ASHRAE Indoor Air Quality Guide

ASHRAE Indoor Air Quality Guide Presented For: Chicago ASHRAE By: James Livingston, Regional Sales Manager, Ruskin Company 1

Purpose of Presentation Comment on ASHRAE IAQ Guide topics as related to air control devices Provide information on the function and benefits of these devices Provide advice on their application 2

IAQ Guide Basics Objectives Presentation Agenda 1 Design & Construction 2 Control Moisture 4 Moisture in HVAC 6 Capture/Exhaust Contaminants 7 Reduce Contaminants 8 Advanced Ventilation Approaches 3

Purpose of IAQ Guide Provide advice on how provide good IAQ via means that are: Cost effective Practical Currently available Technologically sound Sustainable Goal: Increased usage & IAQ! 4

8 Objectives Guide Approach Objectives address components of building IAQ Each Objective contains individual Strategies to help achieve the Objective Benefits designers, constructors, owners and facility managers 5

Scope of IAQ Guide Buildings covered: Commercial & institutional Office Retail Educational Lodging Public assembly 6

Scope of IAQ Guide Buildings not covered: Kitchens Medical procedure rooms Natatoriums Cold buildings Laboratory Industrial Residential Chemical storage 7

Why IAQ? Health & well being of occupants Financial success & sustainability of building 8

Common Sources of Poor IAQ Two Basic Categories Gaseous Radon, C02, chemical vapors, etc. Biological (with 2 subcategories) Microbial Bacteria, molds, mildews, viruses, dust mites, animal dander, etc. Particulate Dust, pollen, building material fibers, process byproduct (such as saw dust), etc. THE SOLUTION TO POLLUTION IS DILUTION W. K.

Health Issues Increased allergy & asthma symptoms Colds & infections Carbon monoxide poisoning Legionnaires disease Lung cancer from Radon exposure 10

Financial Impact Repairs or modifications to correct issues Potential temporary building closure Difficulty in renting spaces Legal action due to sick building or other issues 11

A Different Way Of Thinking Traditional high priority features include cost, space, aesthetics, etc. Make IAQ a priority in the beginning! Early discussions & strategies by all parties Improving IAQ after the fact is difficult and sometimes impossible 12

Objective 1 Manage the Design & Construction Process to Achieve Good IAQ Strategy 1.1 Traditional Design 13

Objective 1 Strategy 1.1 Integrated Design 14

Objective 1 Strategy 1.2 Commissioning Not just post-construction Employ a Commissioning Authority (CxA) for pre-design and during construction Ensure the design meets owners requirements and is being constructed correctly 15

Objective 1 Strategy 1.3 Selecting HVAC Systems Use environmentally-friendly & energy efficient systems when possible Displacement ventilation If conventional means are used (CV, VAV, etc.), be sure good IAQ practices are used (62.1 ventilation for example). 16

Objective 1 Strategy 1.5 Effective Operation & Maintenance O&M can be just as important as design & construction Expected level of owner s O&M efforts? Consider O&M during design & construction Provide documentation & training 17

Objective 2 Control Moisture in Building Assemblies Moisture is a common cause of IAQ problems and responsible for the most costly litigation and remediation Thermal bridging enables interior frost build-up & condensation Condensation liquid can travel through capillary action to inaccessible locations 18

Objective 2 Strategy 2.2 Limit Condensation of Water Vapor within the Building Envelope and on Interior Surfaces Use Thermally Efficient (Insulated) Control Dampers at outside air intakes 19

Strategy 2.2 Why use Thermally Efficient Dampers? Reduce condensation to prevent bacteria, mold, mildew Thermally broken to prevent frost build-up Lessen leakage into or out of space Generally Class 1 leakage 4 cfm/ft² at 1 w.g.

AMCA 500-D Section 6.9 Thermal Efficiency Test Test setup Figure 5.10 Damper tested in both airflow directions ±2 F Steady State Temperature for a period of 10 minutes Applied torque

AMCA 500-D V-groove reference damper 9 cfm per square foot at 1 w.c. How much more efficient is the test damper when compared to the reference damper?

Thermally Efficient Damper Features Insulated & thermally broken blades Blade & jamb seals for low leakage Thermally broken frames Non-metallic bearings

Thermally Efficient Damper Performance AMCA Standard 500-D AMCA certified leakage AMCA certified performance AMCA certified Thermal Efficiency

Objective 2 Strategy 2.3 Maintain Proper Building Pressurization Building pressure affects moisture infiltration and exfiltration Negative pressure in hot, humid conditions promotes moisture infiltration into spaces Positive pressure in humid spaces increases condensation buildup within envelope 25

Strategy 2.3 Pressurization often is not consistent throughout building due to: Stack effect Wind speed & direction Temperature HVAC supply & exhaust rates 26

Strategy 2.3 Airflow measuring stations can assist with pressurization 27

Pick the Product for the Application Use Electronic Air Flow Measurement for very low velocities and large openings Use Velocity Pressure Measurement for high velocities or small openings.

Electronic Airflow Measuring Thermistors, heated mass flow sensors, hot film anemometers, etc. Measures energy to heat element Low velocities as little as 0 fpm 29

Velocity Pressure Airflow Measuring Differential Pressure Minimum 300 fpm Total Pressure Chamber Pt Ps Static Pressure Chamber Pv = Pt - Ps

Locations For Airflow Measuring Stations

Suggestions for Measuring Outside Air VAV & CV Systems Air measuring station w/ control damper built-in Damper control is manual or by BAS DCV Systems Air measuring station with built-in control damper and control system Control system maintains CFM set point as fans scroll up and down Any system, limited space Air measuring combined with outside air louver Can be as little as 4 total depth 32

Suggestions for Measuring Supply Air Fan inlet Highest velocity point in the system Total system supply airflow Retrofit single floor or pressure area Probes or stations Can install as close as 4 in front of existing dampers New construction single floor or pressure area Air measuring station w/ control damper built-in Damper control is manual or by BAS 33

Suggestions for Measuring Return Air Retrofit single floor or pressure area Probes or stations Can install as close as 4 in front of existing dampers New construction single floor or pressure area Air measuring station w/ control damper built-in Damper control is manual or by BAS 34

Suggestions for Measuring Exhaust Air Use velocity pressure probes or stations Works well with high velocity exhaust airflow Much less expensive than electronic airflow stations 35

Objective 4 Control Moisture & Contaminants Related to Mechanical Systems Strategy 4.1 Control Moisture and Dirt in Air- Handling Systems Fungi & bacteria are normally present on building interior surfaces, including HVAC components Microorganism growth in HVAC system results in malodors, nasal & throat irritation and buildingrelated illnesses 36

Strategy 4.1 Outside air louvers can prevent rain penetration Louvers 37

Louvers With Plenum Behind 38

Water Penetration 39

Sloped Plenum Detail 40

Strategy 4.1 Traditional louvers provide protection from non-storm rain Wind Driven Rain Resistant louver provide storm condition protection Let s look at the differences 41

Traditional Louvers: Strategy 4.1 Horizontal blades Drain Gutters Wide Spacing High Free Area Low Cost Stops some rain Not effective in storms 42

Strategy 4.1 Traditional louver sizing AMCA Water Penetration test Beginning Point of Water Penetration free area velocity (FAV) Determine design FAV considering AMCA test data CFM/FAV = Total Free Area required Reference louver Free Area Guide to determine appropriate louver size 43

Standard 500-L Louvers 5.6 Water Penetration Air Exhaust Waterdrop Manifold Wetted Wall Manifold Test Unit Water Droplets Air Entrained into chamber through louver Still Air Condition! Exhaust Fan Air Flow Measurement Collection Zone

Test Conditions Standard 500-L Louvers 48 x 48 size 15 minute intervals Manifold (raindrops) -4 per hour (3.15 gal/15 min) Wetted wall -.25 gpm (3.75 gallons/15 min) Ventilation airflow only no wind 1250 fpm max free area velocity

AMCA Still Air Water Test

.01 oz./ft² of free area Water Penetration Graph Beginning Point Of Water Penetration:.01 oz/ft² at 1,023 fpm Free Area Velocity

Still Air Test with Non-drainable Louver

Where to use: Traditional Louvers Properly drained applications Sloped plenums & ductwork Floor drains Protected areas (overhangs, barriers, interior, non-prevailing wind elevations) Screen applications (vision barriers) Sizing Use Safety Factor (15% to 20% min) Does NOT stop storm rain

Traditional Drainable Louver 29 mph wind, 3 /hr rain, 1,000 fpm intake velocity

New Louver Technology Wind Driven Rain Louvers Horizontal or Vertical blades Drain Gutters on horizontal Hooks on vertical Close spacing Lower Free Area Higher Velocity Effective in storms 51

Std 500-L Wind Driven Rain Test 5.11 Water Rejection Wind Driven Rain Air Exhaust Test Louver Wind Driven Rain plus Air Entrained Into Chamber Through Louver Rain Water Discharge Nozzles Wind/Rain Machine Exhaust Fan Collection Zone 52

Std 500-L Wind Driven Rain Test Rejection Effectiveness Classes A 99% to 100% B 95% to 98.9% C 94.9% to 80% D below 80% (std. louvers) 3 rain/29 mph wind 8 rain/50 mph wind 53

Wind Driven Rain Louver 29 mph wind, 3 /hr rain, 2,000 fpm intake velocity

Rear view, 29 mph wind, 3 /hr rain, 2,000 fpm intake velocity

How Much Water Is Applied? 3 Per Hour Rain On 1m X 1m 21 Gallons Applied Over 1 Hr. Class A (99% or better) allows 27 fl. oz penetration Class D (80% or worse) allows over 4 gallons Std Louvers (60% or lower) -over 7 gallons

Wind Driven Rain Louver Benefits Prevent rain infiltration Lessens interior water damage & mold growth Helps keep walls & floors dry Helps keep filters dry Excellent for Penthouses Allow higher intake velocities Use smaller louvers! Reduce future problems & liability

Wind Driven Rain Louvers Horizontal blade models Vertical blade models 40% - 50% free area 2 to 8 deep Class A @ 800 to 1200 fpm Moderate p Traditional appearance 40% - 45% free area 3 to 7 deep Class A @ 1500 to 2100 fpm Low p Best performance 58

Sizing Example 48 x 48 & 7,000 cfm 6 Traditional 710 fpm.07 p 60% Wind Driven Rain Effectiveness (29 mph) Cost 1.0 5 Horizontal WDR 1,002 fpm.16 p 99.8% Wind Driven Rain Effectiveness (29 mph) Cost 1.7 6 Vertical WDR 1,030 fpm.09 p 99.8% Wind Driven Rain Effectiveness (50 mph) Cost 2.7 48 x 36 (25% smaller) 1,488 fpm.18 p 99.8% Wind Driven Rain Effectiveness (50 mph) Cost 2.3

Rooftop Intakes Traditional style, allows rain penetration Wind Driven Rain Design, prevents rain penetration

What About Snow? 61

Suggestion for Stopping Snow Penetration Heated screen behind louver Prevents snow blowing into ductwork Reasonable pressure drop Relatively slow airflow -350 FPM Face area velocity.

Objective 7 Reduce Contaminant Concentrations through Ventilation, Filtration and Air Cleaning First goal is to reducing contaminant sources, then capturing & exhausting Remaining contaminants should be Diluted with ventilation air, or Reduced by filtration and gas-phased air cleaning (FAC) 63

Strategy 7.2 Continuously Monitor and Control Outdoor Air Delivery Fixed minimum outdoor air dampers may not provide optimum control of intake CFM, particularly in VAV systems Over-ventilation is common now estimated 30% annual savings in U.S. building energy costs if ventilation per standards is maintained 64

Suggestion for Maintaining Proper Outdoor Air Intake Levels Use air measuring station with built-in control damper and control system to maintain CFM set point 65

Air Measuring & Control Stations Advantages System automatically modulates damper to maintain CFM Can be used as minimum outside air damper only (overridden when economizer damper opens), or Can be used as entire outside air damper 66

Pressure Signal Chart text Air Measuring & Control Damper Documentation I/O Chart Provided w/ unit Calibration Certificate 0-10 VDC Input -CFM Setpoint 0 10 VDC Output -Measured CFM Alarm when CFM falls below setpoint

Strategy 7.2 Continuously Monitor and Control Outdoor Air Delivery Proper placement of airflow stations is critical Installing too close to an elbow or other disrupting feature can affect performance 68

Air Measurement Station Placements for Acceptable Installations

Air Measurement Station Placements for Acceptable Installations Air Measurement should be in the Mechanical Spec!

Air Measurement Station Placements for Acceptable Installations 5D 1D 90 DEGREE UNVANED ELBOW

Strategy 7.2 Continuously Monitor and Control Outdoor Air Delivery Consider using airflow measuring sensors between fixed louver blades Higher velocity, better accuracy

Accuracy Considerations: Outside Air Measurement Advantage Outside Air 20,000 CFM supply air measured ±1,000 CFM @ 5% accuracy (S.A.) 16,000 CFM return air measured ±800 CFM @ 5% accuracy (R.A.) Air Flow Sensing Stations THE DIFFERENCE Could be off by ±1,800 CFM Versus measurement at the intake 4,000 CFM @ 5% accuracy (O.A.) ±200 CFM @ 5% accuracy (O.A.)

Objective 8 Apply More Advanced Ventilation Approaches Strategy 8.2 Use Energy Recovery Ventilation Where Appropriate Required by ASHRAE 90.1 2007 & 2010 in some cases 74

Code Driven Requirements ASHRAE 90.1 2007 Energy Standard Energy recovery is required on individual fan systems that are: 5000 cfm or greater, and Outside air accounts for 70% or more of the design supply air quantity Energy recovery system shall have 50% effectiveness: Change in enthalpy equal to 50% of the difference between outdoor air and return air at design conditions

Status of Code Adoption: Commercial www.energycodes.gov/adoption/states As of February 2013 Most States are Expected to Adopt 90.1 2010 by End of 2013!

DOE Climate Zone Map for 90.1 Helena MT Duluth, MN Boise, ID Chicago, IL Burlington, VT Salem, OR Baltimore MD San Francisco CA Phoenix, AZ El Paso, TX Memphis TN Miami FL Figure B-1 Albuquerque, NM Houston, TX

How do Climate Zones affect ERV? ASHRAE 90.1 2010 states: 6.5.6.1 Exhaust Air Energy Recovery. Each fan system shall have an energy recovery system when the system s supply air flow rate exceeds the value listed in table 6.5.6.1 based on the climate zone and percentage of outdoor air flow rate at design conditions.

ASHRAE 189.1 Standard Stretch standard for energy efficiency Glimpse of the future of 90.1 Currently being specified for some government buildings Requires even more energy recovery As low as 10% outside air requires energy recovery in some cases The energy recovery effectiveness shall be 60%

Energy Recovery ERV Latent Recovery Energy Recovery Wheels Fixed Plate w/ Latent Transfer HRV Sensible Only (no latent) Fixed Plate Heat Pipe Runaround Loops 80

Wheel ERV s How They Work Wheel Rotates between the Return Air and the Outdoor Air Airstreams Return Air Temperature and Humidity is absorbed onto the Desiccant Wheel Outdoor Air is tempered (Heated/Cooled) as it flows across the Wheel Outdoor Air Humidity Decreases or Increases as air flows across the Wheel

Exhaust Air Transfer Ratio EATR is the % of air being exhausted from the occupied space that leaks around the ERV wheel and re-enters occupied space. Importance: Per ASHRAE 62.1

Dedicated Duct System

Ducted to Rooftop Unit

Common ERV Configurations Stand Alone Unitized Typically 300 to 12,000 CFM

Small ERV s 150 to 1000 CFM Only 18 to 22 tall!

Example of small ERV application

Small ERV Installation

Questions? 89

Thank You! 90