Handout 1

Space Pressurization:Concept and Practice ASHRAE Distinguished Lecture Series

Jim CooganSiemens Building Technologies

YEA Conference – Specialty Environmental DesignMarch 25, 2014

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Agenda

Introduction (concept, purpose, uses, scope)Physics: Infiltration and ContainmentPressurization MethodsDesign StepsContaminant Control PerspectiveSummary

Handout 2

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Room Pressurization

A ventilation technology that controls migration

of air contaminants by inducing drafts between spaces.

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Room Pressurization

Exhaust system removes air

Supply system delivers less

Room pressureis negative

Infiltration makes up the difference

Inward air flow contains pollutants

Handout 3

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Introduction: Who uses it? Why?

Biological and Chemical Laboratoriesprevent spread of airborne hazards

Hospital Isolation Roomsprotect patients and staff from germs

Hospital Pharmaciesfacilitate sterile compounding

Clean Manufacturingmaintain product quality

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Introduction: Who else uses it?

Office towerscontrol smoke in a fire; maintain exit path

Any Buildingseparate rest rooms from other spaces

Restaurantskeep kitchen smells out of the dining room

Any Buildingkeep unconditioned OA out of occupied spaces

These uses are out of today’s scope

Handout 4

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How is success defined?

Success is control of contaminants, not flows and pressure values

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Infiltration and Containment

Infiltration: mechanical processVelocity, Area, PressureInfiltration CurvesImportance of the EnvelopeSelect Pressurization LevelSpecifying the Envelope

Handout 5

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Infiltration Process:Pressure, Velocity, Area, Flow

Infiltration is a physical processPressurization is an engineered resultASHRAE Handbook and Ventilation Manual from ACGIH model the process

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Pressure vs. Velocity

Simple approach is to model the velocity with a discharge coefficient

ACGIH Industrial Ventilation: 7-3

ASHRAE Fundamentals Handbook presents more complex model, but the result is nearly the same

Pv )4000(6.0

Handout 6

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Infiltration Model for Pressurization

Air velocity through gaps in envelope controls contaminants

Velocity related to pressure by orifice flow

Transfer flow and HVAC flow difference is leak area times velocity

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Reality of Room Air Motion

Photograph of flow field (2D) in cross section of a room“Particle Image Velocimetry”Zhao L., ASHRAE Transactions, DA-07-044

Handout 7

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Velocity and Leakage Area

Flow is velocity times area2011 ASHRAE Handbook HVAC Applications,

puts it together: 53-9

Q = infiltration flow, cfmA = leakage area, sqft

P = pressure across envelope, inwc

PAQ 2610

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Infiltration Curve –Pressure Difference vs. Flow

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Infiltrating Air Flow

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Handout 8

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Infiltration Curves for Several Values of Leakage Area

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Importance of the Envelope

Leakage area is the main mechanical parameter in the pressurization system

Like knowing the hx characteristics to apply a heating coil

Like knowing the pipe diameter in a hydronic system

Handout 9

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Select Pressurization LevelChoose the flow offsetLet it determine the pressure

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Select Pressurization LevelChoose the pressureLet it determine the flow offset

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Handout 10

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Select Pressurization Level

Different ways to express the level of pressurization in terms of the pressure differencein terms of the infiltration flow

“Specify either the pressure or the flow offset, not both.”

Unless you are trying to specify the envelope

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Pressurization and Migration

Positive room pressure drives air and contaminants out

Negative room pressure draws air and contaminants in

Neutral room pressure exchanges air and contaminants in both directions

Handout 11

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Pressurization via HVAC

Control Methods Explained and ComparedDifferential Flow ControlPressure FeedbackCascade Control

Selecting a Pressurization Control MethodHow Tight is Tight?Required Pressure Relationships

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Control Methods Compared

Three widely published methodsSpace pressure feedbackDifferential flow controlCascade control

References: 2011 ASHRAE Handbook, HVAC Applications.Chapter 16 Laboratory Systems Siemens Building Technologies: Doc #125-2412. Room Pressurization Control

Handout 12

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Control Methods Compared

Some other waysAdaptive leakage modelTrim valve

References: W Sun, ASHRAE Transactions, NA-04-7-2. Quantitative Multistage Pressurizations in Controlled and Critical EnvironmentsL. Gartner and C. Kiley, Anthology of Biosafety 2005.Animal Room Design Issues in High Containment

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Pressure Feedback

Handout 13

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Pressure Feedback

Measure pressure differenceacross room boundary

Compare to selected setpointAdjust supply flow or exhaust

to maintain pressure difference

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Differential Flow Control

Handout 14

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Differential Flow Control

Carefully control air supply to roomCarefully control all exhaust from roomEnforce a difference between themSelect the size of difference

to reliably contain pollutants

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Cascade Control

Handout 15

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Cascade Control

Has other names:“adaptive offset” “DP reset”

Measure pressure differenceacross room boundary

Compare to selected setpointControl supply and exhaust flowEnforce a difference between themDynamically adjust flow difference

to maintain the pressure setpoint

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Selecting a Control Method

Factors affecting selectionTightness of envelopeNumber of pressure levels neededSpeed of disturbances and responseDuct conditions for flow measurement

Reference: 2011 ASHRAE Handbook – HVAC Applications, Chapter 16 - Laboratory Systems, page 16.12

Handout 16

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Tightness of Envelope

ox

x

x x

o

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Number of Pressure Levels

Relatively simple requirement2-levels, OK for Differential Flow Tracking

Handout 17

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Number of Pressure Levels

Indicate intended relative pressure levels

+

++

-

--

-

----

--

------

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Effect of Air Flow Errors, In and Out

Nominal value ErrorExhaust flow 1000 +/- 100Supply flow 850 +/- 85Transfer flow 150 +/- 185

Numerical illustration

Handout 18

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Select Pressurization Level

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Based on leakage areaExample: 150 cfm for ½ square foot

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Select Accuracy Target

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Based on need to control contaminantsNot product spec’s

Handout 19

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Derive Flow Control Accuracy

Nominal value ErrorExhaust flow 1000 +/- 30Supply flow 850 +/- 30Transfer flow 150 +/- 45

Numerical illustrationBase flow control accuracy on desired infiltrationANSI Z9.5, Laboratory Ventilation

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Derive Flow Control Accuracy

Nominal value ErrorExhaust flow 1000

200+/- 30+/- 30

Supply flow 85050

+/- 30+/- 30

Transfer flow 150 +/- 45

Numerical illustrationConsider accuracy across range of flow valuesPressurization specs easier to meet at low flow

Handout 20

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Agenda

Introduction (concept, purpose, uses)Physics: Infiltration and ContainmentPressurization MethodsDesign Steps

Contaminant Control PerspectiveSummary

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Pressurization and Contaminant Control

Theory: net inward flow blocks contaminantsRecent research relates pressurization

to contaminant controlASHRAE research relates pressure to clean room contamination: RP 1344 and RP 1399Bio lab experiments: Bennet, Applied Biosafety, 2005Isolation room research, Tang, et al.

Success is control of contaminants, not flows and pressure values

Fact: contaminants cross boundaries for many reasons

Handout 21

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It’s like baseballEven if the wind’s blowing in, sometimes stuff gets out.

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Pressurization and Contaminant Control

Contaminant control can be very important or only slightly important

Biosafety standards recognize range of hazards and range of responses

Engineering and commissioning should match effort and solutions to needs

Handout 22

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Levels of Contaminant Control

Pressurization is one toolPhysical barrier is also

BSL 1 – Laboratories should have doorsBSL 2 – Doors should be self-closingBSL 3 – Series of two self-closing doorsBSL 4 – Airlock with air tight doors

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Summary

Space pressurization: tool for contamination control,not a ‘magic shield’Envelope leakage is main mechanical parameterSeveral HVAC control methods

Differential flow control is used most oftenChoice usually driven by envelope

Derive air flow accuracy spec from pressurizationAlign engineering effort with the hazard

Handout 23

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Thank you!Questions?

Jim Coogan, PEJim.Coogan@Siemens.com