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Field measurements of mercury and SO3 from the Fabric Filter at the Callide Oxyfuel Project during Air-Oxy Transitions
Rohan Stanger*a, Timothy Tinga, Lawrence Beloa, Chris Sperob, Terry WallaaUniversity of Newcastle, bCallide Oxyfuel Project
5th Oxyfuel Combustion Research Network MeetingWuhan, CHINA29th October 2015
ANLECR&D Research areas at COP to reduce cost and risk
• SO3 formation → acid dew point corrosion + temperature• Hg capture → affected by oxy-conditions or carried to CPU
→ Hg oxidation uncertain
• SO2 capture → pH and NaOH usage in high CO2→ SO2/NOx reactions (N2O) in CPU
• Removal of Hg2+ ?
• NOx capture in CPU → kinetic reaction to NO2 or emitted as NO→ stability of condensates
• Hg capture in CPU → dependant on NOx→ product identification and stability→ risk to brazed Al-HEX cold box
Fabric Filter(not ESP)
NaOH Polishing (not FGD)
Compression(no AC bed)
The Callide Oxyfuel Project Retrofit
Picture courtesy of Yamada, IHI APP Oxyfuel Course 2010
No deSOx / deNOx / de-HgAll impurities sent to CPU
64-74% Hg captured in
fly ash
~70% Hg2+
in flue gasTo CPU
Hg results from Macquarie UniTrace Impurity Study, Nelson 2012
Transition Schedule and associated measurements
0:00 - 6:00 8:00 10:00 12:00 14:00 16:00 18:00 20:00 22:00 0:00 - 8:00 10:00 12:00 14:00 16:00 18:00MONDAY 30/06/14 TUESDAY 1/07/14
Sampling interval
AIR Mode
OXY Mode
Ash Samples taken
12
3
4
5
6
7
89
10
11
12
1314
Low NOx burners used Original burners
used
• Transitions between air-oxy modes occur without CO2 capture• All flue gas to stack (except recycle) no CPU• Real oxyfuel emissions • Ideal time for studying Hg behaviour under changing O2
Heated Lance for SO3 and Total Hg(30 minute interval sampling during transitions)
• 2 heated zones• Collects 1 SO3 + 2 Total Hg samples• 10 minute “change-over”
Non-heated lance for continuous “Online Hg”• Designed with manual “switch” between
Hgtotal and Hg0
• In practice SnCl2 not responsive enough for Hgtotal
• Ohio Lumex 915+ Hg analyser• 1-20,000ng/m3 Hg in real time
Probe Assemblies
PFA sampling tubes with AC beds
Heated Probe gas conditioning
Online Hg Probe gas conditioning with PFA switches
Location on stack and sampling equipment
Hg measurements with original burners
AIR
OXY
(as Hg0)
sampling interval
Hg measurements with Low NOx burners(2 out of 4 burners)
(as Hg0 and Hgtotal)
(shaded Online Hg as HgTotal)
(note change in scale from previous slide, was 5µg/m3)
Bigger Picture – Historical trends in CO & Hg
(as Hgtotal)Higher CO
WithLow NOxburners
Summary of Hg exiting the Fabric Filter
• Hg affected by burner configuration• Similar capture in air and oxy firing modes
AIR OXYLow NOx Original Low NOx Original
HgTotal gas µg/m3 0.07 0.53 0.15 4.4* → 2
Hg2+ 0% 77% 65% 87%
HgTotal gas µg/m3
Corrected to 12%CO2
0.06 0.45 0.03 1.2* → 0.42
Hg Captured(by mass balance) 98 % 93% 99% 93%
* Highest point in transition corresponding to higher O2
SO3 measurementsSample Description SO3, ppm
1 OXY steady 0.55
2 OXY → AIR 0.56
3 OXY → AIR <0.27
4 OXY → AIR <0.23
5 AIR steady <0.06
6 AIR → OXY <0.25
7 AIR → OXY <0.26
8 AIR → OXY 0.82
9 OXY steady <0.14
10 AIR steady <0.06
11 AIR → OXY <0.28
12 AIR → OXY <0.26
13 AIR → OXY <0.28
14 OXY steady <0.10
Previous Measurements
31/05/2014 OXY steady 3.65
27/06/2014 OXY steady 1.60
28/06/2014 OXY steady 0.58
• Very low concentrations
• 0.6-3.6ppm SO3• 0.08-0.5% conversion SO2• ADP in oxy 118-136°C• Most below detection limits
• Disappointing for researchers
• Great results for Operators
• BUT is this the whole story?
Recall the Gas Cooler on COP flowsheet
• Gas Cooler used in oxy mode only
• Potential for cold surfaces during transitions
• Speculation that SO3condensing as H2SO4
Bypassed in air mode
oxy mode
Conclusions
• The capture of Hg at Fabric Filter >90%• Burner configuration has over-riding influence on
• Hg total• In particular Hg 2+
• Oxy-firing showed higher concentrations of Hg 2+• Similar to air when corrected to 12% CO2• Expected to be beneficial for downstream capture
• Combined methods of Total Hg (AC) & Online Hg0
allowed trends in Hg 2+ to be observed
• SO3 measurements indicate very low concentrations 0.6-3.6ppm• May be indicator of acid condensation during transitions
Thanks for Listening
further questions?
rohan.stanger@newcastle.edu.au
Overview
• Current work at UoN• Experimental• Results• Key Findings
Comparison of SO3 measurements(& estimates)
Comparison of Hg measurements(by gas phase mass balancing-has advantage of online)
Comparison of Hg measurements(by ash balancing- a poor method for transition tests)
Fabric Filter Trial Outcomes• SO3 levels below detection limit in transitions• SO3 level 0.6 - 3.7ppm in steady state oxy-mode
• Hg affected by burner configuration
AIR OXYLow NOx Original Low NOx Original
HgTotal gas µg/m3 0.07 0.53 0.15 4.4* → 2
Hg2+ 0% 77% 65% 87%
HgTotal gas µg/m3
Corrected to 12%CO2
0.06 0.45 0.03 1.2* → 0.42
Hg Captured 98 % 93% 99% 93%
* Highest point in transition corresponding to higher O2
Oxyfuel research at UoN
• Part of Callide Oxyfuel Project Feasibility Study 2005-6• Coal reactivity 2007-9• Sulfur impacts 2009-11
– Review, SO3 formation, catalytic impacts, ADP
• NOx in compression 2012-15– Effect of pressure residence time, capture in H2O– Laboratory compression system, mass balancing
• Hg in compression 2012-15– Impact of NOx + ∆P + ∆t– Mass balancing → Recovery methods
• Emissions from condensates (depressurised)
Further Research Needs
• Hg-NOx product identification• Different sections of compression • Higher temperature (<200°C directly after ∆P, dry)• After cooling+ water condensation
• SO2-NOx combined capture in compression• Optimised• Formation of N2O minimised or accounted for
• CPU liquid product recovery
Research Needs in the COP CPU
• Australian context– Low Coal sulfur, no deSOx– Low Hg + Fabric Filter, no AC guard bed– No SCR/nSCR
• For a Australian retrofit– Caustic polishing at low pressure– CPU to passively remove NOx + Hg as condensates– Cold Box to remove remaining NOx from product CO2
and recycle•
ANLEC R&DAustralian National Low Emission CoalResearch & Development
• Combined Federal Government Funding & Australian Coal Association• Addresses:
– The near term risk reduction and technology developments necessary for successful demonstration of LECT in Australia.
– The delivery of skills, data and knowledge to assist key stakeholders understand the benefits and deployment risks of LECT's.
– Support for, and investigation of, issues affecting the performance of the early demonstration projects.
• Program overall funding……across 2012 to 2020 ASK NOEL
Publications• Stanger, R, T. Ting, L Belo, C Spero, T Wall (2015), Field measurements of NOx and mercury from oxy-fuel
compression condensates at the Callide Oxyfuel Project, International Journal of Greenhouse Gas Control 42: 485-493, 2015
• Stanger, R., T. Ting, C. Spero and T. Wall (2015). Oxyfuel derived CO2 compression experiments with NOx, SOx and mercury removal—Experiments involving compression of slip-streams from the Callide Oxyfuel Project (COP). International Journal of Greenhouse Gas Control 41: 50-59, 2015
• Stanger R, T Ting, T Wall, High pressure conversion of NOx and Hg and their capture as aqueous condensates in a laboratory piston-compressor simulating oxyfuel CO2 compression, International Journal of Greenhouse Gas Control 29, 2014
• Ting T, R Stanger, T Wall, Oxyfuel CO2 compression: The gas phase reaction of elemental mercury and NOx at high pressure and absorption in nitric acid, International Journal of Greenhouse Gas Control, 29 2014
• Ting, T., R. Stanger, and T. Wall, Laboratory investigation of high pressure NO oxidation to NO2 and capture with liquid and gaseous water under oxy-fuel CO2 compression conditions. International Journal of Greenhouse Gas Control, 18(0) 2013
• ANLECR&D Report website: www.anlecrd.com.au/projects/gas-quality-impacts-assessment-and-control-in-oxy-fuel
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