ebc seminar the iaq/mold assessment – getting it right! – controlling your risk
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EBC Seminar The IAQ/Mold Assessment – Getting it Right! – Controlling Your Risk. Next Speaker Rosemary McCafferty Haley & Aldrich, Inc. Outline. Vapor Intrusion Overview Vapor Intrusion Sampling Vapor Intrusion Evaluation Consideration Remediation Case Study Questions. - PowerPoint PPT PresentationTRANSCRIPT
EBC SeminarThe IAQ/Mold Assessment
– Getting it Right! – Controlling Your Risk
Next Speaker
Rosemary McCaffertyHaley & Aldrich, Inc.
Outline
• Vapor Intrusion Overview • Vapor Intrusion Sampling • Vapor Intrusion Evaluation Consideration• Remediation• Case Study• Questions
Vapor Intrusion Overview:Vapor Intrusion to Indoor Air
Vapor intrusion is the migration of volatile chemicals from the subsurface (soil gas) through cracks in the foundation and into indoor air. Sources can be soil, groundwater or free product (LNAPL).
Soil Gas Properties And Factors Affecting Its Behavior
• Soil gas enters structures through the openings in the foundation. The concentration found in any building is determined by several factors, including:– the concentration of gas in the soil– the permeability of the soil– the pressure differential between the soil and the
building– other preferential pathways
• Most buildings exert a negative pressure on the soil because of the natural stack effect and exhaust devices that exist in all buildings. This “stack effect” can bring in soil gas.
State Vapor Intrusion Guidance
Not evaluated
Defers to federal program
Developed/developing program with varied flexibility
Developed program with varied flexibility, including numerical standards/screening criteria
Conservative program with substantial regulatory oversight
Currently developing guidance No guidance; pathway not evaluated currently
Attributes of MA, NY, and NJ GuidanceMA NY NJ
Trigger distance (feet)
GW: 30H; 15VSoil: 6H; 10V
100 100H; 30V?
Modeling vs. Measurement
Measurement
Measurement
Measurement
Numerical criteria
GW IA (5 compounds)
IA, possibly SV and GW
Background #s incorporated?
Yes Yes No
Analyte list Site-related SV: “wide range”IA: site-related
Full suite TO-15
Outdoor air sampling?
Yes Yes Yes
Hypothetical future use?
No Yes Yes
Massachusetts DEP VI Regulatory Guidance
• GW-2 Groundwater-to-Indoor Air Standards • Indoor Air Sampling & Evaluation Guide, April 2002• Tiered, risk-based approach:
– Generic cleanup standards, – Site-specific standards using modeling, – Site-specific risk assessment
• Background included quantitatively in standards and evaluation (75th - 90th percentile literature value)
• **Critical Exposure Pathways – “measurable concentrations of OHM into the living or working space of a pre-school, daycare, school or occupied residential dwelling…” – Experience says that “background” is not always sufficient. Individual
case managers may require non-detects.
Vapor Intrusion Sampling:When VI would be evaluated (in
MA)• Presence of occupied building• Groundwater concentrations (MA trigger distances)
exceed GW-2 standards • Volatile compounds detected in soil (no screening
levels provided)• Presence of LNAPL/free product (MA trigger
distances) • Soil gas concentrations above screening values
(petroleum sites only)• Known or suspect source beneath structure
Definitions Of Soil Gas• Gaseous compounds (and/or elements) in the
spaces between particles of the earth and soil. These gases can be moved or driven out under pressure.
• Soil gas is vapor that can be extracted from the subsurface, from pores in unconsolidated material above the water table.
Bang Bar Installation
source: Solinst
Soil Gas from Permanent Well
Indoor Air Sampling Considerations
• Conceptual Site Model• Site-Specific Compounds
of Concern• Building Survey• Preferential Pathways• Background*• Individual or Batch Cleaned
Canisters• Sample Collection• Method TO-15/-14/-17,
APH• Certified Laboratories
When to Collect Indoor Air Samples?
Parameter Most Conservative Least Conservative
Season Late winter/early spring Summer
Temperature Indoor 10F > Outdoor Indoor < Outdoor
Wind Steady > 5 mph Calm
Soil Saturated with rain Dry
Doors/Windows Closed Open
Mechanical HeatingSystem
Operating Off
Mechanical Fans Off On
(Indoor Air Sampling and Evaluation Guide, MADEP, April 2002)
Indoor Air Background• Things that are present at a site in the absence of a
release• May be naturally occurring or anthropogenic
• Mold, Moisture, Radon, Pet allergens• Carbon dioxide and Carbon monoxide• Asbestos and Particulates• VOCs/SVOCs
• Can differ from residence to residence & from night to day• Background sources/studies
• EPA VOC Database/Shah and Singh – 1988• Stolwijk – 1990• MA DEP IA Hydrocarbon Study – 1997• H&A/Alpha Labs MA Residential IA Study-2004/2005
Vapor Intrusion Evaluation Considerations
(in Massachusetts)
Evaluation of Potential Indoor Air Impacts from
Subsurface Source1. Compare groundwater, soil and/or soil gas
concentrations to screening levelsIf groundwater or soil gas concentrations do not exceed screening levels AND no precluding factors exist, then no further action is necessary.Precluding factors include:
– Preferential migration pathways (e.g., utilities, sumps, openings to the subsurface)
– Very shallow vapor sources or wet basements– Very “tight” buildings with low air exchange rates or high
indoor/outdoor pressure differentials2. Groundwater, Soil, Soil Gas Modeling
Evaluation of Potential Indoor Air Impacts from Subsurface Source2. Compare list of indoor air
contaminants to subsurface contaminants– Chemicals detected in both
subsurface media and indoor air are more likely to be site-related
– Indicator compounds not commonly found in household products (e.g., 1,1-DCE, radon)
– Potential for reverse migration of vapors to occur (from building interior to sub-slab)
3. Compare indoor air concentrations to literature or site-specific background values and outdoor air concentrations
Evaluation of Potential Indoor Air Impacts from
Subsurface Source4. Compare indoor air concentrations from different levels (or
areas) to evaluate presence of concentration gradients.
basement
1st floor
2nd floor
soil gas
groundwater
Remediation:Setting Cleanup Standards
• Risk Based Targets• Background Values• Non-Detect (CEP)
Consider Vapor Mitigation Options
• Engineering Controls– Floor slab sealing– Vapor barriers– Increased ventilation– Sub-slab
depressurization• Institutional
Controls– Deed restrictions
• Active Remediation– SVE
• Monitoring– Long-term costs– Ownership– Liability– Public perception
(USEPA-TIO Internet Seminar, February 11-12, 2003.
Summary• Management of VI sites differs between
states• Sampling should be guided by historic
information, site conditions, and available data
• Cleanup standards will depend on site use
• VI mitigation is often a cost-effective solution, especially when implemented during construction or redevelopment
Case Study Site: 6 Family Residence
• Conditions: adjacent dry cleaner potential source of legacy chlorinated solvents; groundwater < GW-2, however, elevated soil gas
• Identified: Substantial Release Migration “releases to the groundwater that have resulted or are within one year likely to result in the discharge of vapors into school buildings or occupied residential dwellings.”
• Installed and are operating of a subslab depressurization/ventilation to mitigate the volatilization of VOCs into the building from the underlying groundwater.
• Assessed indoor air quality to evaluate the effectiveness of the subslab system
Thank You• State and federal vapor intrusion guidance
and references can be found at: http://www.haleyaldrich.com/vi%20services.html
• Searchable, indexed database for household products: http://householdproducts.nlm.nih.gov/
• Questions?