Life Cycle Assessment on Personal Computer
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Transcript of Life Cycle Assessment on Personal Computer
SUSTAINABLE MANUFACTURING (CDC10503)
SEMESTER 2 2014/2015
LIFE CYCLE ASSESSEMENT OF
PERSONAL COMPUTER
NAME MATRIX
MASNADIA BT MASHURI HD140060
MOHAMED ABDIRAHMAN IBRAHIM HD140076
MUHAMMAD ZULHILMI BIN HASHIM HD140045
SHAMY NAZREIN BIN MD YAHAYA HD140066
LECTURER’S NAME : ENCIK YUSSNI BIN HASHIM
LCA STEP
LIFE CYCLE ASSESSMENT
STEP 1: GOAL & SCOPE
STEP 2: INVENTORY
ANALYSIS
STEP 3: IMPACT
ASSESSMENT
STEP 4: IMPROVEMENT
ASSESSMENT
INTRODUCTION
STEP 1 GOAL & SCOPE
STEP 1 : GOAL & SCOPE
GOAL/PURPOSE :
The main purpose of this project is to investigate the life cycle
environmental impact of PCs and to determine the desirable or
feasible recycle rate of an end-of-life PC.
SCOPE :
Defined by the system boundaries, the functional unit and and
input/output product (PC).
SYSTEM BOUNDRIES
Figure 1.1: The boundaries of the system of the PC assembled, used and disposed
FUNCTIONAL UNIT
The functional unit of the PC is defined as follows:
Spatial context: a personal computer made, used, and disposed of in Korea.
Temporal context: the life span of a PC, as suggested by authorities 2, is assumed to be four years.
Technology: a desktop personal computer with Intel Pentium IV 1.7 GHz, 128MB RAM, hard disk drive (HDD), CD-ROM drive,2 GB hard disk, power supply, 3.5” floppy disk drive (FDD), modem, and keyboard manufactured in Korea in 2001.
INPUT & OUTPUT
Table 1.1 briefly describes each of the stages for a computer
product system. The inputs (e.g., resources and energy) and
outputs (e.g., product and waste within each life cycle stage,
as well as the interaction between each stage (e.g.,
transportation) are evaluated to determine the environmental
impacts.
Table 1.1: input &
output of ife cycle stage
of the PC.
STEP 2 INVENTORY ANALYSIS
STEP 2 : INVENTORY ANALYSIS
Figure 2.1: Life cycle Inventory for personal computer.
Pre-Manufacturing
Pre-Manufacturing
• raw material
• component
• part production
Main Board
• PCB
• CPU
• FAN
Packaging
• Manual
• Box
• Cushion
Cards
• Modem
• Sound
• Graphic
• Memory
Drivers
• FDD
• HDD
• CD-ROM
• Power supply
Cases
• USB ports
• FAN
• Wire
Figure 2.2 : Pre-manufacturing flow chart.
PC Manufacturing
Manufacturing
(Assembly)
~ Electricity
Electrical components
Packaging the PC
Figure 2.3 : PC manufacturing flow chart.
Transportation
Transportation
~ GasolineManufacturer Retailers
Figure 2.4: Transportation flow chart.
PC Use
PC use
~ Electricity
Home PC
operate for 10.2 hours/week
Office PC
operate for 12.9 hours/week
Figure 2.5: PC use flow chart.
Disposal or End-Of-Life PC
Disposal/
End-of-lifeLandfill Incineration
Recycling
•Refining
•Pre-manipulation
•Disassembling
•Collecting
Figure 2.6: End life PC flow chart.
ASSUMPTIONS AND LIMITATIONS
When site-specific data of sub-components or parts was not available, we adopted other similar databases from SimaPro4.0 and the Korean national databases.
All data on electricity was obtained from the Korean national database.
This study did not consider yield and scraps that may have emerged from electrical parts and PC manufacturing.
Assumed that components and parts as an elementary flow, where data on the input and output of materials was inaccessible.
Assumption of current recycling rate of waste PCs was estimated based on the recent study.
All the components and parts were included in this study except a CPU (central processing unit) embedded in the main board. Material data of small electrical parts are included, however process data of parts on the printed circuit boards such as resistors and capacitors were excluded due to inaccessibility to the data.
STEP 3 IMPACT ASSESSMENT
STEP 3 : IMPACT ASSESSMENT
The impact assessment focuses on characterizing the
type and severity of environmental impact more
specifically.
Classification and characterization following ISO14042
guidelines were applied to analyze the potential
environmental impact of input and output from the LCI.
ISO 14042 IS0 (the International Organization for Standardization)
is a worldwide federation of national standards bodies (IS0 member bodies).
The work of preparing International Standards is normally carried out through IS0 technical committees.
International organizations, governmental and non-governmental. in liaison with ISO, also take part in the work.
IS0 collaborates closely with the International Electrotechnical Commission (IEC) on all matters of electrotechnical standardization.
International Standard IS0 14042 was prepared by Technical Committee lSO/TC 207. Environmental management, Subcommittee SC 5, Life cycle assessment.
Impact Categories for Personal
Computer
Impact categories adopted includes:
The ecological effects of abiotic depletion (ADP)
Global warming (GWP)
Ecotoxicity (ET)
Human toxicity (HT)
Acidification (Acid)
Depletion of the stratospheric zone (ODP)
Photooxidant formation (POCP)
Eutrophication (Eut)
Environmental Impact Assessment for
Personal Computer
Figure 3.1:
Environmental
impact
assessment result
for a personal
computer
1) Pre-manufacturing Stage
This stage was found be the largest contributor to all
environmental impact categories, except for human
toxicity potential.
The manufacturing of small electric parts and several
electronic components during this stage requires a
substantial amount of materials and energy, and emits
substantial quantities of air pollution, waste water, and solid
wastes.
Figure 3.2: Pre manufacturing stage process
2) Manufacturing and Distribution
stages
Most environmental impact
categories were not greatly
influenced by processes during
these two stages.
PC manufacturing is composed
of two simple processes:
assembly and packaging.
These activities require little
electricity, and emit little air
pollutants, wastewater, or solid
waste.
3) Use Stage
From the results of the LCA, we understood the use stage to be
the greatest contributor to environmental impact after the
pre-manufacturing stage.
In this study, we considered two types of consumer behaviors:
home type and office type.
Office type PC use was found to have at least 50% more influence
on environmental impact potential than home type PC use.
4) Disposal Stage
This stage was found to be a major factor in human
toxicity potential.
This stage also greatly contributed to the ecotoxicity
potential, second only to the pre-manufacturing stage.
Life cycle stage Environmental Impact Design Guidelines
Related
Environmental
Management
Pre-Manufacturing
Many small electricity parts
PCB in the main board
Power Supply (Pb-solder, NO2,
CO emission)
ABS in plastic chassis
PVC parts (waste water)
Diminishing product size
Reducing hazardous materials
in parts and materials
Lead-free soldering PCB
Green
procurement
Production Low Impact Clean
production
Transportation Low Impact
Use
Electricity consumption (fossil
fuel)
Reducing power consumption Design for the
environment
Disposal
Collection and transportation
(fossil fuel)
Refinery (Nitric, sulfuric, and
hydrochloric acid)
Enhancing recycling Product
recovery
Design for
recycling
STEP 4 IMPROVEMENTANALYSIS
STEP 4 : IMPROVEMENT ASSESSMENT
Improvement assessment will be considering the pre-
manufacturing stage was a significant stage for all of the
environmental parameters, with the exception of human
toxicity potential. For acidification, global warming, ozone
depletion, and POCP, the environmental impacts of this stage
were about 90% of the total impact of the PC.
We can improve PC production primarily consists of
assembly and packaging processes.
Based on the results of the LCA for a personal computer, we
can improve the several methods were found to reduce the
environmental burden of PC products. Although there are
several guidelines pertaining to life cycle stages, PC
manufacturers might not, for commercial reasons, be able to
consider all the recommendations.
With these techniques and the active participation of process
technologists and designers, LCA might become an analytic
tool for eco-design supporting a continuous environmental
improvement of products.
ENVIRONMENTAL IMPROVEMENT
ASSESSMENT RESULT FOR A PERSONAL
COMPUTER
LCA RESULTS OF IMPROVEMENT
ASSESSMENT
The results of LCA do not represent rigorous and precise data, i.e. Difficulty in the collection of data, lack of detailed information sources, and data quality affected by uncertainty, mostly due to the lack of the knowledge about the actual value of a quantity, and by variability due to the heterogeneity of values and entailed into processes.
The results of the sensitivity analysis allow stating that every assessed eco-profile is differently influenced by the uncertainty study
CONCLUSION The findings from this research have indicated that the energy used
for powering the PC contributed significantly to the examined impact categories, followed by the manufacturing of that product.
Most of that burden is observed in three impact categories: fossil fuels, respiratory inorganics and climate change, that could be attributed to the coal, lignite and natural gas extraction and then their combustion to produce electricity.
Therefore, the energy efficiency of the PC (which depends on the manufacturer), adoption of a responsible attitude of the PC user (application of energy saving mode) and heading for more renewable sources in electricity production should be highly promoted.
REFERENCES The Korean Ministry of Environment (MOE) (2002): Life cycle
inventory of products –Water, industrial water, raw materials and chemical components: Domestic area
Korea Accreditation Board and the Korean Ministry of Commerce, Industry and Energy (2003): Environmental National Standard Database
Korea National Statistical Office (2001): A research on the actual information condition in Korea
Korean Association of Electrical and Electronics Industry for the Environment (2001): A study on the recovery and recycling of waste of electrical and electronic equipment (in Korean)
Pre (1999): SIMAPRO 4.0. Pre Consultants B.V. Plotterweg 12, 3821 BB Amersfoort, The Netherlands