Life Cycle Analysis Meets Cost Benefit Analysis (in the Paint Aisle)

Jeff Cantin jeff.cantin@erg.com Bev Sauer Franklin Associates (a div. of ERG) bsauer@fal.com May 19-22, 2008 Baltimore MD Life Cycle Analysis Meets Cost Benefit Analysis (in the Paint Aisle)

Latex Paint • 343 million gallons sold each year • 64 million gallons left over • Average retail price: $20 per gallon • Cost to municipalities to manage as HHW: $6.00 - $13.50 per gallon (PSI 2004) • “Largest volume material collected by most household hazardous waste collection programs” (EPA 2007)

Latex Paint • Basic ingredients • Pigment – color, protection, filler • Resin (binder) – adhesion and film forming • Solvent – water • Co-solvents – alcohols, ethylene glycol • Additives • Thickeners • Fungicides and preservatives • Plasticizers • Defoamers

Latex Paint • Health and environmental concerns • Older paints may contain mercury or mercuric compounds (banned in 1990) or lead (banned in 1978) • Contain some solvents (ethylene glycol, glycol ethers) • Bactericides may contain formaldehyde • Toxic to fish (CA DFG 1990)

Latex Paint • Disposal options • Liquid – not accepted for landfill disposal • Dried and solidified – nonhazardous, accepted at most landfills • Consumer confusion • Water-based vs. oil-based? • OK to landfill? • How to dry or stabilize? • Result • Substantial quantities brought to HHW collections • Mixture of latex and oil-based paint

Stewardship Opportunities Dry and dispose as MSW Increasing Levels of Stewardship • Product reformulation • Eliminate health and environmental concerns • Consumer education • —Buy what you need • —Store properly • —Use it up Direct consumer re-use Collect and reuse/recycle —Send offsite for recycling —Onsite swap or blending • Return to retailer • —Send to recycler • —Send to manufacturer to be recycled • —Onsite blending, re-sale Collect and downcycle Landfill cover or fuel blending

Multistakeholder Process • Product Stewardship Institute • National Paint and Coatings Association • 4 paint recyclers • 7 states, 18 municipalities • U.S. EPA Paint Product Stewardship Initiative (PPSI) www.productstewardship.us

PPSI Projects • Education Projects • Project #1 Leftover Paint Management Education Pilot • Project #2 Public Education Survey and Analysis • Infrastructure Projects • Project #3 Paint Reuse Guidance Manual • Project #4 National Leftover Paint Infrastructure Model • Project #5 National Leftover Paint Infrastructure Cost Analysis • Market Projects • Project #6 Market Development Strategy • Project #7 Recycled Paint Marketing Guide for Distributors • Project #8 Recycled Paint Certification System • Other Projects • Project #9 Health, Safety, Environmental & Regulatory Issues • Project #10 Financing System Research and Model Development • Project #11 Lifecycle Balance of Costs and Benefits

LCA / CBA of Leftover Latex Paint • What are the lifecyclecosts, benefits, and environmental impacts of alternative leftover paint management schemes? • Do the benefits outweigh the costs?

LCA / CBA of Leftover Latex Paint • Scoping phase • Define alternative leftover paint management methods • Define relevant categories of costs and benefits • Define the “functional unit” and “reference flow” • Define the system boundaries • Identify potential data sources • Identify data quality criteria • Analysis phase • Data collection • LCA modeling • CBA modeling • LCA / CBA integration

LCA Definition • As defined in ISO 14040, a Life Cycle Assessment (LCA) is the “compilation and evaluation of the inputs, outputs and the potential environmental impacts of a product system throughout its life cycle.”

LCA Process Internationally accepted ISO standards (14040, 14044) provide the framework for conducting LCA: • Goal and Scope Definition • Life Cycle Inventory (LCI) • Life Cycle Impact Assessment (LCIA) • Interpretation of Results Goal and scope defined in the first phase of the paint project.

Life Cycle Inventory (LCI) • The inventory is the basic documentation process on which other parts of an LCA are built. • General concept is simple: LCI is a comprehensive input/output analysis or environmental accounting system • Inputs of materials and energy • Outputs of products and releases to air, water, and land

General Life Cycle Flow Diagram Energy Energy Energy Energy Energy Product Use or Consumption Final Disposition:Reuse, Recycle, Landfill, Incineration Raw Materials Acquisition Materials Manufacture Product Manufacture Wastes Wastes Wastes Wastes Reuse Recycle

Paint Management Methods

Life Cycle Impact Assessment (LCIA) • Inventory of inputs/outputs from the inventory phase are translated into potential impacts on human health and the environment using impact assessment (e.g., U.S. EPA TRACI) • Classification • Inventory flows grouped into relevant impact categories • Example: Global warming impact category includes carbon dioxide, methane, nitrous oxide, many other substances. • Characterization • Within each category, normalize to common reference substance • For global warming, each substance multiplied by its global warming potential relative to carbon dioxide

LCIA Limitations • LCI does not track all the detailed information needed to accurately assess actual impacts of emissions • Individual release locations, concentrations • Direct and indirect exposure routes (inhalation, ingestion, dermal), etc. • Aggregated life cycle emission quantities can represent very different scenarios with different impacts • LCIA is not a replacement for toxicology or risk assessment, but is a useful way to condense long list of inventory flows to a set of meaningful impact categories for directional comparisons

Value of LCA • Comprehensive life cycle systems approach ensures that important upstream and downstream impacts are not overlooked • Provides quantitative information needed to make informed decisions • Baseline for tracking & measuring effect of changes for an individual system • Comparisons of alternative designs, formulations, processes • Useful for internal and external purposes • Internal process improvements and designs • Informing customers, stakeholders, or general public • Policy decisions

Data Collection • Surveyed HHW programs and paint processors across the U.S. to gather data on: • Quantities of paint collected • Incoming paint transportation (dropoff at facility, collection events) • Sorting • Processing of usable paint (swap shop, on-site consolidation, sent off-site for reprocessing) • Disposal of unusable paint (bulking, landfill disposal of liquid and dried paint, etc.) • Recycling or disposal of paint containers • Additional information/input from workgroup and Infrastructure Report • Model collection and processing system specifications and costs

Global warming Acidification Human health – cancer Human health – non-cancer Human health – criteria air pollution Eutrophication Ozone depletion Ecotoxicity Smog Water use Fossil fuel use Total energy use Mineral extraction LCA Results

CBA • Account for all private and public costs and benefits associated with each method • Determine which can be monetized

CBA • Monetizing LCA impact categories

Life Cycle Analysis Meets Cost Benefit Analysis (in the Paint Aisle)

Life Cycle Analysis Meets Cost Benefit Analysis (in the Paint Aisle)

Presentation Transcript

Cost Benefit Analysis

Life Cycle Cost Analysis

Cost Benefit Analysis

Cost Benefit Analysis

Benefit/Cost Analysis

Benefit Cost Analysis

Cost-Benefit Analysis

Cost-Benefit Analysis

Cost / Benefit Analysis

Cost-Benefit Analysis

Life-Cycle Cost-Benefit Analysis of Infrastructures

Benefit-Cost Analysis

COST BENEFIT ANALYSIS

Life-Cycle Cost Analysis

Cost Benefit Analysis

Benefit Cost Analysis

COST BENEFIT ANALYSIS

Cost Benefit Analysis

Life-Cycle Cost-Benefit Analysis of Infrastructures

Benefit Cost Analysis