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Description  |
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FIELD OF THE INVENTION
This invention relates to a blowing agent composition and the method used
to prepare a polymeric foam, particularly a styrenic or ethylenic foam.
BACKGROUND OF THE INVENTION
Thermoplastic foams made from styrenic polymers such as polystyrene have
found extensive use, particularly in food packaging and food service
applications. The key to a successful polystyrene foam for food
applications is to use a blowing agent composition during the formation of
the foam that diffuses out of the cells and is substantially replaced by
air before the foam comes into contact with any food to be packaged or
served.
Generally, polystyrene foams are manufactured by mixing a volatile blowing
agent with the styrenic resin under a controlled temperature and pressure
sufficient to plasticize the resin and to maintain the resin blowing agent
composition in an unfoamed state. Thereafter the molten mixture of resin
and blowing agent and sometimes a nucleator is extruded through an annular
die into a zone of lower temperature and pressure. If extrusion conditions
are optimum, a tube of rigid, closed cell foam will be produced.
This tube is usually stretched over a mandrel of larger diameter.
Stretching not only yields a larger tube of foam but also "orients" and
strengthens or toughens the foam.
The tube is then slit and opened up to form at least one flat sheet. The
sheet (or sheets) is usually stored in large rolls and aged for at least
24 hours. The aging process is required to obtain "post expansion" during
the subsequent thermoforming operation.
"Post expansion" refers to the swelling of the foam as it is heated in the
thermoformer oven. This expansion is the result of the different
permeation rates of air and the blowing agent through the foam cell walls.
As the foam emerges from the die during the extrusion step, the cells
containing the blowing agent tend to expand until the pressure within the
cells equals the atmospheric pressure outside the cells. During the aging
period, air permeates rapidly into the cells; but the blowing agent
(having a larger size molecule than air) permeates out relatively slowly.
The result is an increase of cell gas pressure during aging. The gas
pressure increases from 1 atmosphere to about 2 atmospheres. When the foam
is subsequently heated and softened, this increased gas pressure causes
the foamed product to expand further, i.e., "post expand".
Dichlorodifluoromethane (CFC-12) historically has been the blowing agent of
choice in producing polystyrene foam. With the planned phase-out of CFC-12
as a foam blowing agent because of its measurable undesirable Ozone
Depletion Potential (ODP) and the unacceptability of chlorodifluoromethane
(HCFC-22) as a long term alternative blowing agent in food packaging/food
service use, there is a critical need for an acceptable alternative
blowing agent. Hydrocarbon blowing agents, although having zero ODPs, are
less desirable for use in food containers since they are classified as
photochemically reductive volatile organic compounds (VOCs) and their use
is regulated by law.
It is an object of this invention to provide a blowing agent for
thermoplastic polymers such as polyethylene or polystyrene or the like
that displays a zero ODP and is not substantially photochemically
reactive, that can be processed in a manner such that it diffuses
substantially completely from the ultimate foamed product, and that, even
if a slight amount remained in the product, it would be so low as not to
be considered a component of any food served or contained within the
foamed product.
It is a further object to provide an operable process for utilizing the
aforementioned blowing agent in the manufacture of a polymeric foam
product, particularly in the manufacture of a foam of a thermoplastic
composition such as polyethylene or polystyrene or the like.
SUMMARY OF THE INVENTION
The invention comprises a polymeric foam product prepared from a
foam-forming composition containing from 2 weight percent up to about 20
weight percent based on the total weight of the composition, preferably
3-6 weight percent, of at least one polyfluorocarbon blowing agent
selected from the group consisting of 1,1,-difluoroethane (HFC-152a);
1,2-difluoroethane (HFC-152); 1,1,1,2-tetrafluoroethane (HFC-134a);
1,1,2,2-tetrafluoroethane (HFC-134); 1,1,1-trifluoroethane (HFC-143a); and
1,1,2-trifluoroethane (HFC-143); pentafluoroethane (HFC-125), preferably
HFC-152a and HFC-134a, and most preferably HFC-152a. Of course, nitrogen,
carbon dioxide, other inert gases, hydrocarbons and chemical blowing
agents can be used in conjunction with the polyfluorocarbon blowing
agents.
The ultimate polymeric foam product of this invention is characterized in
that the cells of the foam contain no substantial amount of the
polyfluorocarbon (PFC) blowing agent, i.e., 2-30 parts per million (ppm),
preferably 2-6 ppm, of the blowing agent. The cells of the foam are
substantially completely filled with air, making the foam produced
suitable for food contact applications. The amount of PFC remaining in the
foam, although measurable (even with the preferred amounts of 2-6 ppm
present), is insufficient to affect the food or to harm the consumer of
the food.
As stated above, HFC-134a and HFC-152a are preferred in polystyrene and
polyethylene foams. HFC-134a works better in polystyrene insulating foams
because of its slower permeation rate. This yields better long-term
insulating properties. The use of HFC-134a in preparing styrenic
insulating foams or boards will most likely require modification of the
conventional equipment because of its higher solution pressure in
polystyrene resin (higher than the solution pressures of the currently
used blowing agents, i.e., CFC-12, HCFC-142b, CFC-11).
The preference for HFC-152a in polystyrene and polyethylene packaging foams
is based on the following four characteristics:
1. Low environmental impact: zero ODP, very low HGWP, (halocarbon global
warming potential) or "greenhouse effect", and has been added to the list
of organic compounds which are negligibly reactive and thus may be exempt
from regulation under state implementation plans (SIP's) to attain the
national ambient air quality standards (NAAQ's) for ozone;
2. Low molecular weight: less amount of HFC-152a is required to achieve
similar density as existing foams;
3. Low cost per pound; and
4. Rapid diffusion from foams: imperative for food service and food
packaging applications.
HFC-152a is also the preferred polyfluorocarbon blowing agent for
polyethylene foam insulation. Although, both HFC-152a and HFC-134a
permeate within a few days from polyethylene foams and, therefore, do not
contribute to long term insulating value, the higher efficiency of
HFC-152a in the preparation process and its lower cost per pound make it
preferred for polyethylene foams.
The invention also provides a method for use of the blowing agent
composition which comprises foaming a mixture of a styrenic resin and the
polyfluorocarbon blowing agent composition to produce a styrenic foam. In
a preferred embodiment of the method of the invention, the method
comprises producing a styrenic foam by heating a styrenic resin in an
extruder to produce a molten resin; introducing into the molten resin a
blowing agent comprising at least one of the aforementioned
polyfluorocarbons, preferably HFC-152a or HFC-134a to produce a
plasticized extrusion mass under a pressure sufficient to prevent foaming
of the extrusion mass; and extruding the extrusion mass through a die into
a zone having a temperature and pressure sufficient to permit foaming of
the extrusion mass to produce the styrenic foam.
The packaging foams should be produced using no added water, preferably in
the absence of any water. It has been found that the use of water in
polyethylene and polystyrene foam production causes large unacceptable
voids (steam pockets) in the resulting foam product. It is believed that
this is due to the poor solubility of water in these polymers. However,
small amounts of water (1-4 wt.%) may be used if an appropriate
solubilizing or dispersing agent (alcohol, glycol, surfactants, etc.) is
also used.
In the preparation of foams in accordance with the method of the invention,
it is often desirable to add a nucleating agent to the styrenic resin.
These nucleating agents serve primarily to increase cell count and reduce
the cell size in the foam and are used in an amount of about 0.1 part by
weight to about four parts by weight per one hundred parts resin. For
example, talc, sodium bicarbonate/citric acid, gaseous CO.sub.2, calcium
silicate and the like are suitable nucleating agents for reducing cell
size. Talc is a preferred nucleating agent component in the practice of
the method of the invention. Various other additives, for example, fire
retardant additives, color concentrates, stabilizers, anti-oxidants,
lubricants, etc. may also be used depending on the end use of the styrenic
foam.
The invention comprises a method for producing a styrenic foam having a
thickness from about 0.04 to about 4.0 inches, using the blowing agent
compositions of the invention.
Packaging foams are anywhere from 0.04 to 0.200 inches, while insulating
foams may be as thick as 4.0 inches or higher. In the preferred method of
the invention, a styrenic foam is produced from a "styrenic resin", which
means a solid polymer of one or more polymerizable alkenyl aromatic
compounds or a compatible mixture of such polymers. Such an alkenyl
aromatic compound has the general formula:
##STR1##
wherein R.sub.1 represents an aromatic hydrocarbon radical of the benzene
or substituted benzene series, and R.sub.2 is either hydrogen or the
methyl radical. Examples of such alkenyl aromatic compounds are styrene,
alphamethyl styrene, ortho-methyl styrene, meta-methyl styrene,
para-methyl styrene. The solid copolymers of one or more of such alkenyl
aromatic compounds with amounts of other polymerizable compounds such as
methylmethacrylate, acrylonitrile, maleic anhydride, acrylic acid and the
like are also operable in this invention. The preferred styrenic resin is
the homopolymer, polystyrene, which is readily available from various
sources.
In the method of the invention, the styrenic resin is mixed with a blowing
agent composition and the resulting mixture is then foamed. Preferably the
foaming is carried out with the use of an extruder, wherein the styrenic
polymer is heated to about 400.degree.-450.degree. F. to produce a molten
polymer and the blowing agent is then introduced into the extruder where
it is mixed with the molten polymer under pressures such that the
resulting plasticized extrusion mass does not foam, but its viscosity
decreases. The extrusion mass is then cooled. Cooling increases the
viscosity and the melt strength of the mass prior to extrusion. The mass
is then extruded through a die of any desirable shape of a controlled
temperature, usually about 300.degree. F., the reduced pressure outside
the extruder permitting the extrusion mass to foam.
The temperature and pressure conditions under which the styrenic resin and
blowing agent mixture will not foam will depend upon the particular
styrenic resin used and generally, will be at a temperature between about
240.degree. F. and about 440.degree. F. and a pressure above about 600
psig.
The conditions of temperature and pressure under which the extrusion mass
will foam, again will depend upon the precise styrenic resin used and
generally will be at a similar temperature of about 40.degree. F. and
440.degree. F. but at a lower pressure. However, the more precise the
temperature is controlled throughout the extrusion process, the more
uniform the resulting foam.
The melt plasticization is controlled by the choice of the particular
polyfluorocarbon blowing agent composition, the amount of and type of
nucleating agent or other additive(s) present, the particular styrenic
resin or mixture being used and the Tg or Tg's of the resin(s) and the
temperature, pressure in the extruder and the extrusion rate. The shaping
means used can also affect the orientation of the polymer.
In practicing the method of the invention, the blowing agent may be added
to the styrenic resin in any desirable manner and, preferably, by
injection of a stream of the blowing agent composition directly into the
molten styrenic resin in the extruder. The blowing agent should be mixed
thoroughly with the styrenic resin before the blowing agent and styrenic
resin mass is extruded from the die. This is necessary to produce a foam
having uniform density and cellular structure.
The extrusion mass comprising the molten resin and the blowing agent
composition is extruded into an expansion zone within which foam formation
and expansion takes place. Any suitable extrusion equipment capable of
processing polystyrenic compositions can be used for the extrusion. Single
or multiple-screw extruders can be used. Softening the polymer and mixing
with the blowing agent take place during working of the polymer between
flights of the screw or screws, which also serve to convey the extrusion
mass to the extruder die. Screw speed and extruder barrel temperature
should be such as to achieve adequate mixing and softening but not so high
as to degrade the composition being processed.
The foams can be used in the form prepared, cut into other shapes, further
shaped by application of heat and pressure or otherwise machined or formed
into shaped articles of desired size and shape. The styrenic foams
produced at this point where the polyfluorocarbon is still substantially
retained within its cells have utility for insulating material.
For the foams to have utility in the food service and food packaging
application, the tubular foamed product from the initial foaming zone or
stage is fed over a mandrel of larger diameter to be stretched anywhere
from 1.2 to about 5 times its original diameter.
After stretching, the tube is slit and opened to form a flat sheet. The
flat sheet is stored on a roll. The rolls are aged in air over a period of
at least about 24 hours but usually less than 2 weeks, i.e., sufficient
time for air to permeate through the cell walls of the foam, but because
of storage in rolls of foamed sheet, insufficient time for any substantial
amount of the polyfluorocarbon blowing agent to diffuse out. The result is
a substantial increase in gas pressure within the cells. When the foamed
product is heated and softened in the final step of the process, the
increased gas pressure causes the foamed product to expand further, i.e.
post expand. The polyfluorocarbon then diffuses substantially completely
from the final foamed product and is replaced by air.
The following Examples are intended to illustrate the method of using the
preferred polyfluorocarbon blowing agents to make the foamed products of
the present invention.
EXAMPLE 1
In this example, polystyrene foam sheet was prepared using HFC-152a as the
blowing agent; and was compared to a similar product prepared using
HCFC-22 as the "control" blowing agent.
It was concluded that HFC-152a was a very efficient blowing agent. About 25
percent less of HFC-152a than the control was required to achieve a
similar density polystyrene foam.
The post-expansion characteristics of foam sheet produced with HFC-152a
were superior to foam produced with the control.
The polystyrene foam sheet using HFC-152a thermoformed into excellent
quality egg cartons and hamburger containers.
The comparative test (HFC-152a vs. the control) was conducted using a
conventional tandem extrusion system. Foam was extruded through an annular
die, stretched over a mandrel about 4 times the die's diameter, and slit
to produce a single sheet.
The extrusion system was started using the control blowing agent. After
about 25 minutes, HFC-152a was introduced from cylinders pressurized with
nitrogen.
In the following table, Table 1, the data using HFC-152a and the control as
blowing agents are compared:
TABLE 1
______________________________________
HFC-152a
Control
______________________________________
Extrusion rate (lbs/hr)
700 700
Blowing agent injection
32 40
rate (lbs/hr)
Die pressure (psig)
1100 1160
Melt temperature (.degree.F.)
300 295
Foam density (pcf)
4.9 5
Sheet gauge (mils)
114 114
______________________________________
Foam sheet produced in this test using HFC-152a was successfully
thermoformed after 7, 14, 21 and 28 days' aging, whereas the control
failed to produce acceptable product after 21 days.
EXAMPLE 2
In the following table, Table 2, the important properties of HFC-152a and
HFC-134a are compared to CFC-12 and HCFC-22:
TABLE 2
______________________________________
CFC-12 HCFC-22 134a 152a
______________________________________
Molecular Weight
120.9 86.5 102 66
Boiling point (.degree.C.)
-29.8 -40.8 -26.5 -25.0
ODP 1.0 0.05 0 0
HGWP 3.1 0.34 0.28 0.03
______________________________________
The ozone depletion potential (ODP) was calculated using the method
described in "The Relative Efficiency of a Number of Halocarbon for
Destroying Straospheric Ozone": D. J. Wuebles, Lawrence Livermore
Laboratory report UCID-18924, (January 1981) and "Chlorocarbon Emission
Scenarios: Potential Impact on Stratospheric Ozone" D. J. Wuebles, Journal
Geophysics Research, 88, 1433-1443 (1983).
Basically, the ODP is the ratio of the calculated ozone depletion in the
stratosphere resulting from the emission off a particular agent compared
to the ODP resulting from the same rate of emission of CFCl.sub.3,
(CFC-11) which is set at 1.0. Ozone depletion is believed to be due to the
migration of compounds containing chlorine or bromine through the
troposphere into the stratosphere where these compounds are photolyzed by
UV-radiation into chlorine or bromine atoms. These atoms will destroy the
ozone (O.sub.3) molecules in a cyclical reaction where molecular oxygen
(O.sub.2) and [ClO] or [BrO] radicals are formed, those radicals reacting
with oxygen atoms formed by UV-radiation of O.sub.2 to reform chlorine or
bromine atoms and oxygen molecules, and the reformed chlorine or bromine
atoms then destroying additional ozone, etc., until the radicals are
finally scavenged from the stratosphere. It is estimated that one chlorine
atom will destroy 10,000 ozone molecules.
The ozone depletion potential is also discussed in "Ultraviolet Absorption
Cross-Sections of Several Brominated Methanes and Ethanes" L. T. Molina,
M. J. Molina and F. S. Rowland J. Phys. Chem. 86, 2672-2676 (1982); in
Bivens et al. U.S. Pat. No. 4,810,403; and in "Scientific Assessment of
Stratospheric Ozone: 1989" U. N. Environment Programme (21 August 1989).
The global warming potentials (GWP) are determined using the method
described in "Scientific Assessment of Stratospheric Ozone: 1989"
sponsored by the U. N. Environment Programme.
The GWP, also known as the "greenhouse effect" is a phenomenon that occurs
in the troposphere. It is calculated using a model that incorporates
parameters based on the agent's atmospheric lifetime and its infra-red
cross-section or its infra-red absorption strength per mole as measured
with an infra-red spectrophotometer.
##EQU1##
divided by the same ratio of parameters for CFCl.sub.3.
EXAMPLE 3
The permeation and diffusion properties of HFC-152a relative to polystyrene
were determined in this example.
In FIG. 1, the permeation coefficient of HFC-152a is compared to the
coefficients for CFC-12, HCFC-142b, HCFC-22, and nitrogen at temperatures
of 20.degree. C. to 160.degree. C.
In FIG. 2, the permeation rate for HFC-152a through polystyrene film is
presented for various pressure drops across the film at temperatures of
20.degree. C. to 100.degree. C.
In FIG. 3, the diffusion coefficient of HFC-152a into polystyrene is
presented at various temperatures from 20.degree. C. to 160.degree. C.
The permeation tests were conducted by a modification of ASTM D1434-82,
"Standard Method for Determining Gas Permeability Characteristics of
Plastic Film and Sheeting". This modified procedure is described in the
Master of Chemical Engineering Thesis, P. S. Mukherjee, Widener
University, Chester, Pa., February 1988, entitled "A Study of the
Diffusion and Permeation Characteristics of Fluorocarbons Through Polymer
Films":
(1) Using a Barber-Coleman press, 30 g samples polystyrene (as pellets)
were pressed into 6".times.6" sheets of film with 15-20 mil thickness. The
pressing was done at 400.degree. F. and at a pressure of about 35,000 psig
(maintained for 5 minutes).
(2) Discs (15-20 mil thickness) were cut from 6".times.6" sheets of film.
Five discs of 47 mm diameter were made from each sheet. The discs were cut
or stamped at ambient temperature using a die punch made of A-2 type steel
(hardened).
(3) All tests were run at a 20 psia pressure differential between the high
pressure side and the low pressure side of the permeation cell.
(4) Permeation tests were run at 20.degree. to 160.degree. C., with tests
for each polystrene/gas combination being run at at least 5 temperatures.
Data for other temperatures were calculated from the equation:
##EQU2##
wherein P is permeation coefficient, T is .degree.K (C+273.2) and A and B
are constants determined from the permeation coefficients calculated from
the following equation:
##EQU3##
(5) The permeation rates are based on a 1 cm.sup.2 by 1 cm thick film with
a 1.0 psia pressure drop across the film.
To obtain the permeation coefficient (P), the standard permeation equation
is used. It is based on Fick's law of diffusion and Henry's law of
solubility.
##EQU4##
The diffusion coefficient for each experimental temperature was determined
by extrapolating the straight-line plot of low-side pressure versus time,
obtained in the permeation study to the time axis. This time, referred to
as lag time in literature, is used to obtain the diffusion coefficient by
means of this equation:
##EQU5##
Based on the data shown in the figures, it is apparent that HFC-152a
exhibits permeation characteristics similar to HCFC-22 with polystyrene.
The permeation coefficients for HFC-152a are nearly identical to HCFC-22
but the diffusion coefficients differ. The diffusion coefficient for
HFC-152a changes much less over the temperature range
20.degree.-100.degree. C. than the coefficient for HCFC-22. This is an
indication of the solubility difference between the two compounds relative
to polystyrene.
The foregoing indicates that HFC-152a is a good candidate for foaming
polystyrene sheet for food service and food packaging containers. This
blowing agent readily permeates from the foam but still provides effective
post expansion (better than HCFC-22), because the remaining blowing agent
is in the cells, not the polymer.
EXAMPLES 4 AND 5
In these examples, two different foam sheets were produced using a 4.5
inch/6 inch tandem extrusion line; Example 4, 10 g/100 square inches;
Example 5, 17 g/100 square inches.
The manufacturing and test data are presented in Table 4.
TABLE 4
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Example 4 Example 5
(10 g/100 sq.in.)
(17 g/100 sq.in.)
______________________________________
Formulation
Polystyrene (%)
95.3 96.5
HFC-152a (%) 4.4 3.1
Talc (%) 0.4 0.4
Foam Product
Thickness (mil)
85 85
Density (pcf) 3.6 5.9
Cell size (mil)
3.9 8.0
Foam Thickness After
Post-Expansion (mils)
after
1 day 197 211
2 days 188 169
3 days 187 189
4 days 240 174
6 days 244 204
7 days 247 234
10 days 224 198
14 days 214 231
21 days 250 214
24 days 265 215
______________________________________
EXAMPLE 6
In this Example, polystyrene foam sheet was prepared using a 4.5 inch/6
inch tandem extrusion system with a raw material composition of:
93 wt. percent polystyrene pellets
3 to 5 wt. percent HFC-152a
4 wt. percent nucleating agent (talc)
The polystyrene sheet is typically extruded to a thickness of 50 to 300
mils and at a rate of approximately 1,000 pounds of plastic per hour.
Typical extruder conditions range from 2,000 to 4,000 psi and 200.degree.
to 400.degree. C. The ranges are large to reflect the different conditions
in the 4.5" versus 6" extruder sections. The HFC-152a concentration in the
feed material will change depending on the desired thickness (thicker
product requires more HFC-152a).
Once the polystyrene has been extruded, it is typically aged between 3 days
to 2 weeks. During this time, it is stored in rolls in a warehouse. Some
HFC-152a permeates out of the foam at this time but at a relatively slow
rate.
After storage, the rolls of foam are thermoformed, producing the desired
type of end-product (e.g., clamshell containers, plates, etc.). The
permeating rate of HFC-152a during thermoforming is much greater than
during storage.
After thermoforming, the product is stored until it is utilized by the
end-user. Typically, the material is aged about 6 weeks after
thermoforming before it is used. The concentration of HFC-152a in the foam
at this point is 20 to 30 ppm. In one test, the concentration of HFC-152a
was found to be 28 ppm 6 weeks after thermoforming with a precision of
plus or minus 3.5 percent.
Specifically, the loss of HFC-152a and the limits of detectability for
HFC-152a in a polystyrene foam (Hamburger clamshell containers) was
determined up to the time of use and discard. Typically, clamshell
containers are used/discarded 8 weeks from the time of extrusion (6 weeks
from thermoforming). At this time, 28 ppm plus or minus 3.5 percent
HFC-152a was still in the foam.
The residual levels of HFC-152a in Hamburger clamshells as a function of
time is given in the following Table 5.
TABLE 5
______________________________________
Clamshell Residual
Age (weeks)* HFC-152a, ppm**
______________________________________
1 4,027
2 1,427
3 374
4 127
5 49
6 28***
______________________________________
*From date of thermoforming. Polystyrene foam produced 2 weeks prior to
thermoforming.
**Analytical method precision is plus or minus 3.5 percent.
***Clamshell containers are typically 8 weeks old (6 weeks from
thermoforming) when used/discarded.
To determine the amount of HFC-152a remaining in the foam, the clamshells
were cut into flat pieces that would lie flat in a pint "Mason" jar and
5.0 grams of foam pieces were weighed into the jar. Dibutyl phthalate (50
ml) was added to the jar and the jar was set aside for 24 hours to allow
the foam to dissolve. Next, the system was equilibrated at 65 degrees C. A
one-milliliter headspace (gas) sample was withdrawn with a gas-tight
syringe and injected into a Hewlett-Packard 5890 gas chromagraph with
Porapak QS 60/80 mesh packing. The quantity of HFC-152a in the headspace
is determined from the peak area plot; and by comparison with a
calibration curve, the quantity of HFC-152a in the foam sample is
calculated. All samples were run in duplicate. The precision for the
analyses was plus or minus 3.5 percent, with a lower detection limit of
about 0.5 ppm.
* * * * *
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