1. Industry Awareness
Industry Action
Biodegradable/Compostable Plastics
Bioplastics Packaging Materials: Advantages & Disadvantages
Summary of Initial Findings
VII Addressing Ecological Impacts of Plastics Manufacturing
2. Image surrounded by negative media
Lack of upstream or downstream control
Competitors have established some standards (ex. Forest Stewardship Council)
Basic harmful effects (toxicity/life cycle) accepted
Understanding of need to optimize materials and energy inputs through waste minimization and design
Note trends and fads (ex. degradable plastics)
Address attacks & misinformation
Plastic bags are made out of polyethylene. Polyethylene is made of ethylene. In the United States, ethylene is made of ethane which is extracted from natural gas. As a result, plastic bags manufactured in the United States are not made out of oil. http://savetheplasticbag.com/
Photo Credits:
Remember the archetypal turtle shot: http://sackingtheenvironment.org/plastic.aspx
http://tashian.com/carl/photos/alpine-stream.3.jpg
http://wildgreenyonder.files.wordpress.com/2007/02/composting-bottle.jpg
http://images.google.com/imgres?imgurl=http://www.advplastics.co.za/adv_plastics_factory3.gif&imgrefurl=http://www.advplastics.co.za/production_facilities.html&h=312&w=410&sz=76&hl=en&start=2&um=1&usg=__0cdw4Gc_RfPeBoc3DSDlsrzaq-o=&tbnid=5EI8GPRmzWTgWM:&tbnh=95&tbnw=125&prev=/images%3Fq%3Dmanufacture%2Bplastics%26um%3D1%26hl%3Den%26client%3Dfirefox-a%26rls%3Dorg.mozilla:en-US:official%26sa%3DGPhoto Credits:
Remember the archetypal turtle shot: http://sackingtheenvironment.org/plastic.aspx
http://tashian.com/carl/photos/alpine-stream.3.jpg
http://wildgreenyonder.files.wordpress.com/2007/02/composting-bottle.jpg
http://images.google.com/imgres?imgurl=http://www.advplastics.co.za/adv_plastics_factory3.gif&imgrefurl=http://www.advplastics.co.za/production_facilities.html&h=312&w=410&sz=76&hl=en&start=2&um=1&usg=__0cdw4Gc_RfPeBoc3DSDlsrzaq-o=&tbnid=5EI8GPRmzWTgWM:&tbnh=95&tbnw=125&prev=/images%3Fq%3Dmanufacture%2Bplastics%26um%3D1%26hl%3Den%26client%3Dfirefox-a%26rls%3Dorg.mozilla:en-US:official%26sa%3DG
3. Industry Action Apply Standards
Environmentally Preferred Rating (EPR)
Voluntary
Check abidance of Health and safety regulations
Implement Lean Manufacturing
Minimize waste of inputs (energy, labor, materials)
Diagram credits: After the Laboratory for Manufacturing and Sustainability, Sustainable Manfuacturing Spring 2008, Lecture Side 1, originally after F. Jovane, et al. Present and Future of Flexible Automation: Towards New Paradigms, CIRP Annals, 52, 2, 2003, 543.
This section needs to be confirmed and added to by industry and other sources.
EPR - http://www.epraccredited.org/
(Well speak more about bioplastics later)
Diagram credits: After the Laboratory for Manufacturing and Sustainability, Sustainable Manfuacturing Spring 2008, Lecture Side 1, originally after F. Jovane, et al. Present and Future of Flexible Automation: Towards New Paradigms, CIRP Annals, 52, 2, 2003, 543.
This section needs to be confirmed and added to by industry and other sources.
EPR - http://www.epraccredited.org/
(Well speak more about bioplastics later)
4. Biopolymers
Like other resins, biopolymers can gain a variety of certifications or regulatory approval. Natureworks LLC notes the availability of the following:
Food Contact Approval
Fiber Designation
In 2002 the FTC designated the biopolymer PLA as a generic fiber name for synthetic fiber manufactured from a polylactic acid or poly lactate, also called polylactide in Europe.
Compostability
Non-GM Certified
Kosher
Yet, in the US, the regulatory environment and available infrastructure as a whole, remains confusing with regard to these new products.
Biomass can be made into biopolymers (equivalent to renewable polymers)
For example:
Sugar beet > Glyconic acid > Polyglonic acid
Starch > (fermentation) > Lactic acid > Polylactic acid (PLA)
Biomass > (fermentation) > Bioethanol > Ethene > Polyethylene
Many companies have made packaging from these materials
Diagram from http://www.natureworksllc.com/
http://www.compostingcouncil.org/index.cfm.
Bpi
Comstock, K., D. Farrell, Christina Godwin, Yun Xi (3 June 2004). Food packaging of the future. http://depts.washington.edu/poeweb/gradprograms/envmgt/2004symposium/GreenPackagingReport.pdf
Picture credits:
http://www.nature.com/nbt/journal/v23/n6/images/nbt0605-638-I1.jpg
http://www.haringey.gov.uk/compostable_logo.gif
Diagram from http://www.natureworksllc.com/
http://www.compostingcouncil.org/index.cfm.
Bpi
Comstock, K., D. Farrell, Christina Godwin, Yun Xi (3 June 2004). Food packaging of the future. http://depts.washington.edu/poeweb/gradprograms/envmgt/2004symposium/GreenPackagingReport.pdf
Picture credits:
http://www.nature.com/nbt/journal/v23/n6/images/nbt0605-638-I1.jpg
http://www.haringey.gov.uk/compostable_logo.gif
5. A note about Degradable, Biobased, Biodegradable, & Compostable Plastics
6. Bioplastics uptake Bioplastics are an eco-based alternative to traditional plastics. However, many questions remain over their environmental impact and how best to implement them. While worthy of further investigation, bioplastics are subject to the following criticisms:
Continues to use petroleum as an energy and materials source (fertilisers, pesticides, fuel for farm equipment and transport, and for processing)
environmental impact for some products has actually been shown to be worse than traditional plastics
May impede efforts to recycle traditional plastics Sources:
0.17% bioplastics:
Bioplastic. (2008, Aug 25). In Wikipedia, the free encyclopedia. Retrieved August 25, 2008, from http://en.wikipedia.org/wiki/Biodegradable_Plastic;
American Chemical Society. August 29,2007. Plastics from the bread basket. Environmental Science & Technology Online. Retrieved August 25, 2008, from http://pubs.acs.org/subscribe/journals/esthag-w/2007/aug/tech/ts_plastics.html
Types of degradable polymers table: James, K. and T. Grant (2005). LCA [Life-cycle assessment] of degradable plastic bags.
Centre for Design at RMIT University, Australia.
Sources:
0.17% bioplastics:
Bioplastic. (2008, Aug 25). In Wikipedia, the free encyclopedia. Retrieved August 25, 2008, from http://en.wikipedia.org/wiki/Biodegradable_Plastic;
American Chemical Society. August 29,2007. Plastics from the bread basket. Environmental Science & Technology Online. Retrieved August 25, 2008, from http://pubs.acs.org/subscribe/journals/esthag-w/2007/aug/tech/ts_plastics.html
Types of degradable polymers table: James, K. and T. Grant (2005). LCA [Life-cycle assessment] of degradable plastic bags.
Centre for Design at RMIT University, Australia.
7. Bioplastics Packaging Materials WRAP Section 5 Material considerations. The Guide to Evolving Packaging Design.
http://www.wrap.org.uk/retail/the_guide_to_evolving_packaging_design/material_considerations/index.html
Example Materials:
Polylactic Acid (PLA)
Polyhydroxyalkanoate (PHA)
Bagasse (from sugar cane)
Poly-hydroxybutyrate-co-hydroxyvalerate
(PHBV)
Thermoplastic Starch Materials (TSM)
Polyglycolide Acid (PGA)
Polycaprolactone (PCL).
UKs Composting Association (European standard EN13432) sets the requirements for biodegradable and compostable packaging in and out of industrial settings.
http://www.scienceimage.csiro.au/index.cfm?event=site.image.thumbnail&id=3350&viewfile=f&divid=HR
http://www.packaging-int.com/images/companies/2017/veriplastimage2.jpg
http://www.amazon.com/Yellow-Biodegradable-Packing-Peanuts-12BNUTS/dp/B000ZJS9T0/ref=sr_1_13?ie=UTF8&s=office-products&qid=1200526134&sr=1-13
WRAP Section 5 Material considerations. The Guide to Evolving Packaging Design.
http://www.wrap.org.uk/retail/the_guide_to_evolving_packaging_design/material_considerations/index.html
Example Materials:
Polylactic Acid (PLA)
Polyhydroxyalkanoate (PHA)
Bagasse (from sugar cane)
Poly-hydroxybutyrate-co-hydroxyvalerate
(PHBV)
Thermoplastic Starch Materials (TSM)
Polyglycolide Acid (PGA)
Polycaprolactone (PCL).
UKs Composting Association (European standard EN13432) sets the requirements for biodegradable and compostable packaging in and out of industrial settings.
http://www.scienceimage.csiro.au/index.cfm?event=site.image.thumbnail&id=3350&viewfile=f&divid=HR
http://www.packaging-int.com/images/companies/2017/veriplastimage2.jpg
http://www.amazon.com/Yellow-Biodegradable-Packing-Peanuts-12BNUTS/dp/B000ZJS9T0/ref=sr_1_13?ie=UTF8&s=office-products&qid=1200526134&sr=1-13
8. Summary of Initial Findings Issue of upstream and downstream impacts of lifecycle
Addressing concerns of source, toxicity and EOL
Slow to implement infrastructure
Limited control to ensuring proper EOL disposal
Need for redesign to optimize product in environment of constraints
Lack of enforceable best practices/standards
Bioplastics still emerging
research on impacts needed
potential scope unknown
it is unknown if trad. plastics manufactures would be willing to convert to this field
How are other packaging manufactures addressing these issues? Do they concentrate on the same concerns? Go to a factory, seems like efficient factory, decent work environment, fairly satisfied employees, and doing well in business (EEE)
But there are some major issues/ concerns not being sufficiently addressed
Look at others to see if they are addressing these issuesGo to a factory, seems like efficient factory, decent work environment, fairly satisfied employees, and doing well in business (EEE)
But there are some major issues/ concerns not being sufficiently addressed
Look at others to see if they are addressing these issues
9. Glass
Metal
Natural Fibers (not addressed at present)
Wood & Wood Derivatives
Composites
Adhesives, Labels, Ink & Pigment
VIII Addressing the Ecological Impacts of Other Packaging Manufacturing Sectors
10. Advantages
Use
Material properties lend the substance a wide variety of uses
Material is inert, strong, durable, will not leach chemicals, usable at high temperatures, a good barrier for moisture and gas
EOL
Can be recycled with little loss of material integrity while using a high percentage of recycled content
Sterilization for reuse is easy and fast
Implementation
Existing recycling and some reuse infrastructure
Disadvantages
Source
Expensive raw materials (silica, sand, simple materials)
Manufacturing
Energy intensive processes
Distribution
Heavy in comparison to other packaging materials
EOL
Recycling is energy intensive
Difficult to recycle mixed and dark colored glass
WRAP Section 5 Material considerations. The Guide to Evolving Packaging Design. p 2-5 http://www.wrap.org.uk/retail/the_guide_to_evolving_packaging_design/material_considerations/index.html
This resource focuses on practical next step action, but not on remaking the system.
American Chemistry Council Life Cycle Study Sheds Light on Environmental Performance of Everyday Foodservice Packaging Products http://www.americanchemistry.com/s_plastics/sec_pfpg.asp?CID=1439&DID=5231
http://www.wrap.org.uk/retail/materials/glassrite.html
�British Glass http://www.britglass.org.uk/Files/LocalAuthorities/BGEnviroReport.pdf
British Glass: www.britglass.org.uk
Glass Packaging Institute: www.gpi.org
Glass Technology Services (GTS): www.glass-ts.com
Photo Credits:
http://www.sgcontainers.com/index.nsf/BD3B2B123173B60D85256B6A000DD522/$File/group.jpg
http://www.wrap.org.uk/images/r_col/10801_ClearJars.jpg
�
WRAP Section 5 Material considerations. The Guide to Evolving Packaging Design. p 2-5 http://www.wrap.org.uk/retail/the_guide_to_evolving_packaging_design/material_considerations/index.html
This resource focuses on practical next step action, but not on remaking the system.
American Chemistry Council Life Cycle Study Sheds Light on Environmental Performance of Everyday Foodservice Packaging Products http://www.americanchemistry.com/s_plastics/sec_pfpg.asp?CID=1439&DID=5231
http://www.wrap.org.uk/retail/materials/glassrite.html
11. Metal* Packaging Strengths
Use
Strong, long-lasting
high strength-to-weight ratio
EOL
recycling without loss of quality and able to have a high percentage of recycled content
Magnetic extraction allows steel to be easily separaed
Implementation
recycling infrastructure; Weaknesses
Source
Energy intensive
Dangerous proffession? lookupmining
Pollution??
Coke or other forms of carbon (CH4, recycled
organic products) used to reduce ores result in
CO2 emissions
emissions of PFCs from aluminum ore
processing
Manufacturing
Design is limited??
Energy intensive
Coating causes Environmental impacts of coating, but also, water-based paints diffiucult
increased lifetimes of ferrous components
Use
Normally limited to one use
Heavier than some alternatives
EOL
Coatings and alloys can cause recycling difficulties
* (primarily steel and aluminum) - Some steel cans have a very thin layer of tin that protects the surface of the can,
WRAP Section 5 Material considerations. The Guide to Evolving Packaging Design.
Notes many of the design benefits and weaknesses of metal packaging. http://www.wrap.org.uk/retail/the_guide_to_evolving_packaging_design/material_considerations/index.html
Packaging manufacturers have recently been attempting to highlight the benefits associated with their manufacturing process.
Steel Towards a Closed Steel Eco Cycle http://www.mistra.org/mistra/english/research/activeprogrammes/towardsaclosedsteelecocycle.4.1eeb37210182cfc0d680007316.html
Steel just startting to launch
30.05.2008Steel for packaging industry launches sustainability positioning in Europe �APEAL launched its sustainability positioning in Brussels on 28th May 2008, showcasing its unique position as an enabler for a sustainable 21st century. �
Steelforpackaging.org
BPA issues http://www.metal-pack.org/docs/pdf/00024936.PDF
http://www.apeal.org/emc.asp?pageId=192
��APEAL Association of European Producers of Steel for Packaging
http://www.apeal.org/emc.asp?pageId=212
New Packaging Concept Challenges Glass and Cans By Pernille Moulvad, Marketing Team Leader, Faerch Plast A/S
Photo credits:
http://www.spectrumpackaging.com.au/files/W-Tin_Group-Shot.jpg
http://www.qinetiq.com/home/newsroom/news_releases_homepage/2006/4th_quarter/Crown_teams_up_with_QinetiQ_to_resolve_challenges_of_RFID_on_metal_packaging.Par.0001.File.tmp/Metal%20packaging%20image.JPG
http://images.google.com/imgres?imgurl=http://blogs.citypages.com/blotter/images/aluminumCans.jpg&imgrefurl=http://blogs.citypages.com/blotter/2006/05/the_rise_of_the_can_thieves.php&h=200&w=200&sz=10&hl=en&start=2&tbnid=aiIJP8OiNjOXjM:&tbnh=104&tbnw=104&prev=/images%3Fq%3Daluminum%2Bcans%26gbv%3D2%26hl%3Den%26sa%3DG
http://www.cclcontainermedia.com/images/products/BodyShapes.jpg
North American Metal Packaging Alliance, Inc. (NAMPA)
http://www.metal-pack.org/
http://www.area603.com/resserver.php?blogId=6&resource=life%20cycle%20of%20aluminum%20can.jpg&mode=medium
EU Aluminium Association POSITION PAPER 18.04.2008
Carbon footprint: a reliable environmental indicator? http://eaa.net/files/eaa/documentslive/41/124_EAA%20position%20paper-%20carbon%20footprint.pdf
Useful but Broaden the scope to avoid trade-offs
Apply an already standardized approach
Compare products which serve the same purpose
Dont forget the use phase and the recycling benefits
Establish robust life-cycle based methodology
International aluminum Association Carbon Footprint Guidance Document
Position Paperhttp://www.world-aluminium.org/cache/fl0000169.pdf
Pitfalls make it seem like aluminum isnt a great packaging choice as with ISO 1400 standard
Disregarding different mass ie. ISO 14044 standard, means that the Carbon Footprint of 1 kg
aluminium cans has to be compared with the Carbon Footprint of 25 kg of glass bottles.
Disregarding end-of-life recycling
The term "supply chain" which is often used in the literature instead of "life cycle" is misleading,
as it invites to disregard recycling.
Disregarding the use stage
Packaging sector
In a comparative study, the functional unit (e.g. a can with a can of the same volume and not 1kg of cans
with 1kg of cans) must be identical, especially the quantity of the product in the package, the expected
life-time, the aroma conservation and the spoilage rate of the product in the package.
In the incineration process of packaging waste, energy is generated by the combustion of the aluminium
foil, but, contrary to paper and plastics, no CO2 is produced.
The positive impacts resulting from the transportation of the packaging material including the distribution
of the packaged good and, the sealing properties (for conservation of product, avoidance of spoilage and
tampering), have to be taken into account. Usually aluminium packaging systems have a lower mass
than those from competing materials and provide a better protection for the packaged goods.
�
Coming
Aluminum recycling and processing for energy conservation and sustainability /John A.S. Green, editor.PublisherMaterials Park, Ohio :ASM International,c2007.Descriptionx, 267 p. :ill. ;27 cm.NoteIncludes bibliographical references and index.LCCN2007932444ISBN0871708590 9780871708595LanguageEnglish
http://www.area603.com/resserver.php?blogId=6&resource=life%20cycle%20of%20aluminum%20can.jpg&mode=medium
EU Aluminium Association POSITION PAPER 18.04.2008
Carbon footprint: a reliable environmental indicator? http://eaa.net/files/eaa/documentslive/41/124_EAA%20position%20paper-%20carbon%20footprint.pdf
Useful but Broaden the scope to avoid trade-offs
Apply an already standardized approach
Compare products which serve the same purpose
Dont forget the use phase and the recycling benefits
Establish robust life-cycle based methodology
International aluminum Association Carbon Footprint Guidance Document
Position Paperhttp://www.world-aluminium.org/cache/fl0000169.pdf
Pitfalls make it seem like aluminum isnt a great packaging choice as with ISO 1400 standard
Disregarding different mass ie. ISO 14044 standard, means that the Carbon Footprint of 1 kg
aluminium cans has to be compared with the Carbon Footprint of 25 kg of glass bottles.
Disregarding end-of-life recycling
The term "supply chain" which is often used in the literature instead of "life cycle" is misleading,
as it invites to disregard recycling.
Disregarding the use stage
Packaging sector
In a comparative study, the functional unit (e.g. a can with a can of the same volume and not 1kg of cans
with 1kg of cans) must be identical, especially the quantity of the product in the package, the expected
life-time, the aroma conservation and the spoilage rate of the product in the package.
In the incineration process of packaging waste, energy is generated by the combustion of the aluminium
foil, but, contrary to paper and plastics, no CO2 is produced.
The positive impacts resulting from the transportation of the packaging material including the distribution
of the packaged good and, the sealing properties (for conservation of product, avoidance of spoilage and
tampering), have to be taken into account. Usually aluminium packaging systems have a lower mass
than those from competing materials and provide a better protection for the packaged goods.
�Aluminum recycling and processing for energy conservation and sustainability /John A.S. Green, editor.PublisherMaterials Park, Ohio :ASM International,c2007.Descriptionx, 267 p. :ill. ;27 cm.NoteIncludes bibliographical references and index.LCCN2007932444ISBN0871708590 9780871708595LanguageEnglish
* (primarily steel and aluminum) - Some steel cans have a very thin layer of tin that protects the surface of the can,
WRAP Section 5 Material considerations. The Guide to Evolving Packaging Design.
Notes many of the design benefits and weaknesses of metal packaging. http://www.wrap.org.uk/retail/the_guide_to_evolving_packaging_design/material_considerations/index.html
Packaging manufacturers have recently been attempting to highlight the benefits associated with their manufacturing process.
Steel Towards a Closed Steel Eco Cycle http://www.mistra.org/mistra/english/research/activeprogrammes/towardsaclosedsteelecocycle.4.1eeb37210182cfc0d680007316.html
Steel just startting to launch
30.05.2008Steel for packaging industry launches sustainability positioning in Europe APEAL launched its sustainability positioning in Brussels on 28th May 2008, showcasing its unique position as an enabler for a sustainable 21st century.
Steelforpackaging.org
BPA issues http://www.metal-pack.org/docs/pdf/00024936.PDF
http://www.apeal.org/emc.asp?pageId=192
12. Strengths
Source
Renewable material, with potential certificates of sustainability
Distribution
Lightweight
Use
Flexible
inexpensive
EOL
Recyclable
Biodegradable
Implementation
Recycling in place
Certificates of sustainability aid sourcing Weakness
Source
Renewable material, with potential certificates of sustainability
Manufacturing
Potential bleach and chlorine use
Lots of water use
Use
Not as strong a barrier as alternatives
EOL
Recycling is limited because fibers break down
Developments in Wood and Packaging Materials Life Cycle Inventories in Ecoinvent (9 pp)
Roland Hischier; Hans-Jrg Althaus; Frank Werner Corresponding author:: Roland Hischier, EMPA, Swiss Federal Laboratories for Materials Testing and Research, LCA unit, Lerchenfeldstrasse 5, CH-9014 St. Gallen (roland.hischier@empa.ch)
DOI: http://dx.doi.org/10.1065/lca2004.11.181.6
�Environmental Paper Network The State of the Paper Industry. http://www.environmentalpaper.org/stateofthepaperindustry/confirm.htm
WRAP Section 5 Material considerations. The Guide to Evolving Packaging Design. P 16-18
http://www.wrap.org.uk/retail/the_guide_to_evolving_packaging_design/material_considerations/index.html
Picture Credits:
http://www.drevoobal.cz/karton/karton1.gif
http://www.gogreencharleston.org/images/paperboard_collection.jpg
Developments in Wood and Packaging Materials Life Cycle Inventories in Ecoinvent (9 pp)
Roland Hischier; Hans-Jrg Althaus; Frank Werner Corresponding author:: Roland Hischier, EMPA, Swiss Federal Laboratories for Materials Testing and Research, LCA unit, Lerchenfeldstrasse 5, CH-9014 St. Gallen (roland.hischier@empa.ch)
DOI: http://dx.doi.org/10.1065/lca2004.11.181.6
13. Composite Packaging Strengths
Source
Renewable material, with potential certificates of sustainability
Manufacturing
Customizable
Distribution
Lightweight
Use
Wide variety, strong barrier properties Weakness
(Many depend on composites being used)
Use
Not as strong a barrier as alternatives
EOL
Little use of recycled material
Lack of recycling, reuse or composting abilities
Implementation
Lack of reuse, recycling or compostable infrastructure
WRAP WRAP Section 5 Material considerations. The Guide to Evolving Packaging Design. P 21
http://www.wrap.org.uk/retail/the_guide_to_evolving_packaging_design/material_considerations/index.html
Composite packaging producers:
www.tetrapak.com
www.elopak.com
www.sig.biz
Photo credit:
http://www.tetrapak.com/products_and_services/packages/pages/default.aspxWRAP WRAP Section 5 Material considerations. The Guide to Evolving Packaging Design. P 21
http://www.wrap.org.uk/retail/the_guide_to_evolving_packaging_design/material_considerations/index.html
Composite packaging producers:
www.tetrapak.com
www.elopak.com
www.sig.biz
Photo credit:
http://www.tetrapak.com/products_and_services/packages/pages/default.aspx
14. Adhesives and Labels & Ink and Pigment
Adhesives and Labels
Difficult to remove for reuse or recycling
Inks & Pigment
Ultraviolet-curable inks
Minimal odour
Good adhesion
Volatile organic compound (VOC) emissions reduced
Requires more energy to dry and slower printing
Water-based inks
Volatile organic compound (VOC) emissions reduced
Requires more energy to dry and slower printing
Can be harder to remove for recycling
Not good on non-absorbent plastic surfaces WRAP Section 5 Material considerations. The Guide to Evolving Packaging Design. P 22-23
http://www.wrap.org.uk/retail/the_guide_to_evolving_packaging_design/material_considerations/index.html
Photo source:
http://www.stickers-labels.co.uk/food-packaging-labels-450.jpg
http://www.valleylabel.net/Images/products-layout-merge.jpg
http://www.bestprintingfranchises.com/Printing_homepage_picture.jpgWRAP Section 5 Material considerations. The Guide to Evolving Packaging Design. P 22-23
http://www.wrap.org.uk/retail/the_guide_to_evolving_packaging_design/material_considerations/index.html
Photo source:
http://www.stickers-labels.co.uk/food-packaging-labels-450.jpg
http://www.valleylabel.net/Images/products-layout-merge.jpg
http://www.bestprintingfranchises.com/Printing_homepage_picture.jpg
15. Beyond Comparisons This breif survey of the common concerns and advantages associated with the materials manufacturing processes and material properties hints at the breadth of issues being addressed
There are many life cycle assesments and comparison studies which note the differences between certain packaging instances, but the strive towards sustainable packaing is not as simple as redesigning ones product to choose the best material and using the least amount of it necessary for ones purpose.
Good redesign guidelines exsist, but a sustainable product must work towards a state to meet environmental, economic and social requirements. Striving towards such a state may require reducing the amount of tradeoffs necessary though new innovations. It is certain that the current practices are not suffiencient.
Diagram 1 Citation: World Centric PLA Energy Usage Comparison: From Earth to Pellet: Comparing Resource Requirements between PLA, PP, PET and EPS Products.
http://worldcentric.org/sustainability/manufacturing/PLA
Energy use for plastics & other materials diagram citation: PLASTICS INSTITUTE OF AMERICA PLASTICS ENGINEERING, MANUFACTURING & DATA HANDBOOK
Diagram 1 Citation: World Centric PLA Energy Usage Comparison: From Earth to Pellet: Comparing Resource Requirements between PLA, PP, PET and EPS Products.
http://worldcentric.org/sustainability/manufacturing/PLA
Energy use for plastics & other materials diagram citation: PLASTICS INSTITUTE OF AMERICA PLASTICS ENGINEERING, MANUFACTURING & DATA HANDBOOK
16. Overview
Information
Infrastructure
Incentives, Policies, Standards
IX Primary Challenges for Change
17. Primary Challenges for Change A lack of guidance and action hinder creating the momentum for the large-scale changes that needs to take place.
Primary challenges for government, industry and individuals center around:
Lack of information
Missing infrastructure
Insufficient incentives, conflicting policies and standards Federal Trade Commission (FTC) (April 30, 2008). Green packaging claims. Transcript. Washington, DC. http://htc- 01.media.globix.net/COMP008760MOD1/ftc_web/transcripts/043008_sess1.pdf
Federal Trade Commission (FTC) (April 30, 2008). Green packaging claims. Transcript. Washington, DC. http://htc- 01.media.globix.net/COMP008760MOD1/ftc_web/transcripts/043008_sess1.pdf
18. Lack of Information Plenty of critiques, comparisons, and vilification, but a lack of packaging solutions
New packaging materials are not necessarily well known by consumers, addressed by regulations or easily available by potential buyers
Current labeling environment confuses consumers
Existing resin codes are difficult for consumers to understand (Ex: Is #1 the best to buy?)
In the US, claims of biodegradable, degradable, compostable, biomaterial, biopolymers, renewable plastics are not well understood and often misused. (Ex: Biodegregation does not occur everywhere.)
Government guidance is limited.
Green guides are out of date, and often support vague measures (for example: it is near impossible to measure % of population actually recycling ones product)
No laws similar to EU packaging directives or regulation on sharing environmental responsibility in supply chain exist
Greenwashing among companies trying to meet consumer demand is rampant
Understanding of issues in terms of resource management, lifecycle impacts or the concept of sustainability is limited and varying. Focus is on waste management. Federal Trade Commission (FTC) (April 30, 2008). Green packaging claims. Transcript. Washington, DC. http://htc- 01.media.globix.net/COMP008760MOD1/ftc_web/transcripts/043008_sess1.pdfFederal Trade Commission (FTC) (April 30, 2008). Green packaging claims. Transcript. Washington, DC. http://htc- 01.media.globix.net/COMP008760MOD1/ftc_web/transcripts/043008_sess1.pdf
19. Missing Infrastructure Recycling infrastructure incomplete
Many more materials can be recycled than there are facilities for in most regions
Company voluntary activities (Certification, Takeback Policies) can require significant costs and reinvention of the wheel
Composting infrastructure is rare
Without this bioplastics that can only be composted in industrial facilities will either pollute the plastics recycling stream or contribute to landfills Federal Trade Commission (FTC) (April 30, 2008). Green packaging claims. Transcript. Washington, DC. http://htc- 01.media.globix.net/COMP008760MOD1/ftc_web/transcripts/043008_sess1.pdf
Federal Trade Commission (FTC) (April 30, 2008). Green packaging claims. Transcript. Washington, DC. http://htc- 01.media.globix.net/COMP008760MOD1/ftc_web/transcripts/043008_sess1.pdf
20. Insufficient Incentives, Conflicting policies & standards Few incentives, other than individual company goals or costs-saving measures for voluntary action
Measures with teeth are needed to combat inertia towards the status-quo
At present change or compliance with green guide regulations is motivated by forward-thinking producers and consumers who do not mind research
Standards with clear definitions (biocompostable vs. compostable vs. home compostable) quantitative metrics (GHG etc), guides on action (what type of LCA)
At present the USDA defines a biobased product, the ASTN sets standards about biodegradabilitythese are not necessarily coordinated together nor with an national concept/goal of sustainability Federal Trade Commission (FTC) (April 30, 2008). Green packaging claims. Transcript. Washington, DC. http://htc- 01.media.globix.net/COMP008760MOD1/ftc_web/transcripts/043008_sess1.pdf
Federal Trade Commission (FTC) (April 30, 2008). Green packaging claims. Transcript. Washington, DC. http://htc- 01.media.globix.net/COMP008760MOD1/ftc_web/transcripts/043008_sess1.pdf
