Biodegradable Polymers and Plastics
The Industrial Agricultural Products Center (IAPC) at the University of Nebraska has created
a family of resins
that can be engineered to create a programable life product to meet precise performance
requirements. The IAPC uses the
tools of polymer chemistry, the properties of starch and reactive extrusion processing to create
these resins with unique
characteristics.
Made from renewable resources and other environmentally friendly additives the resin's
properties allows for the
responsible disposition of products through hydroytic, biodegradable action, or clean
incineration, with a positive life cycle
impact.
Unlike other environmentally friendly resins, the IAPC resin can be made using conventually
available materials that will
allow it to compete in numerous markets on price and performance:
- Biodegradable Polymers
- Degradable Plastics
- Contact IAPC
For more information or opportunities contact Industrial Agricultural Products
Center, 209 L.W. Chase Hall, Lincoln, NE 68583-0730, by telephone: (402) 472-1634;
Fax (402) 472-6338
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Posted August 1999
Biodegradable Plastic Resin
For more information on other degradable polymers
or opportunities contact Dr. Milford A. Hanna, Industrial Agricultural
Products Center, 208 L.W. Chase Hall, Lincoln, NE 68583-0730, by telephone: (402) 472-1634;
Fax (402) 472-6338 or
e-mail: mhanna1@unl.edu.
The Industrial Agricultural Products Center (IAPC) at the University of Nebraska has created
a family of starch based resins
that can be engineered to create a programable life product to meet precise performance
requirements. The IAPC uses the
tools of polymer chemistry, the properties of starch and reactive extrusion processing to create
these resins with unique
characteristics.
Made from renewable resources and other environmentally friendly additives the resin's
properties allows for the
responsible disposition of products through hydroytic, biodegradable action, or clean
incineration, with a positive life cycle
impact.
Unlike other environmentally friendly resins, the IAPC resin can be made using conventually
available materials that will
allow it to compete in numerous markets on price and performance:
- Packaging
- Medical
- Personal Hygiene
- Consumer Products
- Food Processing
- Many Others. . .
Degradable Plastic
This patent covers a method of making a biodegradable polymer by combining a
carbohydrate and non-biodegradable
polymer with material that breaks up the carbohydrate and causing a reaction under heat and
pressure which substitutes at
least some monosaccharide groups from the carbohydrate into the non-biodegradable polymer
chain that allows the
carbohydrate (starch) to degrade.
For more information on other degradable polymers
or opportunities contact Dr. Milford A. Hanna, Industrial Agricultural
Products Center, 208 L.W. Chase Hall, Lincoln, NE 68583-0730, by telephone: (402) 472-1634;
Fax (402) 472-6338 or
e-mail: mhanna1@unl.edu.
| United States Patent |
5,496,895 |
| Rangaswamy Chinnaswamy and Milford A. Hanna.
|
March 5, 1996 |
Biodegradable polymers
Abstract
To prepare a biodegradable plastic, biodegradable materials such as starches and a
non-biodegradable polymer such as a
polystyrene, polyurethane, polyethylene, polypropylene, or polycarbonate are treated: (1) under
heat, pressure and reagents
to break the polymers; and (2) by adding to them an oxidizing agent. This treatment forms and/or
makes available reactive
groups for bonding: (1) on the biodegradable material groups such as aldehyde or hydroxyl
groups in the case of the
carbohydrates and amine groups in the case of proteins and certain other compounds such as
urea; and (2) on the
non-biodegradable plastic groups such as aldehydes, methyl, propyl, ethyl, benzyl or hyroxyl
groups. In one embodiment,
plastic and starch are processed in an extruder by: (1) mixing a starch in a range of between 15
percent and 80 percent, an
oxidizing agent and an agent to break up the starch and the plastics; and (2) subjecting the
combination to sufficient heat
and/or pressure to break the plastic into shorter chains and bond monosaccharides to monomers
from the
non-biodegradable polymer.
| Inventors: |
Chinnaswamy;
Rangaswamy (Lincoln, NE); Hanna; Milford A. (Lincoln,
NE) |
| Assignee: |
The Board of Regents of the University of
Nebraska (Lincoln, NE) |
| Appl. No.: |
942132 |
| Filed: |
September 8,
1992 |
| U.S. Class: |
525/54.2; 525/54.3;
525/326.1; 525/374; 525/379; 525/380; 525/382;
527/300 |
| Intern'l Class: |
C08G 063/48; C08G 063/91; C08F 008/00; C08F 032/00 |
| Field of Search: |
525/54.2,54.3,326.1,374,379,380,382 527/300 |
References Cited
U.S. Patent Documents
| 4451629 |
May., 1984 |
Tanaka et al. |
526/238. |
| 4891404 |
Jan., 1990 |
Narayan et al. |
525/54. |
Primary Examiner: Nutter; Nathan M.
Attorney, Agent or Firm: Carney; Vincent L.
Parent Case
Text
This application is a continuation of application Ser. No. 07/393,373, filed Aug. 14, 1989, now
abandoned.
Claims
1. A biodegradable polymer comprising polymeric chains that include both monosaccharides
from a starch feedstock and
hydrocarbon monomers from a feedstock non-biodegradable plastic covalently bound to each
other in ratios by weight of
between 15 and 80 percent monosaccharide from starch feedstock to hydrocarbon from the
feedstock non-biodegradable
plastic, wherein at least some of the monosaccharides are bound by covalent bonds within the
hydrocarbon chain of the
biodegradable polymer.
2. A method of making a biodegradable polymer comprising the steps of: combining a
carbohydrate and a
non-biodegradable polymer with material that breaks up the carbohydrate and causing a reaction
under heat and pressure
which substitutes at least some monosaccharide groups from the carbohydrate into the
non-biodegradable polymer chain
wherein the percentage by weight of substituted carbohydrate to non-biodegradable polymer is
between 15 to 80 percent.
3. A process according to claim 2 wherein the non-biodegradable polymer is a polystyrene and
the carbohydrate is a starch.
4. A method of making a biodegradable polymer comprising the steps of: combining a
carbohydrate and non-biodegradable
polymer with material that breaks up he carbohydrate and causing a reaction under heat and
pressure which substitutes at
least some monosaccharide groups from the carbohydrate into the non-biodegradable polymer
chain wherein the percentage
by weight of substituted carbohydrate to non-biodegradable polymer is between 15 to 80
percent;
the non-biodegradable polymer is a polystyrene and the carbohydrate is a starch;
the combination is injection molded in a dispersion pressurized reactor; the carbohydrate to
polystyrene ratio is 60 percent
to 40 percent and includes 10 to 20 grams of citric acid and sodium bicarbonate and is extrusion
processed at a temperature
of substantially 140 degrees Centigrade and a pressure of approximately 20 mega-Pascals.
Description
BACKGROUND OF THE INVENTION
This invention relates to biodegradable polymers and to methods of making them from
non-biodegradable polymers such as
petroleum -based plastics combined with other biodegradable polymers, such as for example,
carbohydrates, proteins, lipids
or the like.
It is known to alter polymers such as petroleum-based plastics by the incorporation of some
carbohydrates to increase their
biodegradability. One prior art biodegradable polymer and method of making it is disclosed in
U.S. Pat. No. 4,016,117 to
Griffin, issued Apr. 5, 1977. In this product, a synthetic resin incorporates particles of
biodegradable substances and an
auto-oxidizable substance. The processing preserves the starch granules in the final product. This
polymer, when it contacts
a transition metallic salt, auto-oxidizes to generate a peroxide or a hydroperoxide.
Other biodegradable products are disclosed in U.S. Pat. Nos. 4,405,731 to Carter issued Sep. 20,
1983; 3,778,392 to
Hughes issued Dec. 11, 1973; 3,949,145 to Otey et al. issued Apr. 6, 1979; and 4,280,920 to
Kesting.
The biodegradable plastics disclosed in these United States patents have the disadvantages of
only containing from
approximately 5 percent to 15 percent carbohydrate while retaining its characteristics as a plastic
although they may have
up to 50 percent starch but become paperlike at such high levels and lose the typical
characteristics of thermoplastic or
thermosetting plastics. The altered structure reduces the elasticity and shear strength.
SUMMARY OF THE INVENTION
Accordingly, it is an object of the invention to provide a novel biodegradable polymer.
It is a further object of the invention to provide a novel process for making biodegradable
polymers.
It is a still further object of the invention to provide a novel biodegradable polymer in which a
carbohydrate or protein or
possibly lipids may be substituted in percentages between 15 percent and 80 percent while
preserving a substantial number
of the desirable properties of the polymer.
It is a still further object of the invention to make a novel biodegradable polymer using a process
which causes chemical
modification of a carbohydrate or protein or possibly lipids or urea and a non-biodegradable
polymer to make a
biodegradable polymer.
It is a still further object of the invention to provide a novel biodegradable plastic and process for
incorporating
carbohydrates or proteins or possibly lipids into polystyrene, polyurethane, polyethylene,
polypropylene, or polycarbonate
plastics in quantities greater than 15 percent while preserving many of the functional
characteristics of the plastic.
It is a still further object of the invention to provide a novel foam plastic product and method of
making it.
It is a still further object of the invention to provide a novel film plastic product and method of
making it.
In accordance with the above and further objects of the invention, a biodegradable polymer is
provided having polymeric
chains that include both hydrocarbon monomers from a non-biodegradable polymer and other
biodegradable groups such as
monosaccharides or amino acids or the like that render the polymer biodegradable. In these
polymers, the biodegradable
groups and hydrocarbon monomers are bonded or interconnected by single and/or double bond
covalent linkages,
hydrocarbon or bridge bonds, Van der Waals' forces or the like to each other. The biodegradable
groups may be obtained
from carbohydrates, proteins, lipids, urea or other materials that can result in groups that combine
with the hydrocarbon
monomers from the plastic while retaining biodegradability.
In preparing the biodegradable plastic, the biodegradable group and a non-biodegradable polymer
such as a polystyrene,
polyurethane, polyethylene, polypropylene, or polycarbonate are treated: (1) under heat, pressure
and reagents to break the
polymers; and (2) by adding to them an oxidizing agent. This treatment forms and/or makes
available reactive groups for
bonding: (1) on the biodegradable material such as aldehyde or hydroxyl groups in the case of the
carbohydrates and amine
groups in the case of proteins and certain other compounds such as urea; and (2) on the
non-biodegradable polymers such
as aldehydes, methyl, propyl, ethyl, benzyl or hyroxyl groups.
In one embodiment, the non-biodegradable polymer is treated by: (1) adding to it a carbohydrate
in a range of between 15
percent and 80 percent, an oxidizing agent and an agent to break up the starch or similar
carbohydrates; and (2) subjecting
the combination to sufficient heat and/or pressure to break the polymer into shorter chains and
bond monosaccharides to
monomers from the non-biodegradable polymer.
In one example of this embodiment, the non-biodegradable polymer is polystyrene, the oxidizing
agent is citric acid and the
substance for degrading the starch is sodium bicarbonate. The heat and pressure is provided by
extruding the combination
at high temperatures to form a biodegradable foam plastic in which the sodium bicarbonate and
citric acid: (1) release
carbon dioxide as a foaming agent; (2) oxidize the methyl groups of the styrene to form groups
such as aldehyde groups
which react with groups on the starch; and (3) form sodium hydroxide to degrade the starch and
thus to form aldehydes
such as formaldehyde or hydroxyl groups to react with the styrene. Similarly, proteins can be
degraded to amino acids or
aldehyde compounds having reactive amine or carboxyl groups to react with the hydroxyl or
aldehyde groups of the
oxidized carbohydrate.
As can be understood from the above description, the biodegradable polymer of this invention
and the method of making it
have several advantages, such as for example: (1) the biodegradable polymer retains its physical
characteristics with a large
percentage of carbohydrate added or protein or other biodegradable material; (2) the
biodegradable polymer effectively
degrades when discarded; (3) the process permits the inclusion of a large amount of
carbohydrate; and (4) the
biodegradable polymer is less expensive than other biodegradable polymers.
DETAILED DESCRIPTION
A carbohydrate, protein or lipid substituted biodegradable polymer or other substituted
biodegradable polymer such as a
urea substituted biodegradable polymer includes a polymeric chain including both hydrocarbon
monomers such as alkyne
and alkene polymers derived from petroleum and biodegradable monomers, such as amino acids
or monosaccharides or
lipids, preferably obtained from agricultural products, such as wheat or corn, in a molecule. The
hydrocarbon monomers
and monosaccharides or amino acids or other such groups are covalently bound to each
other.
More specifically, the monosaccharides or amino groups or carboxyl groups of lipids are bound
in groups or chains of units
or as a single monomer side-chains or branches of the feedstock to hydrocarbon polymers and/or
within the hydrocarbon
chain to pairs of monomers such as glucose, styrene, ethylene, benzyl, acetyl (for lipids) and
amino acids. The
monosaccharide, amino or carboxyl groups or group are bonded to hydrocarbon monomers from
the feedstock
non-biodegradable polymer and similarly the hydrocarbon monomers from the feedstock
non-biodegradable polymer may
be connected as single monomers to monosaccharides or amino acids or the like or be bonded as
chains of hydrocarbon
monomers. The different types of monomers are distributed throughout the polymer molecules of
the biodegradable
polymer. The monomers originating from the petroleum based polymer and from the
biodgradable carbohydrate, protein,
lipid or urea may be interconnected by single and/or double bond covalent linkages, hydrocarbon
or bridge bonds, Van der
Waals' forces or the like but most commonly by covalent bonds.
The biodegradable polymers are prepared by a high-temperature short-time, high-shear extrusion
process in which one or
more biodegradable material such as carbohydrate or protein or lipid or urea or the like and one
or more non-biodegradable
polymer such as petroleum based plastics are mixed with an oxidizing agent and a mild acid or
alkali that breaks the
biodegradable polymer into chains of between 1,000 to 100,000 daltons or approximately 500 to
50,000 monosaccharide
groups in the case of starch or other carbohydrates or the equivalent length in proteins or
lipids.
The non-biodegradable polymer may be any alkyne or alkene chain with a substituted methyl
and/or other functional groups
such as ethene, ethyne, propylene, propyne, butadiene and the like groups on plastics such as
polystyrene, polyurethane,
polyethylene, polypropylene, and polycarbonate among others. The proportion of amino acid or
carbohydrate to
non-degradable polymer w/w (weight to weight) is between 15 and 80 percent carbohydrate or
amino acid and the
carbohydrate, protein or starch should have a chain length greater than 1,000 daltons.
Suitable compounds that degrade the carbohydrates include sodium hydroxide, citric acid,
sodium chloride, sodium
bisulfite, urea, acrylic acid, acrylonitrile, adipic acid, aluminum trichloride, amino resins, analeic
acid, phthalic acid,
azo-bis-isobutyronitrile, berleculite, benzoyl peroxide, bisphenol A, boron triflouride, butadiene,
casein, cellophate, acetate,
butyrate, triacetate, tanthate, chloroprenyl, decamelhylene glycol, diethyl maleate, diethyl
phthalate, ethylene glycol,
propylene glycol, epichlorohydrin, epoxy resins, ethane, ethylene, ethylene oxide, formaldehyde,
fumaric acid, glycerol,
hemomethylene diamine, hexamine, isobutene, isobutylene, melamine, methacrylic acid, methyl
vinyl acetone, polyehylene
terephthalate, phenol, polyamides, potassium amide, sebacoyl chloride, sodium napthalide,
styrene, titanium tetrachloride,
vinyl chloride, vinyl sulphonic acid, zieglar catalyst.
Compounds for degrading carbohydrates are known in the art and differ from each other in their
reactions with starch in
known ways. Instead of a compound that degrades carbohydrates, compounds that form such
carbohydrate-degrading
compounds, such as sodium bicarbonate and citric acid, may also be used.
In manufacturing one suitable biodegradable polymer, a carbohydrate such as starch and
non-biodegradable polymer are
combined in a range of weight-to-weight ratios from approximately 4 parts non-biodegradable
polymer to one part
carbohydrates at one end to one part non-biodegradable polymer to two parts carbohydrate at the
other end of the range and
with 1 to 10 percent each of an oxidizing agent and carbohydrate degrader, and in some
embodiments, a foaming agent,
The combination is subjected to heat at a selected temperature falling within the range of 110 to
180 degrees Centigrade
and a selected pressure falling within the range of 3 to 55 mega-Pascals.
As a result of this process, the carbohydrate molecules degrade and then react with the
non-biodegradable polymer
molecules to form a new polymer having interconnected chemical groups from the carbohyrate
and from the original
non-biodegradable polymer. The reaction under these conditions is believed to be as shown in
equation 1.
In the reaction of equation 1: MS indicates any monosaccharide or amino or lipid group; R1 is
any group attached to the
alkyl group of a monomer of the non-biodegradable polymer; and M is any unit or monomer of
the basic feedstock
non-biodegradable polymer.
In equation 2, there is shown a general reaction between a carbohydrate and a non-biodegradable
petroleum-based polymer.
In this equation, L represents any carbohydrate monomer, M is a monomer of the
non-biodegradable polymer such as
polystyrene, polyethylene or the like and R1, R2, R3 are any other hydrocarbon group such as for
example any acetyl,
methyl, propyl, butyl or the like. Proteins or amino acids and probably lipids may be substituted
into non-biodegradable
polymers to further increase the degradability.
For example, as shown in equation 4 a protein or amino acid, shown as P with connected reactive
groups, can react with
polystyrene or other non-biodegradable polymer have n monomers to obtain the biodegradable
polymer and as shown in
equation 5, a lipid, shown as F with a reactant group is combined with a non-biodegradable
polymer having n monomers M
##STR1## and a reactive group R1 or R2 either of which may be a carboxyl group to obtain a
biodegradable polymer.
In this specification, the term "non-biodegradable" means a material, which when incubated at
room temperature and 50
percent humidity for a time period of two months, shows no substantial growth of bacteria or
fungi nor an increase of less
than a multiple of 4 in bacteria or fungi if the initial product already contained some growth. It
should suffer less than 50
percent loss of its integrity and physical strength by conversion of the polymer to carbon dioxide
and lower molecular
weight hydrcarbons within six months in a landfill. In this specification, the term "biodegradable
material" means that after
incubation at a moisture of 50 percent at room temperature for two months, the material is
substantially degraded and has
lost its mechanical strength or, if it has not reached that stage, that there has been an increase in
microbial growth on the
material of at least four times the starting growth. It should loose at least 50 percent of its
physical integrity and strength
within six months in a landfill.
Also biodegradable polymer in this specification includes those polymers that are ##STR2##
degradable through a process
by which fungi or bacteria secretes enzymes to convert a complex molecular structure of the
compound to simple gasses
and organic compounds and compounds capable of decomposing or deteriorating through a
natural chemical process into
harmless components after exposure to natural elements for not more than one year.
In the preferred embodiment, a starch based biodegradable polymer is prepared by a
high-temperature short-time, high
shear extrusion processes. Starch and polystyrene are combined in a ratio of 60 percent to 40
percent and with 1 to 10
percent each of citric acid and sodium bicarbonate when extrusion-cooked at a temperature of
140 decrees Centigrade and a
pressure of approximately 20 mega-Pascals.
The starch molecules degrade and then react with polystyrene molecules to form a network. The
citric acid controls the
molecular degradation and interactions. The sodium bicarbonate decomposes to NaOH and
CO.sub.2. The NaOH degrades
the starch molecules and the CO.sub.2 contributes to the uniform foam structure of the product.
A reaction under these
conditions is believed to be illustrated as shown in equation 3 in which the left-hand top formula
is that of a polystyrene,
the top right formula is that of a starch and the bottom formula is the formula of the new
biodegradable polystyrene.
The process of choice appears to be high-temperature short-time extrusion. This process,
including the steps for forming
containers is described in "Foam, Extruded Polystyrene", Encyclopedia of Packaging Technology
by Bakker, copyright
1986, published by John Wiley & Sons, Inc, N.Y. N.Y., USA, page 345, the disclosure of
which is incorporated herein by
reference. However, techniques such as thermosetting, injection molding and dispersion
pressurized reactors may also
provide satisfactory reaction conditions to form a similar starch-polystyrene network.
The resultant product may find use as meat trays, cups, egg cartons, plates, bowls, loose-fill
packaging materials, insulation
and sound proofing materials. In other words, it can be used in areas where expanded plastics are
currently being used.
Moreover, other plastic products such as bottles and wrapping materials, may be made using
corresponding
non-biodegradable plastics as a feedstock. For some uses a rodenticide or repellant and an
insecticide or repellant or
antimicrobial agents may be included.
The invention is illustrated by the following examples:
EXAMPLES
GENERAL
The temperatures and pressures in the examples are applied during extrusion of the combination
of ingredients. The starch
in the actual examples was obtained from corn and wheat but can also be obtained from
sorghum, potato, rice and tapioca.
EXAMPLE 1
Wheat starch and polystyrene are mixed in a ratio of 66 percent wheat starch by weight to 27
percent polystyrene and
combined with 3 percent c acid and 6 percent sodium bicarbonate. They are extrusion-cooked at
a temperature of 140
degrees Centigrade and a pressure of approximately 20 mega-Pascals.
The resulting product has the appearance of the original expanded polystyrene.
EXAMPLE 2
Wheat starch and polystyrene are mixed in a ratio of 38.1 percent wheat starch by weight to 57.1
percent polystyrene and
combined with 1.6 percent citric acid and 3.2 percent sodium bicarbonate. They are
extrusion-cooked at a temperature of
140 degrees Centigrade and a pressure of approximately 20 mega-Pascals.
The resulting product has the appearance of the original expanded polystyrene.
EXAMPLE 3
Wheat starch and polystyrene are mixed in a ratio of 52.9 percent wheat starch by weight to 35.3
percent polystyrene and
combined with 4.4 percent citric acid and 7.4 percent sodium bicarbonate. They are
extrusion-cooked at a temperature of
140 degrees Centigrade and a pressure of approximately 20 mega-Pascals.
The resulting product has the appearance of the original expanded polystyrene.
EXAMPLE 4
Wheat starch and polystyrene are mixed in a ratio of 23.4 percent wheat starch by weight to 70.3
percent polystyrene and
combined with 1.6 percent citric acid and 4.7 percent sodium bicarbonate. They are
extrusion-cooked at a temperature of
140 degrees Centigrade and a pressure of approximately 20 mega-Pascals.
The resulting product has the appearance of the original expanded polystyrene.
EXAMPLE 5
One percent milk protein and 20 percent corn starch and/or wheat starch are combined with 79
percent polystryene, 1.6
percent citric acid and 4.7 percent sodium bicarbonate. They are extrusion-cooked at a
temperature of 140 degrees
Centigrade and a pressure of approximately 20 mega-Pascals.
The resulting product has the appearance of the original expanded polystyrene.
EXAMPLE 6
One percent wheat protein (isolated) and 20 percent corn starch and/or wheat starch are
combined with 79 percent
polystryene combined with 1.6 percent citric acid and 4.7 percent sodium bicarbonate. They are
extrusion-cooked at a
temperature of 140 degrees Centigrade and a pressure of approximately 20 mega-Pascals.
The resulting product has the appearance of the original expanded polystyrene.
As can be understood from the above description, the biodegradable polymer of this invention
and the method of making it
have several advantages, such as for example: (1) the biodegradable polymer is less expensive
than other biodegradable
polymers; (2) the biodegradable polymer retains its physical characteristics with a large
percentage of carbohydrate added;
(3) the biodegradable polymer effectively degrades when discarded; and (4) the process permits
the inclusion of a larger
amount of carbohydrate.
Although a preferred embodiment of the invention has been described with some particularity,
many modification and
variations in the preferred embodiment may be made without deviating from the invention.
Accordingly, it is to understood
that, within the scope of the appended claims, the invention may be practiced other than as
specifically described.