Environmental Life Cycle Assessment PSE 476/WPS 576/WPS Lecture 5: LCI

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Environmental Life Cycle Assessment PSE 476/WPS 576/WPS 595-005 Lecture 5: LCI Fall 2012 Richard A. Venditti Forest Biomaterials North Carolina State University Raleigh, NC 27695-8005 Richard_Venditti@ncsu.edu Go.ncsu.edu/venditti 1

Lecture 5: Life Cycle Inventory

Major Parts of a Life Cycle Assessment Goal and Scope Definition Inventory Analysis Interpretation Impact Assessment 3

Life Cycle Inventory Analysis(LCI): Life cycle inventory analysis: Phase of the life cycle assessment involving the compilation and the quantification of inputs and outputs for a product throughout its life cycle [ISO 14044:2006(E)] an inventory analysis means to construct a flow model of a technical system. the model is an incomplete mass and energy balance over the system environmentally indifferent flows such as diffuse heat and emissions of water vapour as a combustion product are not modelled HHGLCA, 2004. 4

Life Cycle Inventory Analysis(LCI): Three major activities: Construction of the flowsheet Data collection and documentation Calculation of the environmental loads in terms of the functional unit (i.e., the reference flow) Resource use Pollutant emissions 5 HHGLCA, 2004.

Construction of the flowsheet Should have all of the processes as in accordance with the Goal and Scope section Should clearly show significant interchanges between processes IF the entire system is extremely complicated then two flowsheets are suggested: A simplified flowsheet showing the major life cycle lumped parts of the system, suitable for communicating the major concepts of the system A detailed flowsheet that provides finer documentation of the system 6 HHGLCA, 2004.

Construction of the flowsheet 7 HHGLCA, 2004.

8 Construction of the flowsheet

Data Collection One of the most time consuming activities in a LCA Garbage in, garbage out Main data: Input flows of raw materials and energy Other inputs such as land use Product output flows Emissions to air, water and land and other environmental impacts (eg., noise) Data to describe processes Example: production efficiencies, equipment, useful lifetimes of products, travel distances Should also have data to guide allocation 9 HHGLCA, 2004.

Data Collection For each process in the flowsheet: Emissions to air Energy Raw materials Process Chemicals Process Product of interest Co-products Solid Waste Emissions to water 10 HHGLCA, 2004.

Data Collection Energy Raw materials Process Chemicals Process Emissions to air Product of interest Co-products Energy Raw materials Process Chemicals Process Emissions to air Product of interest Co-products Solid Waste Emissions to water Solid Waste Emissions to water Emissions to air Energy Raw materials Process Chemicals Process Product of interest Co-products Solid Waste Emissions to water 11 HHGLCA, 2004.

Data Sources Direct measurements Literature Internet Life cycle inventory databases Interviews 12 HHGLCA, 2004.

Data Sources Foreground system: processes that actions can be directly taken wrt the results of the LCA, direct measurements can often be taken (primary data) Background system: processes that actions can not be directly taken wrt the results of the LCA, often, external secondary data used Primary Data: direct measurement/description of variables Secondary Data: data sources from published or unpublished data articles, reports or studies Assumptions: used when primary or secondary data is not available. 13 HHGLCA, 2004.

Foreground and background data 14 HHGLCA, 2004.

Calculation Procedure: Calculation of all flows relative to the Functional Unit (reference flows) 1. Normalize data. For each process, scale each flow to a product or input of the process. 2. Calculate the flows that link the processes together. These flows should be based on the reference flow(s) that are determined to fulfill the functional unit. 3. Calculate the flows that pass the system boundary. These flows should be based on the reference flow(s) that are determined to fulfill the functional unit. 4. Sum up the resource use and emissions to the environment for the whole system 5. Document the calculations. 15 HHGLCA, 2004.

Basic Unit conversions: Convert 25 days into seconds: Convert 4 feet into meters (25.4 mm equals an inch) 16

Scientific Notation: 7x10 +4 = 7 x 10 x10 x10 x10 = 70,000 8.1x10-3 = 8.1 / (10x10x10) = 0.0081 8.1x10-3 = 8.1E-3 (alternate form to express this) 17

Calculation Procedure Example: It is of interest to do a partial life cycle inventory analysis on crayons (major raw materials, CO2 process emissions from burning heating oils, wastes and electricity use). Objective: find a hot spot amongst paper production, wax production and crayon production The functional unit of the study is a box of 20 crayons (also the reference flow, RF) It is known that a crayon has 6 grams of wax and 0.5 grams of paper crayon wrappers. Three processes will be within the system boundary (all others are not within the scope of this study): Dyed Wax Production Paper Production Crayon Production 18

Calculation Procedure Example: Data Collection Product specification. It is known that 1 crayon has 6 grams of wax and 0.5 grams of paper wrapper Crayon Production. It is determined that 10,000 crayons can be successfully wrapped in 24 hours. The electricity consumption is 100 kw-hr for a 24 hr period. CO 2 is emitted at a rate of 10 kg/hr from combustion processes used in the crayon production. There is a defective/disposed stream of crayons that is thrown away; it is 5% of the total successful crayon production. Dyed Wax Production. It is reported that the flow of wax produced in the dyeing process is 6,000 grams per hour. Electricity consumption is 20 kwhr per day. CO 2 is emitted at a rate of 5 kg/hr from combustion processes. 10% of the feed wax is wasted/disposed in the process. Paper Production. 200 metric tonne of paper are produced per day. The amount of electricity consumed is 4000 kw-hr per day. The amount of wood consumed per day is 600 metric tonne of wood. CO 2 is emitted at a rate of 12 kg/hr from combustion processes. Waste is produced at 10 metric tonnes per day rate. 19

Calculation Procedure Example: Normalization Crayon Production. It is determined that 10,000 crayons can be successfully wrapped in 24 hours. The electricity consumption is 100 kw-hr for a 24 hr period. CO 2 is emitted at a rate of 10 kg/hr from combustion processes used in the crayon production. There is a defective/disposed stream of crayons that is thrown away; it is 5% of the total successful crayon production. Normalize with respect to one crayon: 20

Calculation Procedure Example: Normalization Dyed Wax Production. It is reported that the flow of wax produced in the dyeing process is 6,000 grams per hour. Electricity consumption is 20 kw-hr per day. CO 2 is emitted at a rate of 5 kg/hr from combustion processes. 10% of the feed is wasted material that is disposed. Normalize with respect to a gram of wax produced: 21

Calculation Procedure Example: Normalization Paper Production. 200 metric tonne of paper are produced per day. The amount of electricity consumed is 4000 kw-hr per day. The amount of wood consumed per day is 600 metric tonne of wood per day. CO 2 is emitted at a rate of 12 kg/hr from combustion processes. Waste is produced at 10 metric tonnes per day rate. Normalize with respect to a metric tonne of paper produced: 22

Calculation Procedure: link flows Step 2. Calculate the flows that link the processes together. These flows should be based on the reference flow(s) that are determined to fulfill the functional unit. Reference flow: 20 crayons, each with 6 g wax, 0.5 g paper Dyed Wax Production Paper Production Link flow? Link flow? Crayon Production 23

Calculation Procedure: link flows Crayon Production 24

Calculation Procedure: STEP 3: Calculate the flows that pass the system boundary. These flows should be based on the reference flow(s) that are determined to fulfill the functional unit. Crayon Production: 25 HHGLCA, 2004.

Calculation Procedure: STEP 3: Calculate the flows that pass the system boundary. These flows should be based on the reference flow(s) that are determined to fulfill the functional unit. Dyed Wax Production: 26 HHGLCA, 2004.

Calculation Procedure: STEP 3: Calculate the flows that pass the system boundary. These flows should be based on the reference flow(s) that are determined to fulfill the functional unit. Paper Production: 27 HHGLCA, 2004.

Calculation Procedure: Step 4. Sum up the resource use and emissions to the environment for the whole system Paper Prod. Wax Dyeing Crayon Prod. Total Waste (g/rf).5 13.9 6.5 20.9 CO2 (kg/rf) Wood (g/rf) 31.5 0 0 31.5 Raw Wax (g/rf) Electricity (kwhr/rf) 0 140 0 140 (RF= reference flow, 20 crayons, 120 g dyed wax and 10 g paper) 28 Hot spots?

Calculation Procedure: Step 5. Document the calculations (for others). Show example calculations and data used. Explain boundary, allocation, and calculation methods. 29 HHGLCA, 2004.

Summary Life cycle inventory (LCI) analysis 3 Major Activities in LCI Foreground data Background data Primary data Secondary data 5 steps of a LCI Functional unit Reference flows Normalized Process Data Linking flows Hot spots 30

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