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Step 5 End of life
==================
Goal
----
To restore natural capital and support life-friendly chemistry by
eliminating waste, hazards and pollution associated with the fate of
chemicals, materials and products after use. Waste may be mitigated by
designing a product for longevity and durability or for reuse and
recycling.
Introduction
------------
End of life hazards include chemical hazards but also physical hazards
from litter. A viable waste management pathway for a product once it is
no longer needed should be part of the initial product design. In
addition, consumers should have clear information on how to best ensure
proper management and value recovery.
‘Cradle to Cradle’ thinking calls for deciding up front whether the
materials in the product are intended to be ‘biological nutrients’
within a ‘biological cycle’ or ‘technical nutrients’ within a ‘technical
cycle’ (or both). If a chemical or material is intended to be a
biological nutrient, its fate should result in complete and benign
biodegradation in its likely waste pathway, whether that is wastewater
treatment, compost, etc. If it is intended to be a technical nutrient,
it should be reused or recycled in either a widely available recycling
system or in a system managed by the product manufacturer to ensure
recovery and proper management. Green Blue Institute has developed the
`How2Recycle Labeling program `__
to assist with optimizing proper end of life management of packaging
materials.
The chemicals and materials in a product can enhance or diminish the
value of recycled materials. They can also cause problems with different
waste management pathways. For example, if a toxic and persistent
chemical is included in a commercially compostable plastic, the plastic
may biodegrade, but the additive will not. It will stick around and
contaminate the compost and make it less valuable. By building a
chemical inventory, you identify what chemicals are likely present in
the product.
See `Resource 1 - Chemical
Inventory <./resource1-chemical-inventory.html>`__ for guidance and
suggestions. This will help you determine which are likely persistent
and resistant to degradation, as well as which are likely to break down
and what they may break down into, and whether or not these chemical
ingredients are toxic as well.
See `Resource 2 - Chemical Hazard
Assessment <./resource2-chemical-hazard-assessment.html>`__ for guidance
and suggestions on learning about the hazards of the chemicals in your
inventory.
`Learn more about Cradle to Cradle
design. `__
Consider how your product will have the least impact on human health and
the environment after use by striving to be near the top of the waste
hierarchy. While there are exceptions to the waste hierarchy, the idea
of first preventing waste, then recovering the most material value with
the least negative life cycle impacts still holds.
|image0|
Plastic straws are an example of an exception. When used on beaches,
they are frequently littered as opposed to properly disposed of, so it
is unlikely that a recyclable straw would actually be recycled. A
biodegradable straw is a better fit considering the likely end of life
pathways. Another preferrable alternative could be re-usable straws
paired with programs to ensure their return, minimizing litter.
Possible End of Life Pathways for Products After Use
----------------------------------------------------
Waste mismanagement and littering are forms of what is called ‘leakage’
to the environment. It is an all too frequent and very undesirable waste
pathway. Estimate how likely it is that leakage to the environment will
occur. Using global statistics based on types of waste found in the
environment is recommended. Estimates based on regional differences are
relevant. For example, some of the more frequently found litter includes
cigarette butts and plastic bags.
- Leakage (improper management, litter)
- Landfill
- Incineration with no energy recovery
- Incineration with energy recovery
- Recycling (primary, secondary, tertiary or quaternary)
- Compost (commercial)
- Compost (backyard)
- Other biodegradation (aquatic (fresh, marine), aerobic, anaerobic)
Be sure to include only pathways that are actually available in the area
your product is used. While food packaging made from PLA may be
potentially compostable in industrial facilities, this is not relevant
if the area does not have industrial composting facilities, or if those
facilities have chosen to not accept plastic products.
Examples
--------
Example 1: Design for Multiple EOL Pathways
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Floral Soil Solutions designed the Floral Soil product for multiple end
of life pathways. First of all, the product is designed for reuse
multiple times for holding cut flowers. It can also be used to grow
plant plants starting with cuttings and even seeds. After multiple uses,
if the product is truly spent, it can be added to enhance soil in
houseplants, in a garden or in compost.
|image1|
Example 2: Design for Value Recovery
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
A good model for integrating product design with material recovery is
the RecyClass Tool developed by Plastics Recyclers Europe. RecyClass
guides the choice of plastic used in packaging and promotes recycling.
It addresses the presence of incompatibilities that affect the
efficiency of recycling. Plastics that are easy to identify and to
separate from the rest of the product, and for which there is an
established Plastics Recyclers Europe (PRE) recycling stream score
better. RecyClass is limited to a small variety of plastics such as
PET-bottles, PE-LD and HD, polyolefin tubs and trays, PVC from the
building sector and some technical plastics. While limited in scope, the
tool is a good model for how product design considerations can be linked
to material selection and to material recycling options.
|image2| |image3|
Example 3: GreenBlue’s How2Recycle
~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
Green Blue Institute has developed the How2Recycle Program to provide
structured guidance for how to communicate information to customers on
how to manage a product’s packaging once it is ready to become waste.
|image4|
`Image Source: GreenBlue `__\
`Learn more about the Green Blue Institute’s How2Recycle
Program `__
.. |image0| image:: ./assets/5-end-of-life/lansinks-ladder.jpg
.. |image1| image:: ./assets/examples-tools-for-eol/floral-soil-lc.png
.. |image2| image:: ./assets/examples-tools-for-eol/recyclass.png
.. |image3| image:: ./assets/examples-tools-for-eol/recyclass2.png
.. |image4| image:: ./assets/examples-tools-for-eol/triple-p-recycling.png