Life Cycle Assessment: Laying the Foundation for a Transparent Supply Chain

Shopping Bag Case Study

September 26, 2013

Dr. Anahita WilliamsonDirector

Kate WinnebeckLCACP, Senior EHS Specialist

New York State Pollution Prevention Institute at RIT

Life Cycle Assessment (LCA) is a technique used to quantify the environmental impact of a product from raw material acquisition through

end of life disposition (cradle-to-grave)

Life Cycle Assessment

Remanufacture

Recycle

Reuse

Waste Treatment

LCA Methodology• A Life Cycle Assessment is carried out in four distinct

phases: (ISO 14040, 14044)

– Step 1: Goal definition and scoping. Identify the LCA's purpose, the products of the study, and determine the boundaries. (what is and is not included in the study)

– Step 2: Life-cycle inventory. Quantify the energy and raw material inputs and environmental releases associated with each life cycle phase.

– Step 3: Impact analysis. Assess the impacts on human health and the environment.

– Step 4: Report results. Evaluate opportunities to reduce energy, material inputs, or environmental impacts at each stage of the product life-cycle.

Step 1: Goal Definition and Scoping

Define the goal:– Intended application of the study– Intended audience

Define the scope: – Identify the product system to be studied– Define the functional unit– Define the boundaries of the product system– Identify assumptions and limitations of the study– Select impact categories to be included

Today’s Example

• You own a grocery store and customers are starting to request that you sell reusable shopping bags. You are curious which type of bag has the lowest environmental impact. In order to quantify and compare the bag options, a streamlined LCA is performed.

• Goal: – Determine which grocery bag – single use paper,

single use plastic, reusable plastic, or reusable cotton – has the lowest environmental impact

Sustainability Victoria, Comparison of existing life cycle analysis of shopping bag alternatives, Apr07 .

Draw the System Boundaries

• Assumptions:– All bags are manufactured 100km from the customer– All bags travel 10km from the customer to the end of life– Half of paper bags are recycled at end of life, half go to landfill– Plastic & cotton bags go to landfill at end of life

1. As a group, draw the boundaries or process flow of the system

System Boundaries

50/50 to Landfill & Recycling

Cutting down trees

Paper bag

Transform trees into

paper

Form paper into bags

Packaging & Distribution

Use

Extracting petroleum

Single use & reusable plastic bag

Transform petroleum into plastic

Form plastic into bags

Packaging & Distribution

Use Landfill

Functional Unit

• The functional unit is a measure of the function of the studied system

– Provides a reference to which the inputs and outputs can be related

– Enables comparison of two essentially different systems

• Examples– The functional unit for a paint system may be defined as the unit

surface protected for 10 years– The functional unit for a printer may be defined as the number of

printed pages of an acceptable print quality – The functional unit for power generation systems may be defined

as 1kWh of electricity

The amount of shopping bags consumed by a household to carry 70 grocery items home from the supermarket each week for 52 weeks

Bag Type Single use plastic

Single use paper

Reusable plastic

Reusable cotton

Material HDPE Unbleached Kraft paper

Polypropylene Cotton

Mass per bag 7g 42.6g 95g 85g

Relative Capacity 1 0.9 1.1 1.1

Bags per Year 520 578 4.55 4.55

Mass bags per year

3640g 24622.8g 432.25g 386.75g

Functional Unit

Step 2: Life Cycle Inventory

• Highly data intensive

• Detailed mass & energy balances performed over life-cycle

• Advantages: measure data & define baseline metrics of life-cycle processes

• Challenges: Assumptions made when data unavailable

Outputs

Products

Air, Water and Solid Emissions

Inputs

Energy

Raw Materials

database

Inventory collected from multiple sources

Step 2: Life Cycle Inventory

Toner Life-cycle Inventory

Ref: A.Ahmadi,et.al, J.Clean.Prod., 2003

Ref: A.Ahmadi,et.al, J.Clean.Prod., 2003

Toner Life-cycle Inventory

Impact Assessment Results• Impact assessment converts the inventory into impact categories or

end points which details the human health and environmental effects.

High Density Polyethylene InventoryPeer reviewed datasets imbedded in softwareData has been collected by others and represents actual operations

Include:•Known inputs•Emissions to air•Emissions to water•Emissions to soil•Wastes and emissions sent to treatment

Ability to modify datasets based on your own data

2. As a group, choose one of the four bags and list the processes that are included in the inventory

Life Cycle Inventory

Reusable Plastic Bag  Polypropylene, granulate 432.25gExtrusion, plastic film 432.25gTransport, 100km manufacturing to customer 0.043225tkmTransport, municipal waste collection, 10km customer to landfill 0.0043225tkmDisposal, polypropylene, to sanitary landfill 432.25gReusable Cotton Bag  Textile, woven cotton, at plant 386.75gTransport, 100km manufacturing to customer 0.03867tkmTransport, municipal waste collection, 10km customer to landfill 0.0038675tkmDisposal, inert material, to sanitary landfill 386.75g

Single Use Plastic Bag  Polyethylene, HDPE, granulate 3640gStretch blow moulding 3640gTransport, 100km manufacturing to customer 0.364tkmTransport, municipal waste collection, 10km customer to landfill 0.0364tkmDisposal, polyethylene, 0.4% water, to sanitary landfill 3640gSingle Use Paper Bag  Kraft paper, unbleached, at plant 24622.8gProduction of paper bags 24622.8gTransport, 100km manufacturing to customer 2.4623tkmTransport, municipal waste collection, 10km customer to landfill/recycling 0.24623tkmDisposal, packaging paper, to sanitary landfill 12311gRecycling paper 12311g

Step 3: Impact Assessment

• Converts the inventory into impact categories or mid/end points which explain the environmental effect

• Impact categories may include: carcinogens, respiratory organics and inorganics, climate change, radiation, ozone layer, ecotoxicity, acidification/eutrophication, land use, minerals, fossil fuels

• Can apply weights to impact categories

Fate analysisExposure &

effect analysisDamage analysis

Normalization & weighting

Mineral & Fossil

Resources

Ecosystem Quality

Human Health

Impact Assessment

Total Normalized Impact

Normalized Environmental Impact

Step 4: Report Results

• Life cycle interpretation: findings of the inventory analysis or impact assessment are evaluated in relation to the goal and scope of the study to reach conclusions and recommendations

1. Identify significant issues

2. Evaluate results for completeness, consistency, and sensitivity of the data

3. Draw conclusions & make recommendations consistent with the goal & scope of the study

Interpreting Results

• Which bag has the lowest environmental impact? Which bag has the highest?

• Let’s consider cost of the bags.

• As the store owner, does the cost information change which type of bag you would promote? How? 

• As a shopper, does the cost information change which type of bag you would use? How?

Bag Type Single use plastic Single use paper Reusable plastic Reusable cotton

Material HDPE Unbleached Kraft paper Polypropylene Cotton

Cost per bag $0.02 $0.07 $1 $6

Cost per year $10.40 $40.46 $4.55 $27.30

Anahita Williamson, PhDDirectorEmail: anahita.williamson@rit.edu Phone: 585-475-4561

Kate Winnebeck, LCACPSr. Environmental Health & Safety SpecialistEmail: kate.winnebeck@rit.edu Phone: 585-475-5390

New York State Pollution Prevention Institutehttp://www.nysp2i.rit.edu