M., Reynolds, K. and Elk, H.V.: “The Blake Development Project proves the
flexibility of FPSOs in the successful completion of a schedule driven modification to a
producing FPSO,” OTC 13998, presented at the 2002 Offshore Technology Conference,
Houston, TX, May 6-9, 2002.
4. Park, I-K., Shin, H-S., Chung, H-W. and Beek J.W.F.: “Development of a Deep Sea
FPSO Suitable for the Gulf of Mexico Area,” OTC 13999, presented at the 2002 Offshore
Technology Conference, Houston, TX, May 6-9, 2002.
5. Daughdrill, W.H. and Clark, T.A.: “Considerations in Reducing Risks in FPSO and
Shuttle Vessel Lightering Operations,” OTC 14000, presented at the 2002 Offshore
Technology Conference, Houston, TX, May 6-9, 2002.
6. Okamoto, N., Hirayama, H., Ishida, K. and Nishigaki, M.: “Competitive CVAR-FPSO
concepts with Dry trees in ultra-deepwater; Weathervaning CVAR-FPSO for Brazil and
Indonesia vs. Non-weathervaning for West Africa,” OTC 14001, presented at the 2002
Offshore Technology Conference, Houston, TX, May 6-9, 2002.
7. Alvarado, C.S., Cone, R.S. and Wagner, J.V.: “Next Generation FPSO: Combining
Production and Gas Utilization,” OTC 14002, presented at the 2002 Offshore Technology
Conference, Houston, TX, May 6-9, 2002.
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8. Wadah, A. and Christiansen, P.: “LNG FPSO Based on Spherical Tanks,” OTC 14095,
presented at the 2002 Offshore Technology Conference, Houston, TX, May 6-9, 2002.
9. Han, H.Y.S., Lee, J. and Kim, Y.: “Design Development of FSRU from LNG Carrier
and FPSO Construction Experiences,” OTC 14098, presented at the 2002 Offshore
Technology Conference, Houston, TX, May 6-9, 2002.
SUBSEA PAPERS
1. Allen, J.: “Cost Effective System Solutions for Deepwater Production Controls,” OTC
8480, presented at the 1997 Offshore Technology Conference, Houston, TX, May 5-8,
1997, pp. 421-435.
2. Beltrao, R.L.C.: “Cost Reduction in Deep Water Production Systems,” OTC 7898,
presented at the 27th Annual OTC in Houston, TX, May 1-4, 1995, pp. 263-273.
3. Beran, W.T. Hatton, G.J., Stires, J.L. and Gunderson, R.H.: “Subsea Pressure
Boost/Separation: A Necessity for Deepwater Development?” OTC 7267, presented at
the 25th Annual OTC in Houston, TX, May 3-6, 1993, pp. 51-59.
4. Birrell, N.D.: “Deepwater Engineering Trends,” OTC 7629, presented at the 26th Annual
OTC in Houston, TX, May 2-5, 1994, pp. 941-951.
5. Bowers, B.E., Brownlee, R.F and Schrenkel, P.J.: “Development of a Downhole
Oil/Water Separation and Reinjection System for Offshore Application,” OTC 8865,
presented at the 1998 Offshore Technology Conference, Houston, TX, May 4-7, 1998,
pp. 639-647.
6. Bringedal, S., Ingebretsen, T. & Haugen, K.: “Subsea Separation and Reinjection of
Produced Water,” OTC 10967, presented at the 1999 Offshore Technology Conference,
Houston, TX, May 3-6, 1999.
7. Caetano, E.F., Pinheiro, J.A.S.F., Moreira,C.C. and Farestvedt, L.: “MMS 1200:
cooperation on a Subsea Multiphase Flow Meter Application,” OTC 8506, presented at
the 1997 Offshore Technology Conference, Houston, TX, May 5-8, 1997, pp. 115-121.
B-33
8. Carman, R.J., McAdams, J.P and Vilarinho, S.H.: “A Subsea Control System for Phase 1
Development of Garoupa Field,” SPE 7227, Journal of Petroleum Technology, April
1979, pp.398-406.
9. De Donno, S., Colombi, P., Chiesa, G., and Aggradi, G.F.: “The Experience from Field
Operation of a Subsea Multiphase Booster,” OTC 7934, presented at the 27th Annual
OTC in Houston, TX, May 1-4, 1995, pp. 611-617.
10. Dunn, F.P.: “Deepwater Production: 1950-2000,” OTC 7627, presented at the 26th
Annual OTC in Houston, TX, May 2-5, 1994, pp. 921-927.
11. Eyre, G.P. and Day, A.: “Engineering the DEEPSEP Subsea Boosting System,” OTC
7739, presented at the 27th Annual OTC in Houston, TX, May 1-4, 1995, pp. 429-440.
12. Franca, F.A., Rosa, E.S., Bannwart, A.C., Moura, L.F. and Alhanati, F.J.:
“Hydrodynamic Studies on a Cyclonic Separator,” OTC 8059, presented at the 28th
Annual OTC in Houston, TX, May 6-9, 1996, pp. 281-289.
13. Hall, J.E., Sheng, W.Z., Krenek, M.J., Douglas, L.D., Macfarlane, A.M. and Mohr, H.O.:
“Liuhua 11-1 Development – Subsea Production System Overview,” OTC 8175,
presented at the 28th Annual OTC in Houston, TX, May 6-9, 1996, pp. 213-233.
14. Hansen, R.L. & Rickey, W.P.: “Evolution of Subsea Production Systems: A Worldwide
Overview,” SPE 29084, Journal of Petroleum Technology, August 1995, pp. 675-680.
15. High, G. and Wright, P.J.: “Subsea Fibre Optic Communications for Production Control
and Data Acquisition,” OTC 8167, presented at the 28th Annual OTC in Houston, TX,
May 6-9, 1996, pp. 155-163.
16. High G., Frantzen, K.H. and Marshall, M.: “On-Line Subsea Multiphase Flow
Measurement,” OTC 7933, presented at the 27th Annual OTC in Houston, TX, May 1-4,
1995, pp. 597-610.
17. Hodson, J.E., Childs, G. and Palmer, A.J.: “The Application of Specialist Hydrocyclones
for Separation Clean-Up of Solids in the Oil and Gas Industry,” OTC 7590, presented at
the 26th Annual OTC in Houston, TX, May 2-5, 1994, pp. 727-744.
B-34
18. Haugen, S., Hodgson, S., Upchurch, J., McMahan, J., Hazelrigg, K. and Mundorff, J.:
“Clamp on Ultrasonic Instruments in Subsea Applications,” OTC 7746, presented at the
27th Annual OTC in Houston, TX, May 1-4, 1995, pp. 1-7.
19. Jefferies, A.T., Loegering, C., Steib, D. and Schlater, D.: “Shasta/Mustique Subsea
Equipment Platform Interface and Operability,” OTC 8251, presented at the 28th Annual
OTC in Houston, TX, May 6-9, 1996, pp. 895-904.
20. Jones, J.W.: “Subsea Production Systems – Trends in the Nineties,” OTC 7866,
presented at the 27th Annual OTC in Houston, TX, May 1-4, 1995, pp. 541-549.
21. Karlsen, A. & Gustavsson, K.: “Muxcom – A New Subsea Control Concept for Very
Deep Water,” SPE 19227, presented at Offshore Europe ‘89, Aberdeen, Sep. 5-8, 1989,
pp. 1-6.
22. Karrer E. and Victer, W.G.: “Strategies for Cost Effective Solutions in Deep Water
Production,” OTC 8095, presented at the 28th Annual OTC in Houston, TX, May 6-9,
1996, pp. 629-634.
23. Kirkbride, P., Brown, P.G. and Bloomer J.P.: “Lightweight Subsea Manifold Design,”
OTC 7528, presented at the 26th Annual OTC in Houston, TX, May 2-5, 1994, pp. 177-
187.
24. Koene, F., de Graauw, Ir. J. and Swanborn, R.A.: “New Separator Internals Cut
Revamping Costs,” OTC 7742, presented at the 27th Annual OTC in Houston, TX, May
1-4, 1995, pp. 441-447.
25. Leith, G.J. and Anson, B.: “The Subsea Master Station: Its Evolution and Current
Applications,” OTC 7252, presented at the 25th Annual OTC in Houston, TX, May 3-6,
1993, pp. 449-460.
26. Letton W., Svaeren, J.A. & Conort, G.: “Topside and Subsea Experience with the
Multiphase Flow Meter,” SPE 38783, presented at the 1997 SPE Annual Technical
Conference and Exhibition, San Antonio, TX, October 5-8, 1997, pp. 345-357.
27. Marshall, P.W.: “Infrastructure for Regional Development in Deep Water,” OTC 7867,
presented at the 27th Annual OTC in Houston, TX, May 1-4, 1995, pp. 551-562.
B-35
28. Nordvlk, H.S., Sarshar, M.M. & Taylor, M.: “Subsea Processing and Control System in
the GASP Project: Testing of the Prototype System,” SPE 22526, Journal of Petroleum
Technology, March 1992, pp. 341-349.
29. Pagot, P.R., Werneck, M., Assayag, S., Cerqueira, M.B. and Herdeiro, M.A.N.: “Subsea
Separation Systems,” OTC 8060, presented at the 28th Annual OTC in Houston, TX, May
6-9, 1996, pp. 291-299.
30. Powers, M.L.: “New Perspective on Oil and Gas Separator Performance,” SPE paper
20699, SPE Production and Facilities, May 1993, pp. 77-83.
31. Prichard, R.M., DeJohn, K.P. and Baggs, C.: “Pompano Subsea Development:
Production Control System and Umbilicals,” OTC 8206, presented at the 28th Annual
OTC in Houston, TX, May 6-9, 1996, pp. 525-535.
32. Rickey, W.P., Stair, M.A. and Curtis, E.M.: “Zinc Project: Integration Land testing of
the Subsea Control System,” OTC 7243, presented at the 25th Annual OTC in Houston,
TX, May 3-6, 1993, pp. 365-373.
33. Ritter, P.B., Langner, C.G., Sgouros, G.E., Saucier, B.J. and Voss, R.V.: “Popeye
Project: Subsea System,” OTC 8126, presented at the 28th Annual OTC in Houston, TX,
May 6-9, 1996, pp. 97-112.
34. Rule, D.D. and Rickey, W.P.: “The Evolution and Future Trends in Remote Subsea
Maintenance,” SPE paper 18355, presented at the SPE European Petroleum Conference,
London, UK, Oct 16-19, 1988, pp. 193-199.
35. Smith, N.J.: “The Economic Case for Floating Production Facilites,” OTC 7865,
presented at the 27th Annual OTC in Houston, TX, May 1-4, 1995, pp. 535-539.
36. Slater, S.G., Paterson, A.McK. and Marshall, M.F.: “The Development and Use of a
Subsea Multiphase Flow Meter on the UK South Scott Field,” OTC 8549, presented at
the 1997 Offshore Technology Conference, Houston, TX, May 5-8, 1997, pp. 523-531.
37. Remedial Action Approach for the Subsea Control System,” OTC 7293, presented at the
25th Annual OTC in Houston, TX, May 3-6, 1993, pp. 319-329.
B-36
38. Vujasinovic, A.N. & McMahan, J.M.: “Deepwater Hydraulic BOP Control Systems,”
SPE 15890, presented at the SPE European Petroleum Conference, London, UK, October
20-22, 1986, pp. 381-384.
39. Walker, J.F., Jr. and Cummins, R.L.: “Development of a Centrifugal Downhole
Separator,” OTC 11031, presented at the 1999 Offshore Technology Conference,
Houston, TX, May 3-6, 1999, pp. 649-659.
40. White, J., Adamson, S.M. and Hadfield, P.E.: “Cost-Reduction Achieved by
Convergence of Subsea Technology in Both Shallow and Deep Water,” OTC 7189,
presented at the 25th Annual OTC in Houston, TX, May 3-6, 1993, pp. 505-514.
CD ROM - PROCEEDINGS
1. ASME Fluids Engineering Division Summer Meeting, Vancouver, British Columbia,
Canada, June 22-26, 1997.
2. Fifth Latin American and Caribbean Petroleum Engineering Conference and Exhibition,
Rio de Janeiro, Brazil, August 30 to September 3, 1997.
3. ASME Energy Sources Technology Conference and Exposition (ETCE’98) Proceedings,
Houston, TX, Feb. 2-4, 1998.
4. ASME Fluids Engineering Division Summer Meeting, Washington, D.C., June 21-25,
1998.
5. 1998 SPE Annual Technical Conference and Exhibition, New Orleans, LA, September
27-30, 1998.
6. ASME 1999 Energy Sources Technology Conference (ETCE’99), Houston, TX, Feb. 1-
3, 1999.
7. Computer Software & Documentation for the Oil & Gas Industry, compliments of
NPTO/DOE.
8. “Detection and Analysis of Naturally Fractured Gas Reservoirs-Low-Permeability
Reservoirs Project,” U.S. Department of Energy, Office of Fossil Energy, Federal Energy
Technology Center.
9. The Department of Energy’s GASIS Gas Information System, GASIS Release 2, June
1999.
B-37
10. 3rd ASME/JSME Joint Fluids Engineering Conference & FED Summer
Meeting/Exhibition, San Francisco, California, July 18-22, 1999.
11. 1999 SPE Annual Technical Conference and Exhibition, Houston, TX, October 3-6,
1999.
12. ASME ETCE/OMAE 2000 Joint Conference, Energy for the New Millennium, New
Orleans, LA, February 14-17, 2000.
13. 17th International North Sea Flow Measurement Workshop, Clarion Oslo Airport Hotel,
Gardermoen, Norway, October 25-28, 1999.
14. Proceedings of the 1999 Oil & Gas Conference, Technology Options for Producer
Survival, Dallas, Texas, June 28-30, 1999.
15. National Engineering Laboratory, (NEL), Scotland, United Kingdom.
16. Bugli, N., Chen, W. and Reynolds, S., Editors: “Filtration and Separations Technologies
for 2000,”Advances in Filtration and Separation Technology, Vol. 14, American
Filtration & Separations Society (AFS).
17. ASME International, ETCE 2001 Conference (Engineering Technology Conference on
Energy), Houston, TX, Feb. 5-7, 2001.
18. Proceedings of the AFS 15th Annual Technical Conference and Exposition, Galveston,
TX, April 9–12, 2002.
19. 2002 SPE Annual Technical Conference and Exhibition, San Antonio, TX, September
29-October 2, 2002.
20. 2002 AFS, Fluid/Particle Separation Journal, Vol. 14, No. 2, August 2002.
21. Proceedings of the International Symposium on Oilfield Chemistry, Society of Petroleum
Engineers, Houston, TX, February 5-7, 2003.
VIDEO CASSETTES
1. Stratified Flow-21618 EN VHS, time: 29:07.
2. Flow Visualization-21607 VHS, time: 30:12.
PROPOSAL For
DESIGN AND DEVELOPMENT OF INTEGRATED
COMPACT MULTIPHASE SEPARATION SYSTEMS (CMSS)
Submitted to
The U.S. Department of Energy (DOE)
by
Ram S. Mohan, Associate Professor of Mechanical Engineering Ovadia Shoham, Professor of Petroleum Engineering
Shoubo Wang, Visiting Assistant Professor of Petroleum Engg. Luis Gomez, Visiting Assistant Professor of Petroleum Engg.
August 2002
The University of TulsaOffice of Research and Sponsored Programs600 S College AvenueTulsa, OK 74104
Title: Design and Development of Integrated Compact Multiphase Separation Systems (CMSS)
Proposed Duration: 72 mos. Requested Starting Date: October 1, 2002
Amount Requested: $1,835,104
Type of business: Nonprofit Educational Institution
Principal Investigator: Dr. Ram S. Mohan, Mechanical Engineering
Phone: (918) 631-2075 E-mail: [email protected]
Business Contact: Ms. Debbie Newton, Office of Research and Sponsored Programs
Phone: (918) 631-2192 E-mail: [email protected]
Date of Submission: 9-Aug-02
This proposal:1. May be subjected to external review2. Is valid for a period of six (6) months from the submission date3. Has not been submitted to any other Federal, State, local agency or other party.4. Does not contain proprietary information.
Principal Investigator DateRam Mohan, Associate ProfessorDepartment of Mechanical Engineering
Authorized Officer DateAllen R. Soltow, Executive DirectorResearch, Sponsored Programs and Governmental Relations
UNSOLICITED PROPOSAL SUBMITTED TO THE DEPARTMENT OF ENERGY BY:
Cover Page
1
TABLE OF CONTENTS
page
EXECUTIVE SUMMARY 4
1. INTRODUCTION 7
2. LITERATURE SURVEY AND BACKGROUND 11
2.1 Compact Separators for Multiphase Flow 11
2.2 Control System Studies 13
2.3 CFD Simulations and Bubble Trajectories 14
2.4 Swirling Flow Field 16
2.5 Droplet Size Distribution 16
2.6 Floating Production Storage and Offloading (FPSO) Systems 17
2.7 Subsea Operations 18 3. OBJECTIVES 21
4. SUMMARY OF COMPLETED DOE PROJECT 23
4.1 Oil-Water-Gas State-of-the Art Flow Loop 24
4.2 GLCC Development 27
4.3 LLCC Development 30
4.4 GLLCC Development 34
4.5 LLHC Study 37
4.6 High Pressure Testing 43
4.7 Control Strategies Development 45
4.8 Mechanistic Models and Design Procedures for GLCC, LLCC,
GLLCC and LLHC 48
4.9 Technology Transfer and Resulted Field Applications 51
5. COMPACT SEPARATION TECHNOLOGY RESEARCH AT TUSTP 54
5.1 TUSTP Accomplishments 60
6. SIGNIFICANCE AND POTENTIAL OF PROPOSED PROJECT 65
6.1 Industrial Application 65
6.2 Uniqueness of TUSTP Research Capabilities 65
2
6.3 Cost Savings for the Industry 67
6.4 Environmental and Safety Considerations 68
6.5 Support DOE Missions 69
7. SCOPE OF WORK 71
7.1 Phase I (October 2002 – September 2004) 71
7.1.1 Development of Horizontal Pipe Separator (HPS) 71
7.1.2 Development of Slug Damper (SD) 75
7.1.3 Development of Helical Pipe Separator (HP) 77
7.1.4 Design of Slug Generator (SG) 80
7.2 Phase II (October 2004 – September 2006) 82
7.2.1 Experimental Program 82
7.2.2 Data Acquisition 84
7.2.3 CFD Simulations and Mechanistic Modeling 85
7.3 Phase III (October 2006 – September 2008) 86
7.3.1 Control Strategies Development 86
7.3.2 Universal Model Development 86
7.3.3 High Pressure Testing 86
7.3.4 Design Criteria and Design Guidelines Development 86
7.3.5 Design Code Simulators and CMSS Field Prototype 87
8. SCHEDULE OF WORK 88
8.1 Phase I Tasks 89
8.2 Phase II Tasks 89
8.3 Phase III Tasks 90
8.4 Deliverables 91
9. TECHNOLOGY TRANSFER AND TECHNOLOGY DEPLOYMENT 93
10.BUDGET AND PERSONNEL 95
10.1 Current Support 95
10.2 Budget 96
10.3 Research Personnel 105
3
11. REFERENCES 108
APPENDIX I - LETTERS OF SUPPORT FROM INDUSTRY
APPENDIX II - LETTER OF SUPPORT - THE UNIVERSITY OF TULSA
APPENDIX III - LETTER OF SUPPORT – COLORADO ENGINEERING
EXPERIMENT STATION (CEESI)
APPENDIX IV - ASSURANCES AND CERTIFICATION
APPENDIX V - LIST OF M.S. THESIS AND Ph.D. DISSERTATION OF TUSTP
APPENDIX VI - LIST OF TUSTP PUBLICATIONS
4
EXECUTIVE SUMMARY
The petroleum industry has relied in the past mainly on conventional vessel-type separators, which are bulky, heavy and expensive, to process wellhead production of oil-water-gas flow. Economic and operational pressures continue to force the petroleum industry to seek less expensive and more efficient separation alternatives in the form of compact separators. The compact dimensions, smaller footprint and lower weight of compact separators have a potential for cost savings to the industry, especially in offshore and subsea applications. Also, compact separators reduce the inventory of hydrocarbons significantly, which is critical for environmental and safety considerations.
There has been considerable progress, during the past five years, in the research conducted in this area at the Tulsa University Separation Technology Projects (TUSTP) for two-phase and three-phase separation. Most of the R&D at TUSTP in the past 5 years has been carried out through a DOE grant (Mohan and Shoham, 1997). Several compact separator components have been studied, developed and are currently implemented in the field. These include the Gas-Liquid-Cylindrical Cyclone (GLCC�1), the Liquid-Liquid Cylindrical Cyclone (LLCC�2), Gas-Liquid-Liquid-Cylindrical Cyclone (GLLCC�3) and Liquid-Liquid Hydrocyclones (LLHC). Appropriate control strategies have been developed for proper operation of the GLCC� and LLCC� and testing of these devices at high pressure and real crude conditions is ongoing.
The significance of the conducted research of the completed DOE project has been highly appreciated by the industry, as shown by their continuing support to the consortium. TUSTP research team provides expertise in several essential areas, such as multiphase flow measurement and instrumentation, mathematical modeling, fluid mechanics, computational fluid dynamics, process control and high-pressure field applications. Due to the much-needed interdisciplinary nature of the research team, currently no other industry/university research consortium exists in the area of compact multiphase separation technology.
Over 300 GLCC’s that have already been installed and put to use in the field have successfully demonstrated the pronounced impact compact separators are having on the petroleum industry. However, up to date only individual compact separation components have been studied and implemented. Although these individual components have been proven to be successful for bulk separation, they cannot guarantee complete separation of the phases, delivering clean streams of gas, oil and water. To accomplish this final goal, a compact separation system needs to be developed, integrating the individual compact separation components into a system. The developed system should ensure simple, cost-effective, and efficient separation of clean streams of gas, oil, water and solids. This is the gap the proposed study intends to fill.
Goals of the Proposed DOE Project: The current proposal aims at an extension of the above-completed DOE project for an additional period of six years (2002 to 2008). Even though the already developed individual compact separation components have been proven to
1 GLCC� - Gas-Liquid Cylindrical Cyclone - Copyright, The University of Tulsa, 1994 2 LLCC� - Liquid-Liquid Cylindrical Cyclone - Copyright, The University of Tulsa, 1998 3 GLLCC� - Gas-Liquid-Liquid Cylindrical Cyclone - Copyright, The University of Tulsa, 2000
5
be successful for bulk separation, they cannot guarantee complete phase separation delivering clean streams of gas, oil and water. The overall objective of the proposed six-year project is the development of compact multiphase separation systems (CMSS�4) for onshore and offshore applications (including Floating Production Storage and Offloading, FPSO, systems) integrating the already developed and to be developed individual components. These systems will ensure simple, compact, cost-effective, and high-efficient separation of clean streams of gas, oil, water and solids. FPSO systems have been in use in Europe (Atlantic Frontier and North Sea). Recently they are becoming more popular in the Gulf of Mexico due the safety considerations related to the frequent occurrence of hurricanes. However, the challenges with FPSOs are problems in structural integrity due to frequent slushing and 2-5 degree oscillation, and resulting occurrence of foam. The developed compact multiphase separation systems will also be adaptable for subsea applications.
The initial phase of the project (Phase I - 2002 - 2004) will focus on the development of additional individual compact separation components, such as the horizontal pipe separator (HPS), for obtaining clean oil stream from oil-water mixture, flow conditioning components, such as the helical pipe (HP) and slug damper (SD), for dissipating slugs upstream of the compact separators and solid separation unit (SSU). Expansion of the existing TUSTP three-phase flow loop, which will enable testing of integrated CMSSs at higher pressures (up to 200 psia), with upstream slug train generator (SG), will be designed.
The second phase of the project (Phase II - 2004 - 2006) will include the construction of the proposed expansion of the existing flow loop to enable high pressure testing, up to 200 psia. Experimental investigation of the integrated CMSS for different configurations will be carried out in order to evaluate the performance of the individual separation components, integrated in the CMSS, and the total system performance. Also, appropriate CFD simulations will be carried out and dedicated mechanistic models for the CMSS will be developed, utilizing the already developed models for the individual components. Control system studies will be initiated during this phase.
In the final phase of the project (Phase III - 2006 - 2008) dedicated control strategies will be studied and developed for the CMSS. Also, a universal model for prediction of droplet size distribution, in the individual subsystem components and the integrated system, will be developed. High Pressure testing (up to 1000 psia) under real crude conditions will be conducted at available suitable experimental loops (Colorado Engineering Experimentation Station – CEESI) to evaluate the reliability of the integrated compact separation system and improve the design model, prior to implementation in the field. Software simulators will be developed for the proposed CMSSs, to be used by the industry as design tools. The final product of the project will be a design of a CMSS prototype tested for high-pressure real crude conditions and ready for field deployment.
The proposed fundamental CMSS configuration is presented in the figure below. It includes a GLCC for initial gas-liquid separation. The separated gas stream flows into gas scrubber consisting of a standard mist extractor to ensure dry gas stream for downstream use. The liquid phase off the GLCC liquid leg is sent to a Free-Water-Knock-Out (FWKO) LLHC to extract free water from the oil-water mixture. The oil-rich stream from the FWKO LLHC 4 CMSS� - Compact Multiphase Separation Systems - Copyright, The University of Tulsa, 2002
6
will flow into a standard LLHC that will produce a clean oil stream. The water stream from the FWKO and the standard LLHC will flow into a water polishing LLHC for final cleaning of the water stream. The oil extracted from the water-polishing unit will be combined with the oil stream of the standard LLHC for transport to downstream facilities. The GLCC will be augmented for sand separation with a Solid Separation Unit (SSU). Suitable control systems are a crucial component of this CMSS train and will be developed as part of this project.
After the above-mentioned fundamental CMSS configuration is developed and tested, possible alternative components, developed as part of this study, will be integrated into the CMSS train. The alternative components will be more economical and also better perform, than the standard devices available today, which are used in the fundamental CMSS configuration. These alternative components include LLCC to replace the FWKO LLHC, HPS to replace the standard LLHC, a wet gas GLCC to replace or augment the mist extractor. It is important to note that, in principle, it is not necessary to replace all the components of the fundamental CMSS configuration for a given application, rather one of the components can be substituted, based on the application need. Another alternative is using a GLLCC instead of the GLCC for pre-separation of the oil-water mixture.
We believe that the qualifications of the key research personnel, the on going TUSTP research consortium, available test facilities and infrastructure, and university support, provide a unique opportunity to make this project a success. These essential ingredients will ensure the development of the state-of-the-art technology in compact separation technology for the 21st century.
LLHCG L C C
LLHC
Wet Gas Scrubber
Clean Gas
Clean Oil For
Transport Three Phase
Mixture
FWKOLLHC
Clean Water For Disposal
SSU Solids
Fig. 1. Fundamental CMSS� Configuration Using Field Tested Components
COVER SHEET FOR PROPOSAL TO THE NATIONAL SCIENCE FOUNDATIONFOR NSF USE ONLY
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Page 1 of 2
0332020EEC - INDUSTRY/UNIV COOP RES CENTERS
NSF 01-116 03/31/03
173057928
University of Tulsa
0031856000
University of Tulsa600 South College Ave.Tulsa, OK. 741043189
Collaborative Research: Operational Proposal for I/UCRC on Multiphase Transport Phenomena
330,000 60 08/15/03 0245669
Mechanical Engineering
918-631-2397
600 South College AvenueL169 Keplinger HallTulsa, OK 741043189United States
Ram S Mohan Ph.D. 1996 918-631-2075 [email protected]
072420433
0332020
CERTIFICATION PAGE
Certification for Authorized Organizational Representative or Individual Applicant:By signing and submitting this proposal, the individual applicant or the authorized official of the applicant institution is: (1) certifying thatstatements made herein are true and complete to the best of his/her knowledge; and (2) agreeing to accept the obligation to comply with NSFaward terms and conditions if an award is made as a result of this application. Further, the applicant is hereby providing certificationsregarding debarment and suspension, drug-free workplace, and lobbying activities (see below), as set forth in GrantProposal Guide (GPG), NSF 03-2. Willful provision of false information in this application and its supporting documents or in reports requiredunder an ensuing award is a criminal offense (U. S. Code, Title 18, Section 1001). In addition, if the applicant institution employs more than fifty persons, the authorized official of the applicant institution is certifying that the institution has implemented a written and enforced conflict of interest policy that is consistent with the provisions of Grant Policy Manual Section 510; that to the bestof his/her knowledge, all financial disclosures required by that conflict of interest policy have been made; and that all identified conflicts of interest will havebeen satisfactorily managed, reduced or eliminated prior to the institution’s expenditure of any funds under the award, in accordance with theinstitution’s conflict of interest policy. Conflicts which cannot be satisfactorily managed, reduced or eliminated must be disclosed to NSF.
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(3) The undersigned shall require that the language of this certification be included in the award documents for all subawards at all tiers includingsubcontracts, subgrants, and contracts under grants, loans, and cooperative agreements and that all subrecipients shall certify and disclose accordingly.
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0332020
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0331977EEC - INDUSTRY/UNIV COOP RES CENTERS
NSF 01-116 03/31/03
386005984
Michigan State University
0022905000
Michigan State UniversityContracts & Grants DepartmentEast Lansing, MI. 488241046
Collaborative Research: Operating Proposal for I/UCRC on Multiphase Transport Phenomena
430,000 60 08/15/03 0245644
Chemical Engineering
517-432-1105
South Shaw Lane and Red Cedar Road2527 Engineering BuildingEast Lansing, MI 488241226United States
Charles A Petty PhD 1970 517-353-5486 [email protected]
Andre Benard PhD 1996 517-432-1522 [email protected]
Tom I-P Shih Ph.D 1981 517-432-3658 [email protected]
193247145
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0331977
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Certification for Authorized Organizational Representative or Individual Applicant:By signing and submitting this proposal, the individual applicant or the authorized official of the applicant institution is: (1) certifying thatstatements made herein are true and complete to the best of his/her knowledge; and (2) agreeing to accept the obligation to comply with NSFaward terms and conditions if an award is made as a result of this application. Further, the applicant is hereby providing certificationsregarding debarment and suspension, drug-free workplace, and lobbying activities (see below), as set forth in GrantProposal Guide (GPG), NSF 03-2. Willful provision of false information in this application and its supporting documents or in reports requiredunder an ensuing award is a criminal offense (U. S. Code, Title 18, Section 1001). In addition, if the applicant institution employs more than fifty persons, the authorized official of the applicant institution is certifying that the institution has implemented a written and enforced conflict of interest policy that is consistent with the provisions of Grant Policy Manual Section 510; that to the bestof his/her knowledge, all financial disclosures required by that conflict of interest policy have been made; and that all identified conflicts of interest will havebeen satisfactorily managed, reduced or eliminated prior to the institution’s expenditure of any funds under the award, in accordance with theinstitution’s conflict of interest policy. Conflicts which cannot be satisfactorily managed, reduced or eliminated must be disclosed to NSF.
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Is the organization or its principals presently debarred, suspended, proposed for debarment, declared ineligible, or voluntarily excluded from covered transactions by any Federal department or agency? Yes No
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Certification Regarding LobbyingThis certification is required for an award of a Federal contract, grant, or cooperative agreement exceeding $100,000 and for an award of a Federal loan ora commitment providing for the United States to insure or guarantee a loan exceeding $150,000.
Certification for Contracts, Grants, Loans and Cooperative AgreementsThe undersigned certifies, to the best of his or her knowledge and belief, that:
(1) No federal appropriated funds have been paid or will be paid, by or on behalf of the undersigned, to any person for influencing or attempting to influencean officer or employee of any agency, a Member of Congress, an officer or employee of Congress, or an employee of a Member of Congress in connectionwith the awarding of any federal contract, the making of any Federal grant, the making of any Federal loan, the entering into of any cooperative agreement,and the extension, continuation, renewal, amendment, or modification of any Federal contract, grant, loan, or cooperative agreement.
(2) If any funds other than Federal appropriated funds have been paid or will be paid to any person for influencing or attempting to influence an officer oremployee of any agency, a Member of Congress, an officer or employee of Congress, or an employee of a Member of Congress in connection with thisFederal contract, grant, loan, or cooperative agreement, the undersigned shall complete and submit Standard Form-LLL, ‘‘Disclosure of Lobbying Activities,’’ in accordance with its instructions.
(3) The undersigned shall require that the language of this certification be included in the award documents for all subawards at all tiers includingsubcontracts, subgrants, and contracts under grants, loans, and cooperative agreements and that all subrecipients shall certify and disclose accordingly.
This certification is a material representation of fact upon which reliance was placed when this transaction was made or entered into. Submission of thiscertification is a prerequisite for making or entering into this transaction imposed by section 1352, Title 31, U.S. Code. Any person who fails to file therequired certification shall be subject to a civil penalty of not less than $10,000 and not more than $100,000 for each such failure.
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TELEPHONE NUMBER ELECTRONIC MAIL ADDRESS FAX NUMBER
*SUBMISSION OF SOCIAL SECURITY NUMBERS IS VOLUNTARY AND WILL NOT AFFECT THE ORGANIZATION’S ELIGIBILITY FOR AN AWARD. HOWEVER, THEY ARE ANINTEGRAL PART OF THE INFORMATION SYSTEM AND ASSIST IN PROCESSING THE PROPOSAL. SSN SOLICITED UNDER NSF ACT OF 1950, AS AMENDED.
Page 2 of 2
Craig E ONeill Mar 31 2003 2:41PMElectronic Signature
517-353-7885 [email protected] 517-353-9812
0331977
COVER SHEET FOR PROPOSAL TO THE NATIONAL SCIENCE FOUNDATIONFOR NSF USE ONLY
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NAME OF ORGANIZATION TO WHICH AWARD SHOULD BE MADE ADDRESS OF AWARDEE ORGANIZATION, INCLUDING 9 DIGIT ZIP CODE
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IS AWARDEE ORGANIZATION (Check All That Apply) SMALL BUSINESS MINORITY BUSINESS IF THIS IS A PRELIMINARY PROPOSAL(See GPG II.C For Definitions) FOR-PROFIT ORGANIZATION WOMAN-OWNED BUSINESS THEN CHECK HERE
NAME OF PERFORMING ORGANIZATION, IF DIFFERENT FROM ABOVE ADDRESS OF PERFORMING ORGANIZATION, IF DIFFERENT, INCLUDING 9 DIGIT ZIP CODE
PERFORMING ORGANIZATION CODE (IF KNOWN)
TITLE OF PROPOSED PROJECT
REQUESTED AMOUNT
$
PROPOSED DURATION (1-60 MONTHS)
months
REQUESTED STARTING DATE SHOW RELATED PRELIMINARY PROPOSAL NO.IF APPLICABLE
CHECK APPROPRIATE BOX(ES) IF THIS PROPOSAL INCLUDES ANY OF THE ITEMS LISTED BELOWBEGINNING INVESTIGATOR (GPG I.A)
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PROPRIETARY & PRIVILEGED INFORMATION (GPG I.B, II.C.6)
HISTORIC PLACES (GPG II.C.9)
SMALL GRANT FOR EXPLOR. RESEARCH (SGER) (GPG II.C.11)
VERTEBRATE ANIMALS (GPG II.C.11) IACUC App. Date
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PI/PD DEPARTMENT PI/PD POSTAL ADDRESS
PI/PD FAX NUMBER
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CO-PI/PD
CO-PI/PD
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0331989EEC - INDUSTRY/UNIV COOP RES CENTERS
NSF 01-116 03/31/03
346002924
University of Akron
0031237000
University of Akron302 East Buchtel AvenueAkron, OH. 443250001
Collaborative Research: Operational Proposal for I/UCRC on Multiphase Transport Phenomena
330,000 60 08/15/03 0245495
Department of Chemical Engineering
330-972-7943Akron, OH 443253906United States
George G Chase PhD 1989 330-972-7943 [email protected]
0452097552
Electronic Signature
0331989
CERTIFICATION PAGE
Certification for Authorized Organizational Representative or Individual Applicant:By signing and submitting this proposal, the individual applicant or the authorized official of the applicant institution is: (1) certifying thatstatements made herein are true and complete to the best of his/her knowledge; and (2) agreeing to accept the obligation to comply with NSFaward terms and conditions if an award is made as a result of this application. Further, the applicant is hereby providing certificationsregarding debarment and suspension, drug-free workplace, and lobbying activities (see below), as set forth in GrantProposal Guide (GPG), NSF 03-2. Willful provision of false information in this application and its supporting documents or in reports requiredunder an ensuing award is a criminal offense (U. S. Code, Title 18, Section 1001). In addition, if the applicant institution employs more than fifty persons, the authorized official of the applicant institution is certifying that the institution has implemented a written and enforced conflict of interest policy that is consistent with the provisions of Grant Policy Manual Section 510; that to the bestof his/her knowledge, all financial disclosures required by that conflict of interest policy have been made; and that all identified conflicts of interest will havebeen satisfactorily managed, reduced or eliminated prior to the institution’s expenditure of any funds under the award, in accordance with theinstitution’s conflict of interest policy. Conflicts which cannot be satisfactorily managed, reduced or eliminated must be disclosed to NSF.
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*SUBMISSION OF SOCIAL SECURITY NUMBERS IS VOLUNTARY AND WILL NOT AFFECT THE ORGANIZATION’S ELIGIBILITY FOR AN AWARD. HOWEVER, THEY ARE ANINTEGRAL PART OF THE INFORMATION SYSTEM AND ASSIST IN PROCESSING THE PROPOSAL. SSN SOLICITED UNDER NSF ACT OF 1950, AS AMENDED.
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Gerald M Parker Mar 31 2003 3:21PMElectronic Signature
330-972-7666 [email protected] 330-972-6281
0331989
National Science Foundation Industry/University Cooperative Research Center on Multiphase Transport Phenomena
Michigan State University The University of Akron, The University of Tulsa
A. 1
Section A. Project Summary
Computational multiphase transport phenomena (CMTP) is a frontier area of engineering research that broadly impacts many traditional and emerging technologies. Unfortunately, current multiphase transport models have not kept up with the rapid advancements in computational technologies. In response to this situation and the need for more efficient engineering design methods, a group of faculty at Michigan State University, The University of Akron, and The University of Tulsa has organized a pre-competitive, multiuniversity, multidisciplinary NSF Industry/University Cooperative Research Center (NSF I/UCRC) in the area of Multiphase Transport Phenomena (MTP).
Center research will focus on the further development, evaluation, and deployment of
next generation multiphase models for turbulent and non-turbulent flows as well as computational methods for rapid design and analysis of processes and equipment for a wide range of applications encountered in, but not limited to, the automotive, chemical, and petrochemical industries. Problem-oriented research related to 1) multiphase fluids, 2) multiphase phenomena in porous media, 3) multiphase mixing and reactions, 4) multiphase separations, and 5) multiphase turbulence will be addressed during the formative years of the Center. NSF funds will be used to promote long-term synergistic partnerships among industrial members and academic research groups at the three universities. Specific problem-oriented research projects will be identified in collaboration with industrial members of the Center.
Intellectual Merit of the Proposed Activity The academic research groups at the three
universities have significant complementary expertise and interest in the discovery and use of next generation multiphase transport phenomena models. The new Center will focus on the further development and validation of MTP models and computational methods motivated by problem-oriented research such as advanced filtration processes based on nanoscale fibers, multiphase separation processes related to the production of oil and gas in remote locations (subsea, downhole, and offshore), advanced fuel sprays and coking furnaces, fuel cells, and manufacturing processes involving complex fluids such as particulate suspensions, foams, emulsions, and multiphase polymeric fluids.
Broader Impacts of the Proposed Activity Industrial internships for pre-doctoral and
post-doctoral students will be an essential element of the training and technology transfer missions of NSF I/UCRC-MTP. Moreover, undergraduate and graduate student training in the use of current commercial CMTP codes will use case study problems proposed by industrial members. Akron, MSU, and Tulsa recently developed this approach as a summer workshop and Internet course on MTP under the NSF CRCD program. Thus, early training of students in the new Center will catalyze the integration of research and education as well as technology transfer in multiphase transport phenomena by bringing together experimental, theoretical, and computational experts from industry and academia.
0331977
TABLE OF CONTENTSFor font size and page formatting specifications, see GPG section II.C.
Section Total No. of Page No.*Pages in Section (Optional)*
Cover Sheet for Proposal to the National Science Foundation
A Project Summary (not to exceed 1 page)
B Table of Contents
C Project Description (Including Results from Prior
NSF Support) (not to exceed 15 pages) (Exceed only if allowed by aspecific program announcement/solicitation or if approved inadvance by the appropriate NSF Assistant Director or designee)
D References Cited
E Biographical Sketches (Not to exceed 2 pages each)
F Budget (Plus up to 3 pages of budget justification)
G Current and Pending Support
H Facilities, Equipment and Other Resources
I Special Information/Supplementary Documentation
J Appendix (List below. )
(Include only if allowed by a specific program announcement/solicitation or if approved in advance by the appropriate NSFAssistant Director or designee)
Appendix Items:
*Proposers may select any numbering mechanism for the proposal. The entire proposal however, must be paginated.Complete both columns only if the proposal is numbered consecutively.
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0331977
TABLE OF CONTENTSFor font size and page formatting specifications, see GPG section II.C.
Section Total No. of Page No.*Pages in Section (Optional)*
Cover Sheet for Proposal to the National Science Foundation
A Project Summary (not to exceed 1 page)
B Table of Contents
C Project Description (Including Results from Prior
NSF Support) (not to exceed 15 pages) (Exceed only if allowed by aspecific program announcement/solicitation or if approved inadvance by the appropriate NSF Assistant Director or designee)
D References Cited
E Biographical Sketches (Not to exceed 2 pages each)
F Budget (Plus up to 3 pages of budget justification)
G Current and Pending Support
H Facilities, Equipment and Other Resources
I Special Information/Supplementary Documentation
J Appendix (List below. )
(Include only if allowed by a specific program announcement/solicitation or if approved in advance by the appropriate NSFAssistant Director or designee)
Appendix Items:
*Proposers may select any numbering mechanism for the proposal. The entire proposal however, must be paginated.Complete both columns only if the proposal is numbered consecutively.
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0331989
TABLE OF CONTENTSFor font size and page formatting specifications, see GPG section II.C.
Section Total No. of Page No.*Pages in Section (Optional)*
Cover Sheet for Proposal to the National Science Foundation
A Project Summary (not to exceed 1 page)
B Table of Contents
C Project Description (Including Results from Prior
NSF Support) (not to exceed 15 pages) (Exceed only if allowed by aspecific program announcement/solicitation or if approved inadvance by the appropriate NSF Assistant Director or designee)
D References Cited
E Biographical Sketches (Not to exceed 2 pages each)
F Budget (Plus up to 3 pages of budget justification)
G Current and Pending Support
H Facilities, Equipment and Other Resources
I Special Information/Supplementary Documentation
J Appendix (List below. )
(Include only if allowed by a specific program announcement/solicitation or if approved in advance by the appropriate NSFAssistant Director or designee)
Appendix Items:
*Proposers may select any numbering mechanism for the proposal. The entire proposal however, must be paginated.Complete both columns only if the proposal is numbered consecutively.
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0332020
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
- C.1 -
Section C. Project Description
C.1 Executive Summary
Rationale for a Center on Multiphase Transport Phenomena
Computational multiphase transport phenomena (CMTP) is a frontier area ofengineering research that broadly impacts many traditional and emerging technologies inthe automotive (transportation), biochemical, chemical, food, medical, mining,petrochemical, and pharmaceutical industries. In a Vision 2020 report several years ago,leaders from the chemical process industries identified computational technologies as oneof five critical areas for research and education in North America (see Technology Vision2020: The U.S. Chemical Industry, ACS, 1996). Other countries, like Japan, have alsoidentified multiphase transport phenomena as an area of strategic importance for futuretechnology development (Kolev, 2002).
Although significant progress has been made in understanding and implementingCMTP over the past ten years, the impact of CMTP on engineering design remainsisolated within specific disciplines and within different industrial sectors. Furthermore,current research on CMTP in academia is widely dispersed over many universities andinteractions among departments within the same university are rare. It is noteworthy thata Delphi Forecast on Modeling and Simulation Applications for the Automotive Industry(see OSAT, 1998) concluded that “current simulation codes are not sufficientlyconfigured and integrated to allow useful design work". According to this report, one ofthe most negative attributes of current transport phenomena computational design tools isthe time required to develop a simulation. This is not unique to the automotiveindustries, but also reflects the current situation in the chemical process industries(Thompson, 2002).
Vision Statement
In response to the above situation, Michigan State University, The University ofAkron, and The University of Tulsa has formed a multi-university, multi-disciplinaryIndustry/University Cooperative Research Center (I/UCRC) in the area of MultiphaseTransport Phenomena (MTP) under the auspices of the National Science Foundation.The new Center will provide a forum for industry/university cooperative research on thefurther development of next generation multiphase transport models and innovativecomputational design methods. Over the next ten years, I/UCRC-MTP intends to becomeone of the leading industry/university research groups in the area of multiphase transportphenomena.
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
- C.2 -
Mission Statement
I/UCRC-MTP will support the combined research and education mission of theNational Science Foundation in the area of CMTP by bringing together experimental,theoretical, and computational experts from industry and academia in order to 1) conductpre-competitive leading edge research related to emerging and traditional technologiesthat involve multiphase phenomena; 2) develop next generation MTP models; 3) developnext generation CMTP design tools; and, 4) develop innovative methods to effectivelytrain students and engineers in the use of CMTP tools.
Research Focus
Specific problem-oriented research topics will include challenge problems relatedto 1) multiphase fluids, 2) multiphase phenomena in porous media, 3) multiphase mixingand reactions, 4) multiphase separations, and 5) multiphase turbulence. Research duringthe formative stages of the center will address theoretical and computational barrierproblems in the above areas with a strong emphasis on transport phenomena in fluid/fluidand solid/fluid systems.
The Multiphase Fluids Group will develop improved models and computationalmethods for predicting the microstructure of complex fluids in confined flows and freejets. The results will support the development of advanced composite materials reinforcedby nanoscale fibers and particles (clays). The goal is to develop computational toolscapable of evaluating innovative strategies for manufacturing multiphase compositematerials.
The Porous Media Group aims to develop improved models and computationalmethods for quantifying multiphase flows and heat transfer through natural and syntheticporous media. The results will support the further development of high efficiency filtersfor diesel exhaust, soot removal from engine oils, gas phase coalescers, and oil/waterseparators. In addition, improved computational tools will be used to evaluate naturalconvection heat transfer processes within fuel cells and near subsea pipelines.
The Multiphase Mixing and Reactions Group will develop improved computationalmethods for tracking the motion of an interface between two immiscible fluids. Theresults will support the analysis of multiphase processes such as liquid jet breakup,environmental mixing of oil and water, coalescence of liquid droplets on fibers, thestability of liquid/gas interfaces encountered in liquid molding, fuel sprays, interfacialreactions, and fluid/fluid separations in hydrocyclones.
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
- C.3 -
The Multiphase Separations Group will develop computational methods forpredicting the separation of oil-water-gas and re-suspension of sand in oil-water-gasflows. The results will support the evaluation of subsea and surface oil-water-gas pipelineand separator designs and the strategic placement and performance of sand separators.
The Multiphase Turbulence Group will focus on developing methods to predict themean field velocity and the mean field pressure distributions for multiphase flows withstrong streamline curvature. Research results will support the analysis of hydrocycloneseparators, mixing of liquid and gases in furnace tubes, and liquid/gas sprays.
Benefits to Industry
The I/UCRC-MTP membership fee is $30,000 per year for the first five years.Other members, the Three Universities, and the National Science Foundation willleverage this investment. With fifteen members, the Center budget for the first year willbe $732,500. As the Center grows to thirty members, the annual membership fee will beleveraged by an annual budget of $1,355,000.
All members will sign the same Membership Agreement and will be equallyrepresented on the Industrial Advisory Board. Members will participate in strategicdecisions of the Center including the selection and evaluation of research projects. Allindustrial participants will have non-exclusive rights to the entire I/UCRC-MTP researchportfolio. In addition, each I/UCRC-MTP industrial member will have an opportunity toactively participate in I/UCRC-MTP research and education programs.
Most significantly, members will also have an opportunity to propose case studyproblems and/or specific research problems and topics. The case study problems will beused to train I/UCRC-MTP students on the use of current computational technologies.Postdoctoral students will develop simulations and/or experimental results in support ofthe case studies. These results will provide a baseline for identifying the need for newdevelopments and precompetitive research.
Technology transfer between the faculty/student research teams and industrialmembers will be promoted by the following infrastructure: 1) pre-doctoral and post-doctoral industrial internships; 2) the direct involvement of the industrial advisor on theresearch team; 3) the use of commercially available software to disseminate high impactresults; 4) web based submission of quarterly and annual reports; and, 5) biannualresearch retreats on different campuses.
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
- C.4 -
C.2 I/UCRC Program
The NSF Industry/University Cooperative Research Center (I/UCRC) program,which began twenty-three years ago, is one of the most successful programs in the UnitedStates (see Gray and Walters, 1998). The recently formed multi-university I/UCRC onMultiphase Transport Phenomena (MTP) at MSU complements more than fifty I/UCRCCenters currently operating throughout North America. Michigan State University is theLead University for I/UCRC-MTP. Affiliated universities include The University ofAkron and The University of Tulsa. Other universities will be invited to participate as theneed for additional research expertise arises.
Membership Agreement and Annual Fees
During the first Industrial Advisory Board Meeting, the non-academic memberswill approve bylaws that will be used to run the Center. The bylaws will become part ofthe Membership Agreement, which is contained in Section I.3 of this proposal. TheMembership Agreement closely follows the standard I/UCRC model agreement and hasalready been reviewed (and approved) by the National Science Foundation and the threeparticipating Universities. The Membership Agreement addresses intellectual propertyrights, publication delay policy, and other relevant issues. All members pay the sameannual fee of $30,000 for the first five years. Tables in Section F of this proposalillustrate how the membership fee will be leveraged with NSF funds and University fundsto support Center research and Center operations.
National Science Foundation Support
The National Science Foundation will support the operation of I/UCRC-MTP byproviding an annual grant of $50,000 to each university with five to nine members; eachuniversity with ten or more members will receive $70,000 per year. NSF funds will beused to operate the Center and to promote long-term synergistic industry/academicresearch partnerships. The Lead University (MSU) will receive an additional $10,000 foreach affiliated university to partially cover the additional costs of managing the Center.After the fifth year, NSF funding will gradually decline to zero. After the tenth year,I/UCRC-MTP will operate independently of the National Science Foundation.
Institutional Support: Faculty Resources
Twenty-seven faculty participants representing seven disciplines (ChemicalEngineering, Electrical Engineering, Material Science, Applied Mathematics, MechanicalEngineering, Petroleum Engineering, and Polymer Science) support the research andeducational goals of I/UCRC-MTP. The research interests and expertise of the faculty aresummarized in Section E.
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
- C.5 -
The faculty will make significant in kind contributions to the Center by recruitingand mentoring graduate students. The National Science Foundation offers manyopportunities for I/UCRC-MTP research teams to apply for supplemental funding tosupport precompetitive problem-oriented research projects, to support women graduatestudents, minority graduate students, and undergraduate students. Individual I/UCRC-MTP funded projects will be enhanced significantly by faculty members takingadvantage of these opportunities.
Institutional Support: Cost Share
The participating universities will partially support the ongoing costs associatedwith the research and operation of the Center by providing a cost share equivalent to 25%of the total membership fees. University certification letters for this support weresubmitted in the September 2002 Planning Proposal and are reproduced in Section I.1 ofthis operational proposal.
Institutional Support: Commitment to Center Growth
During the first year of operation, each university will have five or more sponsorsthat will pay an annual membership fee of $30,000 each. With a total of fifteen sponsors,the first year operating budget will be $732,500, which leverages an individualmembership fee by more than a factor of 24:1. The total budget for the first year includesmembership fees at $450,000 (~ 62% of total), university cost share at $112,500 (~15%of total), and NSF funds at $170,000 (~ 23% of total). This level of funding will partiallysupport four graduate students at each university for a total of twelve students in the firstyear of operation.
The Center will grow over the first three years by adding five or more newmembers per year. Funding from the National Science Foundation will increase as newmembers are added. With thirty members, the total annual budget for the Center will be$1,355,000, which leverages an individual membership fee of $30,000 by more than afactor of 45:1. The total annual budget for a 30-member Center will include membershipfees of $900,000 (~ 66% of the total), university cost share at $225,000 (~ 17% of thetotal), and a NSF grant of $230,000 per year (~ 17%). This level of funding will supporteight graduate students at each university for a total of twenty-four I/UCRC-MTPgraduate students.
Institutional Support: Research Facilities
The computational and experimental facilities at the three universities provide aunique opportunity for research (and education) in the area of multiphase transportphenomena. A brief description of available resources is given in Section H. Graduatestudents and faculty will also have limited access to state-of-the-art facilities at industrialsites and National Laboratories (see letters-of-intent in Section I.4). Table E.1 in SectionE summarizes the experimental, theoretical, and computational expertise of the faculty.
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
- C.6 -
Benefits to Industry
The I/UCRC-MTP membership fee is $30,000 per year for the first five years.Other members, the Three Universities, and the National Science Foundation willleverage this investment. With fifteen members, the Center budget for the first year willbe $732,500. As the Center grows to thirty members, the annual membership fee will beleveraged by an annual budget of $1,355,000.
All members will sign the same Membership Agreement (see Section I.3) and willbe equally represented on the Industrial Advisory Board. Members will participate instrategic decisions of the Center including the selection and evaluation of researchprojects. All members will have non-exclusive rights to the entire I/UCRC-MTP researchportfolio. In addition, each I/UCRC-MTP industrial member will have an opportunity toactively participate in I/UCRC-MTP research and education programs.
Most significantly, members will also have an opportunity to propose case studyproblems and/or specific research problems and topics. The case study problems will beused to train I/UCRC-MTP students on the use of current computational technologies.Postdoctoral students will develop simulations and/or experimental results in support ofthe case studies. These results will provide a baseline for identifying the need for newdevelopments and precompetitive research. Section C.6 of this proposal summarizes theresults of a recent NSF curriculum development project on multiphase transportphenomena based on industrial case study examples. The new Center will adopt thisparadigm to train new students on the use of commercial computational multiphasetransport phenomena codes.
Technology transfer between the faculty/student research teams and industrialmembers will be promoted by the following infrastructure: 1) pre-doctoral and post-doctoral industrial internships; 2) the direct involvement of the industrial advisor on theresearch team; 3) the use of commercially available software to disseminate high impactresults; 4) web based submission of quarterly and annual reports; and, 5) biannualresearch retreats on different campuses.
In summary, I/UCRC-MTP members will receive multiple benefits including• Participation in the strategic planning of I/UCRC-MTP.
• Opportunity to propose specific research and/or training problems.
• Selection of precompetitive research projects.
• A 24:1 leverage of annual membership fees ($30,000) in the first year for a 15-member Center.
• A 45:1 leverage of annual membership fees ($30,000) in Years 2-5 with a 30-member Center.
• Non-exclusive rights to the entire I/UCRC-MTP research portfolio.
• Sponsorship of postdoctoral research associates and/or graduate students as industrial interns.
• Technology transfer assurance as described above.
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
- C.7 -
C.3 Organizational Structure
Center Director, Co-Director, and Site Directors
The Director of the Center will be responsible for all Center activities and willreport directly to the Dean of Engineering at MSU as well as to the NSF ProgramManager and the Industrial Advisory Board. The Co-Director will be responsible for theresearch portfolio of the Center. The Director and Co-Director will work with the SiteDirectors and the Industrial Advisory Board on strategic planning related to the Centerand on recruiting new members. The Site Directors will be responsible for activities atthe individual universities.
Industrial Advisory Board
Although individual members join I/UCRC-MTP through one of the three affiliateduniversities, there is only one industrial advisory board (IAB) for the Center. Members ofIAB will 1) assist the faculty in identifying precompetitive generic research topics inmultiphase transport phenomena, 2) recommend research projects for funding, 3) assist inidentifying appropriate industrial internship opportunities for graduate students andpostdoctoral students, 4) assist the Center Director and Co-Director in identifying newI/UCRC-MTP members, 5) review the research and educational accomplishments of theCenter.
The Industrial Advisory Board will meet twice a year to review research results andto discuss the strategic plans for the Center. These meeting will occur at the participatinguniversities on a rotating basis. The IAB review meetings will coincide with the biannualI/UCRC-MTP research retreats.
External Evaluator
A Center Evaluator will work with the faculty and the Industrial Advisory Board toassess recruitment and retention strategies, training goals, and the compatibility ofmultidisciplinary cooperative research goals and Ph.D. dissertation goals. An assessmentprocedure will determine (1) whether the objectives are realized as program outcomes;(2) whether the objectives are appropriate; and, (3) how the program may be improved.The following performance measures will be employed: 1) membership satisfaction; 2)number of peer-reviewed journal publications, conference proceedings, andpresentations; 3) retention of Ph.D. students; 4) enrollment and impact of I/UCRC-MTPworkshops on students; and, 5) outcomes and utility of industrial case study problems inproviding focus for research.
University Policy Committee
The Associate Dean of Research and Graduate Studies in the College ofEngineering at MSU and the Dean of the Graduate School at MSU will form a multi-
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
- C.8 -
university administrative oversight committee to provide an annual review of academicstandards, recruitment strategies, retention issues, and funding issues related to theCenter. The Center Director and the Center Co-Director will serve on this committee.
Academic Advisory Committee
The Director of the Center will appoint faculty to serve on a multiuniversityAcademic Advisory Committee that will 1) set standards for student participation, 2)monitor student progress towards a degree, 3) set goals for recruiting students (especiallyminority and women), 4) promote the multidisciplinary nature of the research program,and 5) help students in organizing industrial internships. The five members of the FacultyLeadership Team will all serve on the Academic Advisory Committee.
C.4 Management Plan
Faculty Leadership Team
The center leadership team includes André Bénard, Charles Petty, and Tom Shih atMichigan State University, George Chase at The University of Akron, and Ram Mohan atThe University of Tulsa. This group has been collaborating together for more than threeyears on projects related to multiphase transport phenomena (see Section C.6). They havecollaborated with one another during the planning phase of forming the Center, whichincluded two industry/academic workshops at Michigan State University on September
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
- C.9 -
10, 2002 and February 19, 2003. A summary of each workshop is presented in SectionI.2. The leadership team is committed to the formation and the successful operation ofI/UCRC-MTP. A brief biographical sketch of each leader is given in Section E. Theleaders have made the following commitments to manage I/UCRC-MTP.
André Bénard, Associate Professor of Mechanical Engineering at Michigan StateUniversity, will serve as Co-Director of the Center and Group Leader of the I/UCRC-MTP focus area on multiphase fluids. As Center Co-Director, Professor Bénard will haveoversight responsibilities related to Center research at all three universities and willcoordinate research project assignments in cooperation with the Center Director, theResearch Foci Leaders, and the Industrial Advisory Board.
George Chase, Professor of Chemical Engineering and former Director of theMicroscale Physicochemical Engineering Center at The University of Akron, will serveas the Akron Site Director and the Group Leader for the I/UCRC-MTP focus area onmultiphase phenomena in porous media. Professor Chase will be responsible for 1)organizing and coordinating the I/UCRC-MTP biannual meetings with the other SiteDirectors, 2) recruiting new members to join the Center through Akron, 3) providingliaison between I/UCRC-MTP and the members that join the Center through Akron, and4) working with the academic departments and faculty to recruit graduate students forI/UCRC-MTP at Akron. As the NSF Principal Investigator at Akron, Professor Chasewill also be responsible for all center-related activities at Akron and will report to theDirector of the Center at MSU, to the Dean of the College of Engineering at Akron, andto the National Science Foundation.
Ram Mohan, Associate Professor of Mechanical Engineering and AssociateDirector of Tulsa University Separation Technology Projects, will serve as the Tulsa SiteDirector and Group Leader for the I/UCRC-MTP focus area on multiphase separations.Professor Mohan will be responsible for 1) organizing and coordinating the I/UCRC-MTP biannual meetings with the other Site Directors, 2) recruiting new members to jointhe Center through Tulsa, 3) providing liaison between I/UCRC-MTP and the membersthat join the Center through Tulsa, and 4) working with the academic departments andfaculty to recruit graduate students for I/UCRC-MTP at Tulsa. As the NSF PrincipalInvestigator at Tulsa, Professor Mohan will also be responsible for all center-relatedactivities at Tulsa and will report to the Director of the Center at MSU, to the Dean of theCollege of Engineering at Tulsa, and to the National Science Foundation.
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
- C.10 -
Charles Petty, Professor of Chemical Engineering and Director of the MultiphaseFlow Facility (MFF) at Michigan State University, will serve as the Center Director andas the Group Leader for the I/UCRC-MTP focus area on multiphase turbulence. AsCenter Director, Professor Petty will be responsible for all Center activities and willprovide liaison between the Center and the College of Engineering at MSU, the NationalScience Foundation, the Industrial Advisory Board, and the three Site Directors. Incooperation with the three Site Directors and the Center Co-Director, Professor Petty willbe responsible for ongoing industrial relations and recruitment of new Center Members.
Tom Shih, Professor of Mechanical Engineering and Director of the MultiphysicsComputational Research Laboratory (MCRL) at Michigan State University, will serve asthe MSU Site Director and Group Leader for the I/UCRC-MTP focus area on multiphasemixing and reactions. Professor Shih will be responsible for 1) organizing andcoordinating the I/UCRC-MTP biannual meetings with the other Site Directors, 2)recruiting new members to join the Center through MSU, 3) providing liaison betweenI/UCRC-MTP and the members that join the Center through MSU, and 4) working withthe academic departments and faculty to recruit graduate students for I/UCRC-MTP atMSU.
Administrative Support Staff
The Multiphase Flow Facility (MFF) in Chemical Engineering and theMultiphysics Computational Research Laboratory (MCRL) in Mechanical Engineeringwill provide administrative space for Center operations. A part time PostdoctoralAssociate and/or an Administrative Assistant will facilitate the daily technicalmanagement and technology transfer functions associated with the MSU Site. Anaccountant in the College of Engineering will provide liaison between the Center and theContract and Grant Administration Office at MSU.
The Microscale Physicochemical Engineering Center will provide a focal point forI/UCRC-MTP activities at Akron. A part time Postdoctoral Associate and/or anAdministrative Assistant will facilitate the daily technical management and technologytransfer functions associated with the Akron Site. An accountant in the College ofEngineering will provide liaison between the Center and the Contract and GrantAdministration Office at Akron.
University Separation Technology Projects will provide a focal point for I/UCRC-MTP activities at Tulsa. A part time Postdoctoral Associate and/or an AdministrativeAssistant will facilitate the daily technical management and technology transfer functionsassociated with the Tulsa Site. An accountant in the College of Engineering will provideliaison between the Center and the Contract and Grant Administrative Office at Tulsa.
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Technology Transfer
Technology transfer between the faculty/student research teams and industrialmembers will be promoted by the following infrastructure: 1) pre-doctoral and post-doctoral industrial internships; 2) the direct involvement of the industrial advisor on theresearch team; 3) the use of commercially available software to disseminate high impactresults; 4) web based submission of quarterly and annual reports; and, 5) biannualresearch retreats on different campuses.
Student Recruitment and Plan for Diversity
The IUCRC-MTP recruiting plan will be coordinated with individual academicdepartments. I/UCRC-MTP faculty participants will recruit graduate students through theregular departmental recruiting structure. The academic departments will administerstudent and faculty appointments in I/UCRC-MTP. The two academic co-advisors on thestudents research committee will serve as liaison between the Center and theDepartmental Graduate Committees.
Michigan State University has several innovative and tested programs to recruit andretain underrepresented students. Professor Percy Pierre at MSU, who is nationallyrecognized for his programs on recruiting, mentoring, and retaining minority and womengraduate students in engineering, has agreed to assist the faculty in attracting minoritydoctoral students to the I/UCRC-MTP program. These students will participate in theretention activities associated with the MSU/Sloan Engineering Program. New studentswill attend a specially designed orientation program for doctoral students as well asparticipate in weekly meetings with other minority students. Similar programs at Akronand Tulsa will be coordinated with the MSU program.
The three NSF Principal Investigators (Chase, Mohan, and Petty) will submitannual supplemental proposals to NSF and other appropriate organizations to enhance theparticipation of minority students and women in the Center.
Graduate Student Training
Each MTP graduate student will have two academic mentors and, if available, oneindustrial mentor. The two faculty mentors are responsible for advising the student onuniversity and departmental policies. During the first year in the program, an I/UCRC-MTP graduate student will participate in a CFD design group with a focus on anindustrial challenge problem as well as complete an Internet course on multiphasetransport phenomena (see Section C.6 below). In the second year, the student willcomplete an industrial internship. All I/UCRC-MTP graduate students will write a Masterof Science thesis and/or a Ph.D. dissertation.
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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C.5 Financial Plan
The major source of funds for the Center will be membership fees ($30,000 peryear per member) from industry and other organizations The Universities will provide acost share equal to 25% of the membership fee and the National Science Foundation willprovide a grant to each University to partially fund the operation of the Center. Memberswill join the Center through one of the affiliated universities. I/UCRC-MTP will becomefully operational once each University has received a commitment from five or moreorganizations. The sources of funds for the first year are as follows: 1) membership feesfrom fifteen Members for a total of $450,000; 2) university cost share at $112,500; and3) a National Science Foundation grant of $170,000. Tables in Section F illustrate howCenter funds will be used to support Center research and operations in the first year aswell as in Years 2-5.
An I/UCRC-MTP research project will usually require two or more industrialsponsors to participate fully in Center activities. Therefore, multiple membership feeswill be used to support an individual project (∼ $47,000 per project). A proposedprocedure for selecting individual projects is briefly described in Section C.7 below.
During the first year of operation, twelve full-time (20 hours per week) graduatestudents and three part-time (20%) postdoctoral associates will be funded by the Center.The Center intends to recruit additional sponsors (federal government, state government,foundations, and other companies) to increase the membership fees to $900,000 (seeSection F for five-year budget). With this level of support, the center would have anannual budget of $1,355,000 and would partially fund the research of twenty-fourgraduate students in the area of multiphase transport phenomena.
C.6 Previous NSF Support Closely Related to this Proposal
NSF/ECC-9980325: November 1999-March 2003, Combined Research and CurriculumDevelopment on Multiphase Transport PhenomenaPrincipal Investigator:Charles A. PettyNSF Program Manager:Mary F. PoatsUniversity Participants:Michigan State University, The University of Akron, and The University of TulsaFaculty Participants:M. J. Amey (College of Education, MSU), A. Bénard (ME, MSU), G. G. Chase (ChE, Akron), E. A. Evans(ChE, Akron), K. Jayaraman (ChE, MSU), R. S. Mohan (ME, Tulsa), S. M. Parks (ChE, MSU), C. A. Petty(ChE, MSU), O. Shoham (PE, Tulsa), S. A. Shirazi (ME, Tulsa), K. D. Wisecarver (ChE, Tulsa), M.Zhuang (ME, Tulsa)Undergraduate Student Participants:Katharine Baker (ChE, MSU), Christina Berger (ChE, MSU), Dina Eldein (ChE, MSU), Floyd. Hammond(PE, Tulsa), Troy Hendricks (ChE, MSU), Nick Lynn (ME, MSU), Steve Leibrandt (ME, MSU), Luwi
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Michigan State UniversityThe University of Akron, The University of Tulsa
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Oluwole (ChE, MSU), Carl Rose (ChE, MSU), S. Jose Severino (PE, Tulsa), Stephanie Teich-McGoldrick(ChE, MSU), Chad Trainer (PE, Tulsa), Sara Vermillion (ChE, Akron), William Wehbe (ME, MSU), AndyYoder (Che, MSU),Graduate Student Participants:Luis Gomez (PE, Tulsa), YoChan Kim (ChE, MSU), Figen Lacin (ME, MSU), Hongmin Li (ME, Akron),Dilip Mandal (ME, MSU), Brian Raber (ChE, Akron)Industrial Participants:AEA Technology Engineering Software Inc., Bechtel Technology and Consulting, ChevronTexaco, TheDow Chemical Company, DuPont Central Research & Development, Eastman Chemical Company,ExxonMobile Production Company, Fluent Incorporated, Krebs Engineers, Pharmacia, The Procter &Gamble Company, and The Trane Company.
Summary of CRCD-MTP
This curriculum development project on multiphase transport phenomenacombined the research experiences of nine research laboratories at The University ofAkron, Michigan State University, and the University of Tulsa. The objective of theproject was to develop a new curriculum for teaching students multiphase computationalfluid dynamics for advanced design. The CRCD-MTP teaching paradigm will be adoptedby I/UCRC-MTP as a means to rapidly introduce students to research in the area ofmultiphase transport phenomena.
The impact of multiphase flow research on solving practical engineering problemsis an integral part of the CRCD-MTP learning experience. Industrial participants in theproject provide specific design problems related to emerging or traditional technologies.Students are taught the fundamentals of computational fluid dynamics (CFD) during aone-week workshop. This is followed by an Internet course on multiphase transportphenomena. The students work in teams on CFD design problems with a faculty andindustrial mentor. The salient results of this NSF/CRCD project were recently presentedas part of the NSF Showcase at the 2002 ASEE Annual Conference & Exposition inMontreal, Canada (June 16-19) and at ICEE-2002, the International Conference onEngineering Education in Manchester, UK (August 18-22).
Need for a Multiphase Transport Phenomena Curriculum
Multiphase transport phenomena research is of industrial and national importance.Advances in oil and gas production, composite material processing, bioremediation ofsoils, plastic recycling, modern biotechnology reactors and separators, high-performancefiltration devices, nuclear fuel reprocessing, and efficient automotive fuel utilizationrepresent a few disparate engineering problems that rely on a basic fundamentalunderstanding of multiphase transport phenomena.
This curriculum development focused on the need to bridge an educational gapbetween undergraduate training in transport phenomena of single-phase fluids asexemplified by Bird et al. (2002) and transport phenomena of multiphase fluids (see, forexample, Gidaspow, 1994; Drew and Passman, 1999; and Kolev, 2002). Moreover, a
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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significant gap is developing on the use of conventional transport phenomena principlesand computational fluid dynamic tools in the area of single-phase and multiphaseturbulent flows (Crow et al., 1996; Pope, 2000). CFD has opened the possibilities ofanalyzing in the classroom flows in complex geometries unimagined ten to twenty yearsago. However, students (and faculty) need further training to effectively use modern CFDcodes and to understand how CFD results can be used as an innovative process designand diagnostic tool.
Goals of CRCD-MTP
The overall goal of the NSF CRCD-MTP project was to develop and implement amultiphase transport phenomena course across professional disciplines. The structure ofthe curriculum addresses the following eight educational needs for advancedundergraduate students, beginning graduate students, and industrial postgraduatestudents: 1) training in fundamentals of multiphase transport phenomena; 2) training inthe development of multiphase model formulation, interpretation, and experimentalvalidation; 3) training in the fundamentals of numerical methods that support currentstate-of-the-art commercial CFD codes; 4) training in the implementation of CFD codes;5) training in the use of CFD codes for non-turbulent flows of single phase fluids; 6)training in the use of CFD codes for turbulent flows of single phase fluids; 7) training inthe application of multiphase CFD codes; and, 8) training in the integration of CFD toolsinto the design process.
Organization of the CRCD-MTP Training Program
CRCD-MTP CFD Bootcamp The CFD bootcamp was conducted at MSU for aweek in August 2000, June 2001, and June 2002. Approximately twenty undergraduateand graduate students participated each year. The students reviewed key ideas associatedwith single-phase transport phenomena, conducted practical hands-on experimentsrelated to single phase and multiphase materials and learned to use a commercial CFDcode (i.e., CFX during the first year; Fluent during the second and third years).
Each student was a member of a CFD design team. Each team met with anindustrial mentor to discuss a CFD case study of interest to the industrial participant (seeTable C.3 above). The teams completed a case study design during the summer andpresented the results of their work at professional meetings.
Internet Course on Multiphase Transport Phenomena An Internet coursecomplements the CFD design experience by offering the following topical lectures:Intraphase and Interphase Transport Phenomena; Transport Phenomena in MultiphaseFluids; Computational Fluid Dynamics; Gas/Liquid, Solid/Liquid, and Liquid/LiquidFlows; Transport Phenomena in Porous Media; and, CFD Case Study Examples. Apreview of the CRCD-MTP program is located at www.vu.msu.edu/preview/eng-mtp.
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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Computational Fluid Dynamics Case Studies CRCD-MTP student teamscompleted six industrial CFD case studies. Table C.3 below identifies the titles of theprojects and the participants.
Table C.3 CFD Design Projects and ParticipantsTeam A: Numerical Simulation of a Solid/Fluid Suspension in an Enclosed TankTeam B: Numerical Simulation of Flow within a HVAC HeaderTeam C: Numerical Simulation of a Bubble ColumnTeam D: CFD Study of Water/Oil Dispersions in a Distribution ManifoldTeam E: Influence of Cone Angle and Capacity on Hydrocyclone SeparatorsTeam F: CFD Simulation of a Pulsed-Jet Mixer
Team CompanyHost University
IndustrialAdvisor
AcademicAdvisor
GraduateStudent Mentor
UndergraduateStudent
A PharmaciaMSU Mark Widman Steve Parks
Charles Petty YoChan KimC. BergerC. Rose
A. Yoder
BThe TraneCompany
MSURay Rite André Bénard
Mei ZhuangFigan Lacin
Dilip MandalD. El-deinN. Lynn
C Eastman ChemicalAkron Kevin Fontenot George Chase
Edward EvansBrian RaberHongmin Li
K. BakerT. HendricksS. Vermillion
D Chevron-TexacoTulsa Gene Kouba Ram Mohan
Ovadia Shoham Luis GomezF. HammondS. LeibrandtJ. Severino
E Krebs EngineersMSU Tim Olson Steven Parks
Charles PettyL. OluwoleW. Wehbe
F BechtelMSU
BrigetteRosendall
Charles PettySteve Parks
D. EldeinS. T-McGoldrick
C. Trainer
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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C.7 Research Plan
Background and Premise
Multiphase fluids occur ubiquitously in engineering applications and involvedispersed two-phase flows such as fiber suspensions, emulsions, and foams. Modelingand simulating these systems challenge current physical understanding and currentcomputational resources. Indeed, multiphase flows are often unstable and involve large-scale secondary motions, and buoyancy effects. Secondary flows can significantlyinfluence multiphase mixing, multiphase separation, interfacial mass and heat transfer,and multiphase reactions. Unfortunately, current multiphase models for mass, energy, andmomentum transport often invoke ad hoc (and untested) assumptions that misrepresentthe influence of important physical phenomena on space-time scales encountered in MTPproblems. This situation significantly limits the use of advanced computational methodsfor innovative engineering design and research.
Significant gains are anticipated by sharing knowledge and methodologies in thismultidisciplinary Center, which will examine automotive and transportation inspiredapplications along side chemical and petrochemical inspired applications. For example, inorder to bridge nanoscale, microscale, mesoscale, and macroscale phenomena, currentMTP models use ensemble, volume, and/or time averaging techniques that require anidentification of specific space-time scales that control chemical kinetics, interfacialtransport processes, and turbulent mixing. These models are often discipline specific,even though they share common features.
Bénard (1996) and Bénard and Diaz (1998) have noted that the effort required tosimulate the flow within a complex domain can be so significant that it may take lesstime to study the key ideas experimentally. However, given the potential benefits ofsimulations in engineering design and optimization, the foregoing situation suggests thatthere is a need for a comprehensive re-evaluation of the modeling process, especially inthe area of computational multiphase transport phenomena (CMTP). This has justbecome possible through recent complementary developments in transport models andmesh generation techniques as well as advances in computer technology.
Clearly, additional research and training are needed for CMTP technology tobecome a widespread engineering design tool. I/UCRC-MTP research will address bothof these needs by improving the accuracy of the physical models currently available, andby improving the numerical methods used for simulations. Therefore, the Center willaddress precompetitive problems related to the further development of
• next generation multiphase transport models and their experimental validation,and
• novel computational methods for rapid analysis of multiphase processes
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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Research Foci
I/UCRC-MTP research projects will examine problems related to the following fivefocus areas: 1) multiphase fluids, 2) multiphase phenomena in porous media, 3)multiphase mixing and reactions, 4) multiphase separations, and 5) multiphaseturbulence. Research during the formative stages of the center will address theoreticaland computational barrier problems with a strong emphasis on transport phenomena influid/fluid and solid/fluid systems. Precompetitive research topics were identified bycompany representatives at the I/UCRC-MTP planning meetings on September 10,2002and on February 19-20, 2003 (see Section I.2 for a summary of the planning meetings).
Identification and Selection of Research Projects -- Member Participation
Although individual members join the Center through one of the three affiliateduniversities, there is only one industrial advisory board (IAB). All members willparticipate in the selection and evaluation of research projects. Most significantly, IABmembers will also have an opportunity to propose specific problem-oriented researchtopics and precompetitive research areas of interest.
During the first few months of operation, a portfolio of relevant research topics willbe compiled based on the interest of IAB members and the five focus groups. Theseresearch topics will be posted on the Center web site and will form the basis forcollaborative projects. Each focus group will develop a set of proposals consistent withthe goals of their group (see below), the interest of members, and the mission of theCenter. IAB members will review the faculty research proposals prior to the I/UCRC-MTP research meeting. At the meeting, faculty/student teams will discuss their proposalswith IAB members.
All I/UCRC-MTP research projects will be developed by students and supervisedby faculty. Each project will require two or more industrial sponsors. Members of IABwill develop bylaws that will identify procedures for selecting projects. Members willhave an opportunity to fund one or more projects at different universities or at the sameuniversity. Problem-oriented research projects are often broad enough in scope thatcomplementary expertise and knowledge from all three universities will be needed toaddress relevant research issues. Significant resources for research are available toI/UCRC-MTP members in terms of faculty (see Section E) and state-of-the-art researchtechnologies (see Section H).
An example research problem from each of the research focus areas is describedbelow. This description stems, in part, from discussions with potential I/UCRC-MTPmembers that attended planning meetings either on September 10,2002 or February 19,2003. Section I.2 summarizes the results of these earlier planning meetings.
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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C.7.1. Focus Area 1: Multiphase FluidsAndré Bénard, Group Leader
Faculty Resources:A. Bénard (MSU), G. Chase (Akron), E. Evans (Akron), K. Jayaraman (MSU),C. Lira (MSU), J. Lloyd (MSU), A. Lee (MSU), M. Mackay (MSU),C. Petty (MSU), D. Reneker (Akron), and G.Young (Akron)
The Multiphase Fluids Group will develop improved theoretical models andcomputational methods for predicting the microstructure of complex fluids in confinedflows and free jets. The results will support the development and use of advancedmaterials reinforced, for example, by nanoscale fibers and particles (clays). The goal ofthis group is to develop computational tools capable of evaluating innovative strategiesfor manufacturing multiphase composite materials.
Example Project: Die Design for Multiphase FluidsBackground
Manufacturing processes involving multiphase materials such as suspensions,immiscible polymers, or liquid crystalline polymers often result in parts withmicrostructures that are strongly coupled with the processing flow fields. Consequently,controlling the microstructure of the final composite can be achieved indirectly by flowcontrol. One possible approach is to extrude the multiphase fluid through a speciallydesigned die (see for example Goettler. and Lambright, 1977a, 1977b; Doshi, 1986). Thedesign procedure however is often tedious and time consuming since numerous dies mustoften be designed before the desired microstructure is obtained. The goal of this project isto develop a computational approach that can identify promising die designs for testing.
Predicting the orientation of the microstructure for complex fluids however is still asignificant challenge for engineers and scientists. While some successes have beenreported in the literature, especially for fiber suspensions, there is still a need forimproved models applied in complex flows. Tucker and Huynh (2001) very recentlyreported on the need for improving the accuracy of predictions in molds with short flow-lengths (i.e. thickness/length < 50). Although the origin of the discrepancies betweenpredictions and observations is not easy to pinpoint, the source of the problem could bethe closure model for the orientation tetradic, or the constitutive equation expressing thecoupling between the flow field and the microstructure.
The ability to predict changes in the microstructure of complex fluids duringprocessing will have an important impact on next generation processing strategies forpolymer and polymer-matrix composites. Such an approach may yield new fundamentalresults on the influence of complex flow patterns on the microstructure of liquidcrystalline polymers and other complex fluids.
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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A. Benard and C. Petty have been involved with the problem of flow-inducedalignment of particles for nearly five years. The explicit representation used in the closuremodel developed at MSU complements the implicit closure models of Cintra and Tucker(1995) and Dupret et al. (1997). A few articles and patents have been published on semi-empirical design of extrusion dies (Goettler. and Lambright, 1977a, 1977b; Doshi, 1986),as well as processing methods to induce orientation of the microstructure (e.g. Baird andSukhadia, 1993; Handlos and Baird, 1995), none however involved numerical studies.
Predicting the response of suspensions to various flow fields encountered duringprocessing is often based on a moment equation of the average orientation dyadic. Aclosure model that relates the fourth order orientation tensor to the second orderorientation tensor was recently developed at MSU (Petty et al., 1999). This new algebraicclosure model retains all six contraction and symmetry properties of the exact fourthorder tensor. This new closure model allows understanding of the complex phenomenaassociated with the processing of short-fiber composites and the behavior of complexfluids such as liquid crystalline polymers.
This research aims to combine recent developments in numerical methods with newpredictive models for the microstructure of complex fluids in order to simulate extrusionprocesses in a novel way. The computational costs associated with such simulations canbe enormous due to the prohibitively large number of unknowns. Recent availability ofinexpensive parallel computers, large memories and fast chips however make thisproblem tractable.
Questions regarding the prediction and control of the microstructure of productsmade from multiphase materials are numerous (Guell and Papathanasiou, 1997). Specificproblem areas include:
• The formulation of realizable closure models to predict the behavior ofsuspensions or immiscible polymer blends during processing;
• Understanding the flow behavior of complex fluids during processing and theinstabilities associated with a processing methodology; and,
• Validation of multiphase averaging theories through detailed simulations andexperimental measurements at the microscale level.
Proposed Research
The MSU group has already developed and validated a closure model for the fourthorder orientation tensor. A two-dimensional finite element code that implements the newtheory for flow-induced alignment of particles is already available. With this software,the influence of geometrical on changes in the fluid microstructure (suspensions, liquidcrystalline polymers, bubbles, etc) can be ascertained. The software however must bedeveloped further to study flows in axisymmetric geometries and complex three-dimensional domains, which are important for industrial applications. Therefore, duringthe initial stages of this project, a finite element code will be developed to predict three-
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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dimensional flow-induced orientation of a dispersed phase in complex geometries with anemphasis on the relationship between die geometry and the resulting microstructure forextruded profiles.
Research Methods
The finite element model will use the fictitious domain method to reduce themeshing requirements and reduce the design cycle time. Such methods use a regular grid,thus obviating the need for a boundary matching mesh, and the boundary conditions onthe surfaces are preserved by converting the surface integral into volume integrals usingmeasure theory concepts. Although the formulation of a successful fictitious domainapproximation is challenging, the strategy should nevertheless succeed for extrusionapplications inasmuch as successful fictitious domain strategies have already beendeveloped for a class of problems in heat conduction, elasticity, and flow (see, esp.,Astrakhantsev,1978; Diaz and DeRose, 1998; and Bertrand et al., 1997, Li and Bénard,2003). Particularly relevant to this work are the results presented by Glowinski andcolleagues (Glowinski et al., 1998, 1993).
Novelty of the Proposed Research, Anticipated Results, and Benefits
No systemic studies of using the die geometry to control flow and microstructurehave been presented in the literature. Such studies may yield novel geometrical designsthat will favor the orientation of the particles for a given application as discussed inGoettler and Lambright (1977a, 1977b), Doshi (1986), Baird and Sukhadia (1993) andHandlos and Baird (1995). Guidelines on the design of dies may also evolve from thiswork.
The fabrication of multiphase materials such as composites or alloys is a difficultproblem that involves complex transport phenomena. Significant advances have beenmade in manufacturing these materials, but there is still a need to understand relevanttransport phenomena during the processing stage (Advani, 1994; Wang, 1997). Importantproblems that affect the microstructure evolution of multiphase materials duringprocessing will be studied.
The materials considered will be polymer blends, polymer composites and metalalloys. Such materials, despite their differences, still follow the same fundamentalgoverning principles for mass, heat and momentum transfer. One must, however, stilldevelop specific closure models and determine the relative importance of variousphenomena to accurately describe the processing of such materials and predict theresulting microstructure.
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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C.7.2. Focus Area 2: Multiphase Transport Phenomena in Porous MediaGeorge Chase, Group Leader
Faculty Resources:A. Bénard (MSU), G. Chase (Akron), S. Hariharan (Akron),K. Jayaraman (MSU), C. Lira (MSU), D. Raneker (Akron), C. Petty (MSU),T. Shih (MSU), L. Thompson (Tulsa), and G. Young (Akron)
The Porous Media Group aims to develop improved models and computationalmethods for quantifying multiphase flows and heat transfer through natural and syntheticporous media. The results will support the further development of high efficiency filtersfor diesel exhaust, soot removal from engine oils, gas phase coalescers, oil/waterseparators, and oil & gas reservoir simulations. In addition, the improved computationaltools will be used to evaluate natural convection heat transfer processes within fuel cellsand around partially buried pipelines on the ocean floor.
Example Project: Models for Coalescence Filter MediaBackground
Filter media are widely employed in the chemical, petrochemical, andtransportation industries to separate a dispersed phase from a continuous fluid phase.Important applications include soot removal from engine oils, air cleaners, demisters, andliquid/liquid separators. The performance of coalescence filters is directly linked to theability of the medium to promote drop coalescence and subsequently drain the liquidphase (Moazed 2002; Mathavan 1992). While droplet coalescence and drainage areconceptually simple phenomena, they are difficult to predict due to complex interfacialphysicochemical phenomena such as capillary forces, interfacial chemistry (wetting,surfactants), and the local filter microstructure.
A major challenge in understanding the performance of coalescence filtertechnology relates to unsteady-state behavior during shutdown and startup. Mostcoalescence models available in the literature assume steady-state conditions and auniform saturation of the drop phase across the medium. Current approaches also assumeaverage properties across the medium. The following four stages characterize thecoalescence process from onset to steady state.
1) The initial startup stage where the filter medium is empty of drops and the localsaturation is near zero.
2) The loading stage where the local saturation increases sufficiently to cause ameasurable change in the local void space for the continuous phase yet lowenough to prevent the captured droplets from migrating.
3) The unsteady coalescence stage where the captured droplets locally migratethrough the filter.
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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4) A steady coalescence stage where the droplet coalescence and migration resultin a constant outlet stream.
An analysis of the four transient stages requires a means to predict the space-timevariation of the local saturation within the coalescing filter. Predicting the local spatialvariation of saturation requires a model for droplet capture, coalescence, and drainage.Sherony et al., (1978) describe a capillary conduction model and a collision model formigration of droplets through fibrous media. The models result in a continuum scalecorrelation for predicting drop motion. Reynor and David (1999) developed continuumand macroscopic models that account for evaporation. Mesoscale or sub-scale models areneeded to link microscopic phenomena to the local characteristics of the filter media suchas fiber orientation, fiber size, and fiber spacing.
Proposed Research
Professor Reneker and his colleagues at The University of Akron have developed anew class of nanoscale and microscale organic fibers and fiber coatings. One objective ofthis research is to explore the efficacy of using coated fibers as a coalescence medium forhigh-temperature and low-pressure drop applications. The specific goal of this project isto develop a validated computational model for the transient stage of a coalescence filter.The theory and computational methodology will be applicable to a wide class of filtermedia.
The overall coalescence efficiency of the fiber bed will be evaluated. The effects offlow rates and depths of fiber bed on coalescence efficiency will also be studied. Thepurpose of this research will also be to evaluate the applicability of the well-knownCarman-Kozeny filtration equation and the Sherony-Kintner coalescence model on filterbeds of various scales (from micro-size fibers down to nanoscale fibers) and to improveon these models with the development of mesoscale (or sub-scales) models that accountfor various microscopic phenomena.
Research Methods
The model system considered at first will be air loaded with oil droplets. A modelaccounting for the local fiber orientation, drag of drops on fibers, wetability of the dropson the fibers, drag of fluid on the drops, gravity, and drop size has been already beendeveloped for the startup stage and has been solved analytically. A numerical model hasbeen developed for the loading stage. The remaining two stages will requiredevelopment of appropriate constitutive sub-scale models to model the capture,coalescence, and migration of drops in 2D or 3D flows. The Sherony and Kintnercoalescence model will be modified to include these phenomena.
Layered filters will be used in experiments so that the media can be separated andthe saturation of the layers can individually be measured. The measured saturationprofiles will be compared with the model results.
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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Novelty of the Proposed Research, Anticipated Results, and Benefits
The proposed research involves very detailed modeling of the physical processesencountered in coalescence filters. No such detailed modeling has been used yet toaccount for the transient phenomena occurring in coalescence filters. Research at Akronis the first of its kind to predict the startup performance of coalescing filters (the startupand loading stages). Experiments will verify the model predictions of the saturationspatial variation.
C.7.3. Focus Area 3: Multiphase Mixing and ReactionsTom I-P Shih, Group Leader
Faculty Resources:A. Bénard (MSU), G. Chase (Akron), F. Jaberi (MSU), E. Evans (Akron),K. Jayaraman (MSU), C. Lira (MSU), N. Mueller (MSU), B. McLaury (Tulsa),R. Mohan (Tulsa), C. Petty (MSU), R. Ramsier (Akron), T. Shih (MSU),H. Schock (MSU), Z. Wang (MSU), I. Wichman (MSU), K. Wisecarver (Tulsa),R. Worden (MSU), G. Young (Akron), and M. Zhuang (MSU)
The Multiphase Mixing and Reactions Group will develop improvedcomputational methods for tracking the motion of an interface between two immisciblephases. The results will support the analysis of multiphase processes such as liquid jetbreakup, environmental mixing of oil and water, coalescence of liquid droplets on fibers,the stability of liquid/gas interfaces encountered in liquid molding, fuel sprays, interfacialreactions, crystallization, hydrate and wax formation in oil-gas-water pipelines, and fluid-fluid separators.
Example Project: Simulation of Interfacial Motion with a Level-Set MethodOn Adaptive Cartesian Grids
Background
Physical phenomena involving the motion of interfaces separating two or morephases are abundant in industry and nature. One may, for example, be interested insimulating very large problems such as the flow of oil out of a broken pipeline or simplystudy the rise of a single buoyant bubble. To tackle such problems, various numericaltechniques have been proposed to track the interface separating two or more phases (seefor example Harlow and Welch, 1965; Unverdi and Tryggvason, 1992; Esmaeeli et al.,1996, and Torres and Brackbill, 2000). The so-called level-set method (Osher, et al.,1988) is a relatively recent technique designed to capture the interface motion by solvingthe evolution equation of a signed distance function.
The level-set method was shown to be very promising for tracking the interfacesbetween two or three different incompressible fluids (Sussman, et al., 1994). A keyadvantage of the method is the ease with which it can handle complex topologicalchanges of the interface. The method however in its current use has the drawback of
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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exhibiting unphysical loss of mass for coarse grids. Although this problem may bepartially alleviated by modifying slightly, at each time step, the interface location untilmass is globally conserved, such a procedure is expensive computationally and still doesnot ensure local mass conservation. To mitigate this problem, it is proposed to use anadaptive Cartesian grid method that will refine the mesh near the interface location. Thistechnique has been used at MSU (Wang, et al., 2002) for the simulation of turbulent flowproblems and for flows in complex geometries.
Proposed Research
This project aims to further develop the level-set method for multi-scale interfacialproblems through the use of unstructured anisotropic adaptive Cartesian grids. Theresearch will focus on developing efficient, robust and scalar algorithms to handle free-surface flow problems with disparate space and time scales, such as those occurring inoil-water separation problem, and liquid jet breaking and merging.
The following three tasks will be addressed in this project: 1) The development ofa multi-scale anisotropic grid generator and adaptor that responds to the location andcurvature of the interface; 2) The development of a parallel level-set flow solversupporting the anisotropic adaptive Cartesian grids, and various data structures includingtree-based and list-based data structures; 3) Validate the efficacy of the grid adaptor andflow solver by simulating a free-surface problems involving disparate length and timescales.
Research Methods
The level set method can already handle complex interfacial topological changeswithout any special treatment. The main contribution of the present project is to furtherdevelop this method on unstructured adaptive Cartesian grids. Interface and solutionbased grid adaptations will be developed to dramatically improve the accuracy andefficiency of the level-set method for diverse time and length scales. This computationaltool will be verified and demonstrated for oil-water separation problems.
Novelty of the Proposed Research, Anticipated Results and Benefits
•••• The extension of the level-set method to anisotropic adaptive Cartesian grids;•••• The use of interface and physics-based grid adaptations to dramatically improve
the solution accuracy and efficiency of the computations;•••• The tool will immediately expand the spectrum of interfacial flow problems
that can be addressed, and will dramatically improve the solution accuracy andefficiency for multi-scale problems.
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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C.7.4. Focus Area 4: Multiphase SeparationsRam Mohan, Group Leader
Faculty Resources:G. Chase (Akron), C. Lira (MSU), C. Petty (MSU), R. Mohan (Tulsa),N. Mueller (MSU), O. Shoham (Tulsa), and M. Worden (MSU)
The Multiphase Separations Group will develop computational methods forpredicting the separation of three phase fluids (i.e., oil-water-gas) and re-suspension ofsolids in three phase fluids. The results will support the evaluation of subsea and surfaceoil-water-gas pipelines, separator designs, and the strategic placement and performanceof sand separators.
Example Project: Sand Separation in Multiphase Flow Production Pipelines
Background
Sand management programs in the petroleum industry are currently focused on sanddetection in a sand-oil-water-gas mixture. They deal with identification of the number ofphases present and the interphase and intra-phase interaction. Doan and Ali (2000)recently developed an empirical correlation with twenty-nine parameters and sixdimensionless groups for the flow of a dilute sand-oil suspension in a horizontal well.These studies have focused on solid-liquid mixture at low flow rates. Doron and Barnea(1993, 1996) developed a three-layer physical model for horizontal pipes to determine thelimit deposit velocity
Proper characterization of different hydrodynamic processes will not only help buildand refine existing predictive tools, but also help optimize the chemical treatment andseparation processes. The processes of dispersions, emulsions, foams, and suspensionsassociated with sand management and separation will present a lot of special challengesto remote operations that will be resolved with the results of this project.
Sand sedimentation in multiphase oil-water-gas mixtures under transient and steadyconditions is still an unresolved problem. Also, sand bed compaction, binding with thefluid media, and re-fluidization of sand in pipelines. Fear of sticking a pig in sanddeposits too often prevents the petroleum industry from pigging the line, which can costproduction reduction and may shorten the life of the pipeline. In the past, the industryhas utilized de-sanding hydrocyclones. However, no criteria have developed for locating,sizing, and operating the cyclones. It is still debatable whether to locate the de-sanderupstream or downstream of a de-gasser. Solids stabilized emulsions create chemicaltreating problems for the industry, especially in remote operations.
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
- C.26 -
Proposed Research
The goal of this project is to develop a means to separate sand in multiphaseproduction lines. The following tasks will support this goal:
•••• Predict the hydrodynamic flow behavior of sand particles in multiphasepipelines, including prediction of sedimentation, re-fluidization, bed formation,compaction and sweeping efficiency.
•••• Predict the hydrodynamic flow behavior of sand particles in de-sandinghydrocyclones.
Research Methods
A state-of-the-art multiphase model for interpenetrating continua will be used toevaluate the fate of sand particles in multiphase pipelines and separators (see, esp,Manninen et al., 1996; Ivanov et al., 1999). A discrete particle method will also beemployed to understand the relationship between in situ sedimentation and operatingconditions. Previously developed mechanistic models and experimental results developedby the Tulsa Separations Group will be used to validate the approach.
Novelty of the Proposed Research, Anticipated Results and Benefits
The proposed study will provide a design tool for sand management and separation.The research will support a comprehensive approach to sand management and separationthat includes detection and characterization of dispersions, emulsions, foams, andsuspensions. Specific deliverables of the proposed study include:
•••• Computational results of sand flow in pipes;
•••• Computational results related to sand separation in hydrocyclones;
•••• Experimental validation of the above multiphase simulations using datareported in the literature and previous performance expectations based onmechanistic models for limiting cases (i.e., two-phase solid/fluid flows);
•••• A design code to be used by industry for sand management in pipelines andseparation of sand in hydrocyclones.
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
- C.27 -
C.7.5. Focus Area 5: Multiphase TurbulenceCharles Petty, Group Leader
Faculty Resources:A. Bénard (MSU), F. Jaberi (MSU), A. Naguib (MSU), B. McLaury (Tulsa),C. Petty (MSU), H. Schock (MSU), T. Shih (MSU), O. Shoham (Tulsa),Z. Wang (MSU), K. Wisecarver (Tulsa)
The Multiphase Turbulence Group will focus on developing methods to predictthe mean field velocity and the mean field pressure distributions for multiphase flowswith strong streamline curvature. Research results will support the analysis ofhydrocyclone separators, mixing of liquid and gases in furnace tubes, and liquid/gassprays.
Example Project: Turbulence Closure for Interpenetrating Continua
Background
Turbulent flows with strong streamline curvature occur in many engineering andnatural situations. Examples include swirling flows in hydrocyclone separators, flowsthrough curved pipes, swirling fuel sprays, turbine mixers, jet-pulsed mixers,impingement mixing of reactants in resin transfer molding, and flows around bluffbodies. An important challenge problem in all of these examples is to predict the meanvelocity field, u< > , the mean pressure field, p< > , and the spatial variation of thecomponents of the Reynolds stress, u 'u '−ρ < > for single-phase fluids and formultiphase fluids.
For constant density Newtonian fluids, the mean velocity and mean pressure fieldsare governed by the single-phase Reynolds Averaged Navier-Stokes (RANS-) equationand the continuity equation:
( u ) ( u u ) p g ( 2 S u 'u ' )t
∂ ρ < > + ∇ ⋅ ρ < >< > = −∇ < > + ρ + ∇ ⋅ µ < > −ρ < >∂
. (C.1)
tr( S ) 0< > = . (C.2)
The k-ε model for single-phase turbulent flows uses a Boussinesq model to relate theReynolds stress and the local mean strain rate (Pope, 2000):
1u 'u ' 2 S tr ( u 'u ' ) Ie 3−ρ < > = µ < > −ρ < > . (C.3)
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
- C.28 -
In the above equation, eµ is the "eddy" viscosity and S< > is the mean strain rate,
T1S [ u ( u ) ]2
< > ≡ ∇ < > + ∇ < > . (C.4)
The mixture model for interpenetrating continua also uses the Boussinesq model to relatethe turbulent stress and the mean strain rate (see Mannheim et al., 1996; Drew andPassman, 1999; Gidaspow, 1994).
An attractive feature of Eq.(C.3) is the property that the production of turbulenceenergy is positive provided the "eddy" viscosity is positive:
u 'u ' : S 2 S : S 0e−ρ < > < > = µ < > < > ≥ . (C.5)
Although Eq.(C.3) satisfies Ineq. (C.5) and may be computationally convenient, it has thefollowing undesirable features (see Parks et al., 1998):
1) For statistically stationary, fully-developed channel flows (or pipe flows), theEq.(C.3) predicts that the turbulent energy is equally distributed over all thecomponents of the fluctuating velocity. This well-known isotropic prediction forsimple shear flows does not agree with longstanding experimental observations.
2) For some flows, Eq. (C.3) is unrealizable inasmuch as it predicts the existence ofnegative eigenvalues for u 'u '< > . This is an unphysical (and unacceptable)property for a closure model.
3) Eq.(C.3) is indifferent to an arbitrary time-dependent orthogonal transformation.This result is contrary to direct numerical simulations (DNS) and large eddysimulations (LES) in non-inertial frames.
Although non-linear counterparts of Eq.(C.3) have been proposed to account for theanisotropic nature of turbulence in simple shear flows (see Pope, 2000), these anisotropicalgebraic models still show the undesirable features listed as 2) and 3) above. Thus,Eq.(C.3) clearly misrepresents the underlying mechanisms associated with the intraphaseexchange of mean momentum and, thereby, does not provide a basis for turbulencemodeling of multiphase flows.
Recent research at MSU (see Parks et al., 1998) has discovered a new class ofalgebraic closures for the Reynolds stress for single-phase fluids that accounts for 1) theanisotropic distribution of turbulent kinetic energy among the three components of thefluctuating velocity for single-phase simple shear flows, 2) the realizability of theReynolds stress, and 3) the influence of frame rotation on the Reynolds stress. Theobjective of this research is 1) to validate this theory experimentally and 2) to extend theapproach to multiphase flows by developing an algebraic turbulence closure for the
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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Reynolds stress appropriate for a two-phase mixture model based on the ideas ofinterpenetrating continua.
Proposed Research
I/UCRC-MTP research will extend the algebraic aniotropic prestress closure forsingle-phase turbulent flows to two-phase turbulent flows. The new theory will be used topredict the mean velocity field, the mean pressure field, and the components of theReynolds stress in industrial process equipment such as hydrocyclone separators, jet-pulsed mixers, and multiphase sprays. Simulations will be implemented using Fluent andother readily available user software. The ability of the new theory to predict the localanisotropy of the turbulent kinetic energy in flows with streamline curvature will bevalidated experimentally for fully developed turbulent flows between two concentriccylinders. The new theory will be used as a microscale anisotropic subgrid model forlarge eddy simulations as well as a mesoscale anisotropic model for the Reynolds stressin the RANS-equation.
Research Methods
Particle Image Velocimetry (PIV) and Laser Doppler Anemometry (LDA) will beused to validate the new single-phase and two-phase closure models for the Reynoldsstress. An optically homogeneous solid-liquid dispersion will be used as a model fluid.Rotational concentric cylinders will be used to develop the turbulent flow at large Taylornumbers. The components of the Reynolds stress will be measured by using LDA andPIV.
The mean field velocity, the mean field pressure, and the Reynolds stress for fullydeveloped rotational turbulent flow will be calculated using the new closure models(single-phase and two-phase) by using established computational codes for the RANS-equation and the transport equations for the turbulent kinetic energy and the turbulentdissipation.
Novelty of the Proposed Research, Anticipated Results, and Benefits
An algebraic, realizable closure for the Reynolds Average Navier-Stokes (RANS-)equation that predicts the essential anisotropic structure of turbulent flows in inertial andnon-inertial frames would have a significant impact on engineering design and evaluationof separation processes, mixing processes, and many other engineering applications. Asuccessful extension of the new theory to multiphase turbulence using the mixture modelof interpenetrating continua would provide a design tool currently unavailable (seeIvanov et al., 1999; Manninen et al., 1996; Pope, 2000).
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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Section D. References
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
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Michigan State UniversityThe University of Akron, The University of Tulsa
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Severino, J.G., Gomez, L.E., Mohan, R.S. and Leibrandt, S., 2002, “Performance of aLarge Tank Separator: Fluid Flow Phenomena and Droplet Size Distribution alongthe Spreader System,” ETCE2002/MANU-29107, Presented at the ASMEEngineering Technology Conference on Energy, Houston, TX, Feb. 4-5, 2002.
Sherony, D.F., R.C. Kointner, and D.T. Wasan, 1978, "Coalescence of SecondaryEmulsions in Fibrous Beds," in Surface and Colloid Science, ed. E. Matijevic, pp 99-159, Plenum, New York.
Skogestad, S., Gundersen, T., Johnsen, O., 1986, “Compositional Simulation of aRefinery Coker Furnace - an Industrial Example of Two-Phase Flow with ChemicalReaction”, Modeling, Identification and Control, 7 (1), 25-44.
Shokoohi, F. and Elrod, H.G., 1987, “Numerical Investigation of The Disintegration ofLiquid Jets”, Journal of Computational Physics, Vol. 71, pp 324-342.
Soule, A.D., C.A. Smith, X.N. Yang, C.T. Lira, 2001, "Adsorption Modeling with theESD Equation of State", Langmuir, 17(10), 2950-2957.
Sprague, D.E., Roy, K., 1990, “Statistical Determination of the Performance and CokingRate of Fired Heaters”, Chemical Engineering Progress, 86 (Aug.), 14-20
Subramanian, R., H. Pyada, C.T. Lira, 1995, "An Engineering Model for PhysicalAdsorption of Gases, and Clustering in Supercritical Fluids", Ind. Eng. Chem. Res.,34, 3830.
Sussman, M., Smereka, P. and Osher, S., 1994, A Level Set Approach for ComputingSolutions to Incomoressible Two-Phase Flow, J. Comput. Phys. 114, 146-159.
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
-D. 6 -
Thompson, T.B., 2002, “Multiphase Fluid Dynamics Research Consortium, Cooperatingfor Success!”, Industrial Symposium held at Michigan State University, EastLansing, MI, September 10th.
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0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
E.1
Section E. Biographical Information
F.1 Faculty Participants and Areas of Expert Knowledge
Faculty Department Expert Knowledge
A. BénardAssociate Professor Mechanical materials processing
computational methodsF. A. Jaberi
Associate Professor Mechanical turbulencecomputational fluid dynamics
K. JayaramanProfessor Chemical polymer processing
rheologyA. Y. Lee
Associate ProfessorMaterialsScience
materials processingrheology of complex fluids
C. T. LiraAssociate Professor Chemical multiphase thermodynamics
multiphase reactorsJ. R. LloydProfessor Mechanical fire and combustion, turbomachinery,
electromagnetic fluids
M. E. MichaelProfessor Chemical polymer rheology
surface propertiesN. Mueller
Assistant Professor Mechanical turbomachinery, compressorsmultiphase systems, HVAC
A. NaguibAssistant Professor Mechanical experimental fluid dynamics
C. A. PettyProfessor Chemical multiphase separations
turbulenceT. I-P ShihProfessor Mechanical automotive engines
computational fluid dynamicsH. J. Schock
Professor Mechanical automotive enginesmultiphase sprays
Z. J. WangAssociate Professor Mechanical turbulence
computational fluid dynamicsI. S. Wichman
Professor Mechanical combustion processesmultiphase sprays
R. M. WordenProfessor Chemical biochemical processes
multiphase catalyst
Mic
higa
n St
ate
Uni
vers
ity
M. ZhuangAssociate Professor Mechanical multiphase aerodynamics
computational fluid dynamics
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
E.2
G. G. ChaseProfessor Chemical filtration
multiphase transport phenomena
E. E. EvansAssistant Professor Chemical crystal growth processes
plasma reactors
S. I. HariharanProfessor Electrical computational fluid dynamics
homogenization theory
R. RamsierAssociate Professor Physics heat transfer
interfacial transport phenomena
D. H. RenekerProfessor
PolymerScience
polymer physicselectrospinning of nanofibersT
he U
nive
rsity
of A
kron
G. W. YoungProfessor Mathematics materials processing
multiphase transport phenomena
B.S. McLauryAssociate Professor Mechanical computational fluid dynamics
corrosion, erosionR. S. Mohan
Associate Professor Mechanical multiphase control systemsmultiphase mixing and separation
O. ShohamProfessor Petroleum multiphase centrifugal separators
computational fluid dynamicsL. Thompson
Assistant Professor Petroleum filtration reservoir simulations
The
Uni
vers
ity o
f Tul
sa
K. D. WisecarverProfessor Chemical petrochemical processes
multiphase reactions
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
F.2
Table F.1a. Annual Budget for the MSU Site, Year 1
Source of FundsItem Member
FeesCostShare
NSFSite
NSFLead
Total ∼ %
Salary and FringesFour Graduate Students
@ $23,400 each$22,767 $37,500 $33,333 $93,600 36%
Salary and FringesFour Faculty Mentors
@ $5,000 each20,000 20,000 8%
Salary and FringesPostdoctoral Associate
25%15,000 15,000 6%
Research TravelFour Projects
@ $2,000 each8,000 8,000
I/UCRC-MTP Review MeetingsTravel, Per Diem, & Fees
Four Projects@ $3,000 each
12,000 12,000
Research S & EFour Projects
@ $2,000 each8,000 8,000
11%
RESEA
RC
H
Salary and FringesCenter Director
Center Co-Director∼ two weeks summer each
$13,333 13,333
Salary and FringesSite Director
∼ two weeks summer5,000 5,000
NSF Evaluator 5,000 5,000
Discretionary 4,233 4,233
11%
AD
MIN
ISTRA
TION
Direct Costs 100,000 37,500 33,333 13,333 184,166 72%
∼ Indirect Costs 50,000 NA 16,667 6,667 73,334 28%
Total Costs $150,000 $37,500 $50,000 $20,000 $257,500 100%
% of Total 58% 15% 19% 8% 100%
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
F.3
Table F.1b. Annual Budget for the MSU Site, Years 2-5
Source of FundsItem Member
FeesCostShare
NSFSite
NSFLead
Total ∼ %
Salary and FringesEight Graduate Students
@ $23,400 each$65,533 $75,000 $46,667 $187,200 40%
Salary and FringesEight Faculty Mentors
@ $5,000 each40,000 40,000 9%
Salary and FringesPostdoctoral Associate
50%25,000 25,000 5%
Research TravelEight Projects@ $2,000 each
16,000 16,000
I/UCRC-MTP Review MeetingsTravel, Per Diem, & Fees
Eight Projects@ $3,000 each
24,000 24,000
Research S & EEight Projects@ $2,000 each
16,000 16,000
12%
RESEA
RC
H
Salary and FringesCenter Director
Center Co-Director∼ two weeks summer each
$13,333 13,333
Salary and FringesSite Director
∼ two weeks summer5,000 5,000
NSF Evaluator 5,000 5,000
Discretionary 3,467 3,467
6%
AD
MIN
ISTRA
TION
Direct Costs 200,000 75,000 46,667 13,333 335,000 72%
∼ Indirect Costs 100,000 NA 23,333 6,667 130,000 28%
Total Costs $300,000 $75,000 $70,000 $20,000 $465,000 100%
% of Total 65% 16% 15% 4% 100%
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
F.4
Table F.2a. Annual Budget for the Akron Site, Year 1
Source of FundsItem Member
FeesCostShare
NSF Site
NSFLead
Total ∼ %
Salary and FringesFour Graduate Students
@ $23,400 each$22,767 $37,500 $33,333 $93,600 40%
Salary and FringesFour Faculty Mentors
@ $5,000 each20,000 20,000 8%
Salary and FringesPostdoctoral Associate
25%15,000 15,000 6%
Research TravelFour Projects
@ $2,000 each8,000 8,000
I/UCRC-MTP Review MeetingsTravel, Per Diem, & Fees
Four Projects@ $3,000 each
12,000 12,000
Research S & EFour Projects
@ $2,000 each8,000 8,000
12%
RESEA
RC
H
Salary and FringesCenter Director
Center Co-Director∼ two weeks summer each
Salary and FringesSite Director
∼ two weeks summer5,000 5,000
NSF Evaluator 5,000 5,000
Discretionary 4,233 4,233
6%
AD
MIN
ISTRA
TION
Direct Costs 100,000 37,500 33,333 170,833 72%
∼ Indirect Costs 50,000 NA 16,667 66,667 28%
Total Costs $150,000 $37,500 $50,000 $237,500 100%
% of Total 63% 16% 21% 100%
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
F.5
Table F.2b. Annual Budget for the Akron Site, Years 2-5
Source of FundsItem Member
FeesCostShare
NSFSite
NSFLead
Total ∼ %
Salary and FringesEight Graduate Students
@ $23,400 each$65,533 $75,000 $46,667 $187,200 42%
Salary and FringesEight Faculty Mentors
@ $5,000 each40,000 40,000 9%
Salary and FringesPostdoctoral Associate
50%25,000 25,000 5%
Research TravelEight Projects@ $2,000 each
16,000 16,000
I/UCRC-MTP Review MeetingsTravel, Per Diem, & Fees
Eight Projects@ $3,000 each
24,000 24,000
Research S & EEight Projects@ $2,000 each
16,000 16,000
13%
RESEA
RC
H
Salary and FringesCenter Director
Center Co-Director∼ two weeks summer each
Salary and FringesSite Director
∼ two weeks summer5,000 5,000
NSF Evaluator 5,000 5,000
Discretionary 3,467 3,467
3%
AD
MIN
ISTRA
TION
Direct Costs 200,000 75,000 46,667 321,667 72%
∼ Indirect Costs 100,000 NA 23,333 123,333 28%
Total Costs $300,000 $75,000 $70,000 $445,000 100%
% of Total 65% 16% 15% 100%
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
F.6
Table F.3a. Annual Budget for the Tulsa Site, Year 1
Source of FundsItem Member
FeesCostShare
NSF Site
NSFLead
Total ∼ %
Salary and FringesFour Graduate Students
@ $23,400 each$22,767 $37,500 $33,333 $93,600 40%
Salary and FringesFour Faculty Mentors
@ $5,000 each20,000 20,000 8%
Salary and FringesPostdoctoral Associate
25%15,000 15,000 6%
Research TravelFour Projects
@ $2,000 each8,000 8,000
I/UCRC-MTP Review MeetingsTravel, Per Diem, & Fees
Four Projects@ $3,000 each
12,000 12,000
Research S & EFour Projects
@ $2,000 each8,000 8,000
12%
RESEA
RC
H
Salary and FringesCenter Director
Center Co-Director∼ two weeks summer each
Salary and FringesSite Director
∼ two weeks summer5,000 5,000
NSF Evaluator 5,000 5,000
Discretionary 4,233 4,233
6%
AD
MIN
ISTRA
TION
Direct Costs 100,000 37,500 33,333 170,833 72%
∼ Indirect Costs 50,000 NA 16,667 66,667 28%
Total Costs $150,000 $37,500 $50,000 $237,500 100%
% of Total 63% 16% 21% 100%
0331977
National Science Foundation Industry/University Cooperative Research Center onMultiphase Transport Phenomena
Michigan State UniversityThe University of Akron, The University of Tulsa
F.7
Table F.3b. Annual Budget for the Tulsa Site, Years 2-5
Source of FundsItem Member
FeesCostShare
NSF Site
NSFLead
Total ∼ %
Salary and FringesEight Graduate Students
@ $23,400 each$65,533 $75,000 $46,667 $187,200 42%
Salary and FringesEight Faculty Mentors
@ $5,000 each40,000 40,000 9%
Salary and FringesPostdoctoral Associate
50%25,000 25,000 5%
Research TravelEight Projects@ $2,000 each
16,000 16,000
I/UCRC-MTP Review MeetingsTravel, Per Diem, & Fees
Eight Projects@ $3,000 each
24,000 24,000
Research S & EEight Projects@ $2,000 each
16,000 16,000
13%
RESEA
RC
H
Salary and FringesCenter Director
Center Co-Director∼ two weeks summer each
Salary and FringesSite Director
∼ two weeks summer5,000 5,000
NSF Evaluator 5,000 5,000
Discretionary 3,467 3,467
3%
AD
MIN
ISTRA
TION
Direct Costs 200,000 75,000 46,667 321,667 72%
∼ Indirect Costs 100,000 NA 23,333 123,333 28%
Total Costs $300,000 $75,000 $70,000 $445,000 100%
% of Total 65% 16% 15% 100%
0331977