Chapter 1
Recycling Plastics from Municipal Solid Waste
An Overview
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Wayne Pearson
Plastics Recycling Foundation, P.O. Box 189, Kennett Square, PA 19348
Recycling means that we
disposables, to someone.
value. In fact, if it were
fact that no one wants to
are going to try to sell our garbage, or other
The problem is that garbage has very little
extremely valuable, it would be stolen. It is a
buy garbage.
Consequently, a lot of work must be done to the garbage pile to turn it
into viable products. This work includes processing the garbage to
quality raw materials that can be manufactured into products that can
be sold to buyers who will buy it again, and again, and again.
Recycling requires four elements:
•
•
•
•
collection
sorting of raw materials
reclaiming the raw materials to make a product
markets and paying customers for the product
The Nation is producing 180 tons of municipal solid waste a year.
Based on the EPA study, about 29 billion pounds of plastic entered the
waste stream in 1988. This represented about 56% of what was
produced that year. The lag is what would be expected, considering the
different life cycles of the different uses.
Because the life cycle of packaging is so very short, we can assume that
virtually all of the production ends in the waste stream within one year,
whereas the more durable uses would take longer to reach the waste
stream.
The EPA claims that eight percent of the 180 million tons of MSW or about 29 billion
pounds of plastics in municipal solid waste accounts for about 20 percent of the
volume (Figures 1 and 2).
0097-6156/92/0513-0001$06.00/0
© 1992 American Chemical Society
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.
2
EMERGING TECHNOLOGIES IN PLASTICS RECYCLING
Packaging, the element in the waste that is getting the most national
attention and the highest concern, represents about 3 0 % (Figures 3 and
4)·
The plastics share of packaging by weight is 13 percent (Figure 5).
Packaging is dominated by paper and glass (Figure 6).
The following recyclable items are reasonably viable in terms of
technology and economics today:
newspapers
aluminum and steel cans
glass bottles and jars
plastic beverage containers
It's interesting to note that on a volume basis the plastic beverage
container is equal to about 1/3 of the volume of things that are
recyclable today, namely:
newspapers, non-plastic beverage containers
and plastic beverage containers (Figure 7).
Moreover, it is technically and economically viable to collect and sort
plastic beverage bottles to reclaim the polymers contained therein
which include polyethylene terephthalate (PET), high density
polyethylene (HDPE) and polyvinyl chloride (PVC). The markets for these
reclaimed polymers exist in far greater size than all the polymer used in
the manufacture of beverage containers.
Including plastics beverage
containers with non-plastic beverage containers (glass, aluminum and
steel) along with newspapers increases the volume that can be recycled
by the home owner by about 50 percent, and it can be highly profitable
because plastics beverage containers are second only to aluminum in
value.
This technology to collect and sort these commodities is available to
hundreds of communities in the Nation who are redeveloping and
implementing plans to collect and include them in their recycling
programs.
The infrastructure for reclaiming, cleaning up and producing products to
sell is growing fast. There are a number of major companies involved in
the business already, and the list is growingzyxwvutsrqponmlkjihgfedcbaZYXWVU
(Table 1).
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.
PEARSONzyxwvutsrqponmlkjihgfedcbaZYXWVUTSRQPONMLKJIHGFED
Recycling Plastics from Municipal Solid Waste
MzyxwvutsrqponmlkjihgfedcbaZYXWVUT
Paper and
paperboard
Other
Μ
Figure 1. Materials Generated in MSW by Weight (180
million tons), 1988.
•
Paper &zyxwvutsrqponmlkjihgfedcbaZ
ι
Paperboard I
=
Other
I
Figure 2. Materials in MSW by Volume (Cubic Yards),
1988.
I
Packaging
Figure 3. Percent of Plastics in MSW by Use (%).
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.
4
EMERGING TECHNOLOGIES IN PLASTICS RECYCLING
TABLE 1. M ajor U. S. a nd Canadian S crap
Plastic Bottle Reclaimers (1991)
E stima te d
Annua l
C a pa city
in
M illion Lbs.
C ompa ny
Loca tion
Clean Tech
Day Products
Eagl ebrook Plastics
Graham Recycling
Johnson Controls
M.A. Industries
Dundee, Ml
Bridgeport, NJ
Chicago, IL
York, PA
Novi, Ml
Peachtree City,
GA
Edgerton, Wl
Odessa, TX
Vancouver, WA
Berthierville, PQ
Philadelphia, PA
12
40
35
20
20
20
Chicago, IL
40
M i d w e s t Plastics
Orion Pacific
Partek
Pelo Plastique
Plastic Recycling
Alliance
Plastic Recycling
Alliance
Quantum Chemical Co.
Star Plastics
St. Jude Polymer
Union Carbide
United Resource
United Resource
Recovery
Source:
Heath, OH
Albany, NY
Frackville, PA
Piscataway, NJ
Findlay, OH
Johnsonville, SC
10
7
5
15
40
40
32
25
50
8
175
Resource Recycling, 1991
In addition, the National Polystyrene Corporation has several
polystyrene plants and more in the planning. There are also a number of
manufacturers of plastic profiles for park and highway equipment using
commi ngl ed plastic from the waste stream.
Some driving forces are accelerating and expanding the demand for these
recycled materials, particularly the activities of packagers who wish to
use recycled plastic to achieve a more environmentally attractive
package.
In a word, the Nation is well positioned to recycle newspapers and
beverage containers, including plastic beverage containers.
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.
PEARSONzyxwvutsrqponmlkjihgfedcbaZYXWVUTSRQPONMLKJIHGFED
Recycling Plastics from Municipal Solid Waste
Figure 4 . Packaging Share of Municipal Solid Waste.
DDzyxwvutsrqponmlkjihgfedcbaZYXW
Other
U
Paper
11 Glass
H Metals
•
Figure 5.
Figure 6.
Plastics
Plastics Share of Packaging.
Plastics Packaging by Volume.
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.
6
EMERGING TECHNOLOGIES IN PLASTICS RECYCLING
Figure 8.
Trash Pile-Number of Items.
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.
7
1. PEARSONzyxwvutsrqponmlkjihgfedcbaZYXWVUTSRQPONMLKJIHGFED
Recycling Plastics from Municipal Solid Waste
However, to fully understand the complexity of processing trash to
useful products beyond these traditional items, it is helpful to gain a
perspective. The trash pile can be viewed as a pyramid as shown below
(Figure 8). At the top are ten items we commonly recycle, namely:
-
newspapers
aluminum beverage cans
steel beverage cans
tin cans
clear glass bottles
brown glass bottles
amber glass bottles
green glass bottles
PET soft drink bottles
HDPE milk, water and juice bottles
At the next level there are 100 items which include: colored plastic
detergent bottles, pharmaceutical bottles, other papers, magazi nes, and
bi -metal c o n t a i n e r s .
Below that there are 1,00 items which include other glass, ceramics,
multi-layer materials (foil, paper, etc.).
At the next level there may be 10,000 items including household
cl othi ng, industry, etc.
The more items to process back to their original or "closed loop"
applications, the more complex the collection, sorting and reclamation
become and the more expensive it becomes.
This is where the development of commingled products comes in. It may
be necessary to work with mixed paper, mixed glass, mixed metal, and
mixed plastics if we wish to go deeper into our trash.
BE Y O N D BE V E R AG E BO T T LE S
It is technically feasible to recycle, recover and reuse all of the
discarded plastics packaging, but with the exception of beverage
bottles, economics limit the degree of recycling at this time.
Communi ti es are not enthusiastic about collecting materials if their
alternate methods of garbage disposal cost less. Therefore, it is
necessary to consider the cost to the community as well as the cost to
the reclaimer to get the full cost of the recycled material. The fact that
the recycled material must compete with virgin resin in quality and
price must be taken into account when considering markets.
The cost to the community includes the following:
cost to collect recyclables
cost to sort recyclables
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.
8
EMERGING TECHNOLOGIES IN PLASTICS RECYCLING
From these two costs the community is entitled to subtract:
the cost of collecting trash that is avoided (by diverting it to
recyclables)
the cost of disposal avoided (e.g. tipping fee at landfill)
The sum of these four items will be the cost to the community. The
community can recover some or all of that cost by selling the recovered
recyclables. The price that they need to cover the total cost is the
theoretical price the reclaimer should pay for a raw material.
The reclaimer will have the following costs:
•
•
•
•
raw material (equals community cost)
reclaiming cost (e.g. cost to convert the raw material to product
marketing expenses and overheads
profit and return on investment
The sum of all these costs, including dividends needed to pay stockholders,
becomes the minimum price required to make an economically attractive venture
for manufacturing a product derived from feedstock obtained from processing
trash.
The next question becomes: Is the price higher or lower than the price of virgin
material? The processing technologies today are good enough to manufacture
a product essentially equal in quality to virgin. However, in a normal free market
situation a manufacturer will insist on receiving a discount to use what is
deemed to be inferior quality material.
If we take a look at the economic viability of plastics packaging recycling consid
ering the virgin prices based on oil at nominally $20/barrel (Figure 9) we see
clearly that beverage containers are economically viable with current cost to
landfill which is between $50 and $100 ton. However, it is also clear that beyond
beverage bottles it is not economically attractive at today's price of oil, alternative
disposal costs and current recycling technology.
If, however, the price of oil were to rise to $35 per barrel (Figure 10),
then the cost associated with manufacturing virgin polymers from high
priced oil-related feedstocks would increase substantially.
Therefore,
even if recycled material were discounted, versus virgin prices, the
price would be high enough to make it economic to collect, sort, and
reclaim many plastic components from the waste stream.
This suggests that there is a "future value" to recycling that should be
given consideration from the point of view of "stock piling" material
going into the trash stream to be utilized in a future time when the
price of oil might be higher than $20/barrel.
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.
1. PEARSONzyxwvutsrqponmlkjihgfedcbaZYXWVUTSRQPONMLKJIHGFE
Recycling Plastics from Municipal SolidWaste
9
PRICE
'
,zyxwvutsrqponmlkjihgfedcbaZYXWVUTSRQPONMLKJIHGFEDC
PET
Oil at $20
per barrel
zyxwvutsrqponmlkjihgfedcbaZYXWVUTSRQPONML
zyxwvutsrqponmlkjihgfedcbaZYXWVUTSRQPONMLKJIHGFED
CO ST
g OfJ I T
s Package
Ethylene
Plastic Lumber
Figure 9. Viability of Plastics Packaging Recycling vs.
Today's Virgin Prices Based on Oil at $20/Barrel.
Figure 10. Viability of Plastics Package Recycling vs. Virgin Prices Based on
OiTat$35/barrel.
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.
10
EMERGING TECHNOLOGIES IN PLASTICS RECYCLING
Another issue that surfaces here is that if the public decides to
purchase recycled material, despite quality deficiencies, then the price
of recycled material need not be discounted versus virgin. In fact, the
price of recycled material could exceed the price of virgin. That would
change economics substantially, as shown with non-beverage bottles
(Figure 11).
This new marketing factor can be labelled "green". Simply stated, it
means that a product that can trace its pedigree to the post-consumer
garbage pile will be preferentially purchased versus one whose pedigree
is traced to natural gas or oil.
R E S E AR C H P R O G R AM S
To go beyond beverage bottles is needed to develop next generation
technology. We must reduce the cost of collection and sorting and
upgrade the quality of the generics recovered through improved
processing technologies so as to increase the value.
The process for deriving products with a garbage pile origin can be
d i a g r a m m e d as follows:
Garbage Pile
I
Collect and Separate
Recyclables
Generics
Separating Plastics
Non-Generics
Macro
Unrefined
Commingled
M icro
Refined
Commingled
M olecular
M a rke ts-
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.
1.
11
PEARSONzyxwvutsrqponmlkjihgfedcbaZYXWVUTSRQPONMLKJIHGFED
Recycling PlasticsfromMunicipal Solid Waste
PRICE
Cents/Lb.
50
40
Virgin Price (oil at $20/barrei)
Recycle Cost
30
Free Market Recycle Price (Oil at $20/barrel)
20
10
0
Landfill
50
Price-$/Ton
100
Figure 11. Economic Viability-Plastics Package
Recycling/Non-Beverage Bottles.
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.
12
EMERGING TECHNOLOGIES IN PLASTICS RECYCLING
Once the plastics are separated from the non-plastic recyclables, there
are a number of technologies for separation of the plastics to generic
components and there are technologies for dealing with commingled
(unseparated) plastics.
Research programs that are underway focus on the issue of collection,
sorting/reclaiming a n d end-use markets.
C O LLE C T I O N
In collection the issues are:
collection of all clean
col l ecti on c o n t a i n e r
packer trucks
truck routing
plastics
The question is: "What will the consumer give when asked to deliver all
clean plastics?"
This includes all rigid containers (beverage bottles,
detergent bottles, and rigid tubs) and non-rigid materials such as film.
Types of trucks and truck routing are also being studied.
S O R T I N G / R E C LAI M I N G
In the sorting and reclaiming of generics, the research is focused on
three types of separation:
macro
micro
molecular
Micro-sorting is
Macro-sorting is the separation at the container level.
the separation of chips of containers after the containers have been
shredded and chopped up. Molecular sorting involves dissolving polymers
in an organic solvent. It has been demonstrated that five or more
polymers can be separated for packaging from each other in a solvent
system.
Some polymers will be de-polymerized (sorted at the monomer molecule
level). Condensation polymers are among the more easily depolymerized molecules, so it is not surprising to see commercial
operation in place or planned to de-polymerize PET (from SODA BOTTLES)
to the monomers dimethyl terephthalate and ethylene glycol.
Purification of these molecular separations can be high. Monomer
derived from post-consumer PET bottles has been found acceptable by
the FDA.
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.
1.
13
PEARSONzyxwvutsrqponmlkjihgfedcbaZYXWVUTSRQPONMLKJIHGFED
Recycling PlasticsfromMunicipal Solid Waste
While molecular separation technology may not be economically viable
today, it will become more economically viable as the price of oil
increases, and/or as costs can be reduced for this methodology.
Industry and recycling communities are working on these same issues so
that the number of high quality generic plastic items in the trash pile
that will become economically viable will increase with time.
In connection with minimizing cost of collecting and sorti ng,
technologies that simplify collection, sorting and cleaning are surfaci ng.
Two of these technologies are:
the molecular separation of commi ngl ed plastics
the development of new compounds and families of products
based on "refined commi ngl ed" plastics
It has been demonstrated at the Center for Plastics Recycling Research
at Rutgers University, that mixed or commingled plastics from the postconsumer waste stream can be used to make a wide range of plastic
products using traditional virgin plastics processing equi pment.
The commingled plastic material requires no macro sorting and
collecting can be simplified. Thus the cost of collection and sorting can
be reduced substantially.
Once collected, the commingled plastic materials are "refined" by
chopping the plastics and washing them free of paper, metal and any
other non-pl asti c materi al s.
The "refined" (clean) commingled materials can then be modified by
mixing in one of the polymers or compatibilizers to achieve desired end
properties.
The compatibilized mixture is melt-filtered as it is blended
to produce a high purity pellet which can be processed on conventional
plastics processing equi pment.
It is desirable to segregate blow molding resin types from injection or
extrusion resins which can be accomplished at the "refined" commingled
plastic reclamation plant. Thus a broad range of "new" products can be
designed which expand the recycling potential for post-consumer
plastics.
There are a few commercial products we would define as "refined
c o m m i n g l e d " . These include mixtures of reclaimed polymer with virgin
polymer and compatibilizers added to achieve a specific property.
These molecular separation and refined commingled technologies do not
require plastics to be sorted. Moreover, the range of plastics collected
from the householder could be enlarged substantially. Bales containing a
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.
14
EMERGING TECHNOLOGIES IN PLASTICS RECYCLING
wide range of unsorted post-consumer plastics would be shipped to a
plant that could separate them into generic resins at the molecular level
or could manufacture new compounds from the commi ngl ed, unseparated
materials.
Both of these technologies will drive the cost of collecting and sorting
down and at the same time will provide some reasonable level of value
for the recovered generics and/or non-generic (commingled) plastics.
END U S E
End use market research programs continue to focus on and expand the
market opportunities for the full range of polymers from the waste
including polyethylene terephthalate (PET), high density polyethylene
(HDPE), polyvinylchloride (PVC), polystyrene (PS), and polypropylene
(PP), and market research on non-generic uses including the previously
mentioned new family of compounds and profiles is continuing.
C O N C LU S I O N
In conclusion, in 1985, very few people believed that plastics from the
post-consumer stream were recyclable, let alone were being recycled.
Today, the amount that is recycled is still in an early stage.
Approximately 300 million pounds of PET bottles are being recycled,
which represents about 3 0 % of that container, and probably about 1 0 % of
the milk, water and juice bottles are being recycled. However, the
technology has been researched sufficiently so that we can say
confidently that the entire packaging stream is recyclable. That is to
say, we have the technology for collecting, sorting, cleaning it up and
finding markets for it.
The economics for recycling plastic beverage containers are very
favorable making it highly desirable for communities to include them in
their recycling programs right now. Should they elect to do that, they
will be able to have the potential for increasing the volume they can
remove from the waste stream by 5 0 % , assuming that they are
collecting newspapers and non-beverage containers.
Looking beyond plastic beverage containers, we see that the technology
is viable but that there is a lot of work to do to reduce the cost of
collection, sorting and reclamation, and there is also work to do on the
market development.
However, with time, the rising costs of virgin
material, and alternative disposal costs will provide the driving forces
that will increase the percent of post-consumer plastics that are
recycled.
RECEIVED June 10,
1992
Andrews and Subramanian; Emerging Technologies in Plastics Recycling
ACS Symposium Series; American Chemical Society: Washington, DC, 1992.