HK1004069B - Polystyrene foam made with only carbon dioxide as a blowing agent and a process for making the same - Google Patents

Description

This invention relates to polystyrene foam prepared with a blowing agent which is only carbon dioxide. The invention also includes a process for making this polystyrene foam utilizing only carbon dioxide as the blowing agent. This invention is particularly suited for making polystyrene foam sheet having a thickness of less than about 0.5 inch (1.25 cm).

Polystyrene foam, particularly in sheet form, is at the present time made from any number of blowing agents which may possess or cause one or more of the following undesirable characteristics: volatility, flammability, poor thermoforming characteristics, brittle foam sheet physical properties, high cost or an adverse effect to the ozone layer. Examples of these blowing agents would include aliphatic hydrocarbons and fully or partially halogenated hydrocarbons.

Some have experimented with blends of carbon dioxide and other blowing agents such as aliphatic hydrocarbons or fully or partially halogenated hydrocarbons. An example of this can be seen in U.S. Patent Nos. 4,344,710 and 4,424,287. These patents, however, state that the use of a 100 percent carbon dioxide blowing agent has not been successfully employed in continuous direct injection foam sheet manufacturing (Column 1, lines 42-45 and lines 49-55 respectively) due to the extreme volatility. Use of these materials is said to produce corrugation and surface defects.

Others have developed methods and apparatuses for metering a gaseous blowing agent, such as an atmospheric gas, into a molten resin charge, such as polystyrene, in an accurate and precise manner. One example of this can be seen in U.S. Patent No. 4,470,938. The apparatus of this patent meters discrete uniform volumetric charges of gaseous blowing agent into the molten resin using a free piston-cylinder combination which is given motive power by the supply gas source.

A typical current commercial polystyrene foam sheet extrusion process may use a tandem extrusion process (two extruders in series). The first extruder melts the polymer to produce a polymer melt. A high pressure metering pump would then deliver blowing agent to the polymer melt at the end of the first extruder where mixing is initiated prior to entering the second extruder where further mixing and cooling of the blowing agent and the polymer melt occurs. After exiting the second extruder the polymer melt then passes through and becomes a foam structure at an annular die. The foam structure, in the shape of an annular tube, is then stretched over a forming mandrel. The annular tube coming off the mandrel is then slit and opened to form a sheet which is then gathered on one or more rolls. The sheet is then aged and then thermoformed into a foam sheet packaging article.

The use of carbon dioxide as the sole blowing agent avoids many of the problems of ocher blowing agents and blends of other blowing agent with carbon dioxide. The use of carbon dioxide in liquid form avoids the problems of handling a gas.

Thus the invention is concerned with polystyrene foam blown solely with carbon dioxide, preferably liquid carbon dioxide, and the process necessary to make such polystyrene foam.

The invention is particularly suited for making polystyrene foam sheet having beneficial physical properties for thermoforming purposes.

AU-A-529339 discloses the preparation of foamed sheets of alkenyl aromatic polymers using carbon dioxide as a blowing agent. However, the amount of carbon dioxide and extrusion conditions recommended differ from those of the invention.

In a first aspect, the invention provides a process for producing a thermoplastic foam comprising the following steps:

• a. melting a styrenic polymer;
• b. continuously directly introducing into the melted styrenic polymer a blowing agent consisting of carbon dioxide in an amount of 0.5 to 6 weight percent by weight of the polymer;
• c. mixing intimately the styrenic polymer and the carbon dioxide; and
• d. extruding and foaming the mixture at a die temperature below 150°C into a region of lower pressure to form thermoplastic foam sheet, wherein the resulting thermoplastic foam has a cell size in any direction which is less than lmm, and sheet thickness of less than 0.5" (1.25cm).

The process of the present invention is especially suited to make thermoplastic foam sheet for thermoforming purposes.

Figures 1 and 2 are machine direction and cross direction tensile elongation values, respectively, for foams prepared with carbon dioxide (CO₂) and dichlorodifluoromethane (CFC-12) as blowing agents.

Figure 3 is a post expansion study of foam sheet at three different residence times in an oven.

Polymers useful in the present invention are those polymers, copolymers and interpolymers having at least 70 percent by weight styrene monomer incorporated into the final resin as the monomeric repeat units. This includes other polymers such as for example styrene acrylonitrile, styrene acrylic acid, other known equivalents and blends having the styrene monomer repeat unit requirement. For the purpose of this invention these useful polymers shall be referred to as styrenic polymers. The preferred materials are styrenic homopolymers.

The blowing agent preferably used is that grade of carbon dioxide which is normally commercially available. For the purposes of this specification such carbon dioxide is referred to as 100 percent carbon dioxide even though this carbon dioxide may contain minor impurities or amounts of other compounds.

The carbon dioxide is preferably added to a polymer melt in a liquid form, although use of the carbon dioxide in the gaseous form would also be acceptable in the practice of the present invention.

The use of a tandem extrusion process for the manufacture of polystyrene foam sheet is typical, but is not required. Such a process includes a primary extruder, a blowing agent addition system into the primary extruder, a secondary extruder, an annular die, a cooling mandrel, a sheet cutter or slitter and a sheet gathering device, such as for example rollers and winders.

However, the use of this exact equipment set-up is not required in the process of this invention.

Additives, such as pigments, nucleating agents and other additives conventionally known in the art may be added to the polystyrene foam of the present invention. The addition of a nucleating agent is generally preferred and is added in an amount of from 0.02 to 10 percent of the total polystyrene by weight. Preferably the amount of nucleating agent is between 0.2 to 2 percent. One conventional nucleating agent is talc.

Polystyrene foam sheet can be produced using 100 percent carbon dioxide as the blowing agent provided certain modifications are made in the handling and the preparation of the polystyrene foam sheet. Preferably the carbon dioxide is continuously directly introduced or injected into the molten resin. Preferably the carbon dioxide is continuously directly injected as a high pressure liquid.

To produce foam sheet having a density in the range of 2 to 10 pounds per cubic foot (PCF) (32 to 160 kg·m^-3), preferably 3 to 6 PCF (48 to 96 kg·m^-3), 0.5 to 6 weight percent, preferably 1 to 4 weight percent of carbon dioxide is required per weight of polymer. Cell sizes in all directions are less than 1 millimeter (mm), and preferably less than about 0.5 mm. The thickness of the foam sheet is preferably less than about 0.5 inch and more preferably less than about 0.25 inch.

It is possible to have a blow up ratio, that is a stretching of the foam over a mandrel after it exits a die, greater than 4:1. It is preferable to have a blow up ratio of at least 2.0:1.

The foaming temperature at the die is generally below 150°C and preferably between 130 and 145°C. The thermoplastic foam is extruded and foamed into a zone of lower pressure preferably air at atmospheric pressure.

While it may be possible to use a polystyrene cam sheet immediately it is preferred to age the polystyrene foam sheet for a period of time, usually at least about 20 hours prior to thermoforming the foam sheet. This will allow time for air to counter diffuse into the cells. It will also render the tensile elongation values substantially constant. This will provide uniform thermoforming characteristics for the polystyrene foam sheet to be thermoformed.

Substantially constant tensile elongation values over an extended period of time obtained with a minimum of aging of the foam sheet would yield more consistent results upon thermoforming the foam sheet, thus more consistent product with less scrap. The tensile elongation values are preferably in excess of five percent and remain above five percent for an extended period of time eg. 80 - 300 hours, thus allowing the storage of foam sheet for an extended period of time before thermoforming without worrying about the changing values or the degradation below five percent of the tensile elongation values of the foam sheet.

The tensile elongation values are determined according to the method ASTM D638 "Tensile Properties of Plastics" published by the American Society for Testing and Materials (ASTM). The words machine or extrusion direction, transverse or cross direction and vertical direction are used in their normal and conventional manners.

Though the tensile elongation values of the foam sheet of the present invention are not perfectly constant, they are substantially constant and even more important for thermoforming, the tensile elongation values remain above a value of five percent for an extended period of time. Generally when these values fall below five percent the foam sheet becomes too brittle for thermoforming.

The thermoforming temperature will be somewhat higher than that of a polystyrene foam sheet blown with fully or partially halogenated chlorofluorocarbon or hydrocarbons since the CO₂ provides essentially no solvent effect which would normally lower the heat distortion temperature and therefore the melt strength of the foam walls upon reheating. The polystyrene foam sheet blown with 100 percent CO₂ can be post expanded in a range of 20 to 50 percent during thermoforming. It is preferred that the polystyrene foam sheet be aged for at least 20 hours prior to the carefully controlled thermoforming of the foam sheet.

Example and Comparative Example

Polystyrene foam sheet is prepared on a tandem extrusion line, with the polystyrene resin having a weight average molecular weight of about 300.000 being melted in the first extruder and with the carbon dioxide being continuously directly injected as a high pressure liquid into the end of the first extruder as a liquid. The pump heads providing the carbon dioxide to the extruder are cooled to about 0°F (-18°C) with liquid nitrogen to eliminate vapor lock and to improve pump efficiency. The carbon dioxide is metered using a mass flow meter on a low pressure side or suction side of the pump. Confirmation of the percent of CO₂ used is also made by measuring the weight loss of the CO₂ from storage cylinders holding the CO₂.

The results of this example and a comparative example, conventionally blown with dichlorodifluoromethane (CFC-12), are shown in Table I. Weights are percent weight by polymer weight. The thermoforming was performed in a manner typical for forming meat trays. Table 1

	Comparative Example	Example
	CFC-12
% Blowing Agent by weight	5.0	2.5
% Talc by weight	0.7	0.5
Sheet Gauge, mils (mm)	120 (3.0)	130 (3.3)
	3.5 (56)	3.2 (51)
Die Melt Temperature, °C	150	144
Output Rate, lbs/hr (Kg/hr)	198 (89.8)	169 (76.7)
Blow Up Ratio	3.5:1	3.5:1
Extruder Pressure, psi (KPa.)	3800 (26200)	4700 (32400)
Die Pressure psi (KPa.)	2000 (13800)	3500 (24100)
Sheet Aging Time, days	7	3
Thermoformer % Post Expansion	54	30
Tooling Used	meat tray	meat tray

As can be seen from Table 1 it is possible to use a lower amount of carbon dioxide to produce a foam sheet having approximately the same thickness and same density as a foam polystyrene foam sheet blown with the fully halogenated chlorofluorocarbon CFC-12. In addition the foam sheet produced from the 100 percent CO₂ blowing agent under these conditions has a smooth, uniform surface similar to that of foam sheet manufactured with aliphatic hydrocarbons and fully or partially halogenated hydrocarbons.

A typical set of cell sizes for 100 percent CO₂ blown foam sheet in the machine direction is 0.39 mm; cross direction is 0.33 mm; vertical direction is 0.28 mm. For the CFC-12 blown foam sheet, typical cell sizes are in the machine direction 0.28 mm; in the cross direction 0.33 mm; in the vertical direction 0.22 mm.

Figures 1 and 2, with a different example and comparative example (density of 5.1 PCF (81 kg/m³) for the CO₂ blown foam sheet and 5.4 PCF (86 kg/m³) for the CFC-12 blown sheet), also show an unexpected benefit when foam sheet is produced using only carbon dioxide as the blowing agent. The benefit is that the percent elongation in both the machine (Figure 1) and transverse (Figure 2) directions remains essentially constant, or at worst, decreases only slightly over time after a short initial aging period.

As Figures 1 and 2 show the tensile elongation values remain substantially constant for the CO₂ blown foam sheet, with only a 9.3 percent change in the machine direction from the period of time of 24 hours to 313 hours and only a 7.4 percent change in the cross direction during the same period.

In contrast, when using CFC-12 as the blowing agent, the percent elongation decreased drastically and substantially over the same time period after the same short initial aging period. Figures 1 and 2 show that the CFC-12 blown foam changed 29.0 percent in the machine direction and 15.2 percent in the cross direction for the period of time of 18.5 hours to 330 hours.

The tensile elongation values preferably vary by no more than 15 percent over an extended period of time under ambient conditions in both a machine and a cross direction after an initial aging period, and the tensile elongation values are preferably greater than or equal to about five percent over an extended period of time under ambient conditions in both a machine and a cross direction.

Also in Figures 1 and 2 the percent elongation in both directions is above five percent for an extended period of time only when carbon dioxide is used as the blowing agent.

The CO₂ blown foam sheet exhibits a machine direction tensile elongation of 6.8 percent and a cross direction tensile elongation of 6.3 percent after 313 hours of aging. The CFC-12 blown foam has a machine direction tensile elongation of 4.4 percent and a cross direction tensile elongation of 3.0 percent after 330 hours of aging.

Tensile elongation values below five percent are generally considered to be brittle and not acceptable for thermoforming purposes.

Tensile elongation values for the foam sheet which change at a rapid rate over an extended time make a determination as to when to thermoform the foam sheet difficult, and in addition, the foam sheet becomes brittle and difficult or impossible to thermoform when the tensile elongation values are less than five percent.

The product of the present invention has elongation values which remain constant, or at worse, decline only slightly over a long period of time. This means, as shown in Figures 1 and 2, that foam sheet stored on a roll and waiting to be thermoformed will have approximately the same elongation values at the thirty hour mark as at the one hundred sixty hour mark. This is not true for foam sheet produced with dichlorodifluoromethane and other types of aliphatic hydrocarbon and fully or partially halogenated hydrocarbon blowing agents.

Corrugation

It is also possible with the present invention to make 3-6 PCF foam sheet blown with CO₂ having little or no corrugation.

For the purpose of definition "little or no corrugation or noncorrugated" means that the thickness values for peaks and valleys are averaged, the overall average is determined by averaging the peak and valley averages and the difference between the overall average and the peak and valley average is less than about fifteen (15) percent.

In Table 2 Sheets 1, 2 and 3 have a blow-up ratio of 3.5:1. The weight percent CO₂ is 2.3 for Sheet 1; 2.0 for Sheet 2; and 1.3 for Sheet 3. The die temperature is 146°C( centigrade) for Sheet 1; 141°C for Sheet 2; and 144°C for Sheet 3. TABLE 2

Corrugation in mils (mm)
Sheet 1		Sheet 2		Sheet 3
3.77 PCF		3.60 PCF		5.75 PCF
Peak	Valley	Peak	Valley	Peak	Valley
141 (3.58)	94 (2.39)	105 (2.67)	84 (2.13)	87 (2.21)	81 (2.06)
154 (3.91)	101 (2.57)	105 (2.67)	88 (2.24)	88 (2.24)	85 (2.16)
171 (4.36)	108 (2.74)	108 (2.74)	89 (2.26)	92 (2.34)	99 (2.51)
127 (3.22)	89 (2.26)	103 (2.61)	90 (2.29)	87 (2.21)	95 (2.29)
				85 (2.16)	86 (2.18)

TABLE 2

AVG.	AVG.	AVG.	AVG.	AVG.	AVG.
148 (3.76)	98 (2.49)	105 (2.67)	88 (2.24)	88 (2.24)	89 (2.26)

TABLE 2

Average of Peak and Valley
123 (3.12)		96.5 (2.45)		88.5 (2.25)

TABLE 2

Difference Based on AVG
20 percent		8.8 percent		0.6 percent

As can be seen from Table 2, with the value in mils (mm), the corrugation of Sheet 1 is 20 percent. This corrugation is visibly noticeable and this level of corrugation makes this sheet unsuitable for many thermofoaming operations. Sheets 2 and 3 are acceptable. As can be seen the corrugation is 8.8 and 0.6 percent respectively, well below the 15 percent level. The difference between Sheet 1 and Sheets 2 and 3 is visibly noticeable and measurements confirmed the visual evidence.

As is clear in these examples, corrugation can be minimized or even prevented by controlling the die temperature and amount of blowing agent when using 100 percent carbon dioxide as a bowing agent.

Post Expansion (Thermoforming)

Polystyrene foam sheet 5.0 PCF (80 Kg/m³) and 100 mils (2.54 mm) thick, blown with carbon dioxide, is thermoformed into egg cartons in a thermoformer. Prior to being thermoformed the foam sheet is heated in an oven for 5, 6 or 7 seconds as detailed in Figure 3. The oven temperatures are about 500°F (Fahrenheit) (260°C) in the bottom of the oven and about 600°F (316°C) in the top of the oven.

Figure 3 shows that although the percent of puff or post expansion is sensitive to the amount of time in the oven, generally the amount of puff can be as much as 20 to 50 percent.

The present invention has been described with preferred embodiments. It is to be understood however that modifications and variations from the preferred embodiments may be resorted to, without departing from the scope of the invention, as those skilled in the art will readily understand, within the scope of the appended claims.

Claims (14)

1. A process for producing a thermoplastic foam comprising the following steps:

   a. melting a styrenic polymer;

   b. continuously directly introducing into the melted styrenic polymer a blowing agent consisting of carbon dioxide in an amount of 0.5 to 6 weight percent by weight of the polymer;

   c. mixing intimately the styrenic polymer and the carbon dioxide; and

   d. extruding and foaming the mixture at a die temperature below 150°C into a region of lower pressure to form thermoplastic foam sheet, wherein the resulting thermoplastic foam has a cell size in any direction which is less than lmm, and sheet thickness of less than 0.5" (1.25cm).
2. The process for producing a thermoplastic foam, as recited in Claim 11, wherein the carbon dioxide is introduced in the polymer melt as a liquid.
3. A process as claimed in Claim 1 or Claim 2, including the step of thermoforming the thermoplastic foam into articles.
4. A process as claimed in any one of Claims 1 to 3, including the step of passing the thermoplastic foam over a forming mandrel having a blow up ratio of greater than 2.0:1 immediately after step d.
5. A process as claimed in any one of Claims 1 to 4, including the step of aging the thermoplastic foam, after step d. and prior to thermoforming.
6. A process as claimed in Claim 5, wherein the said aging is carried out until the thermoplastic foam has tensile elongation values which vary by no more than 15 percent over an extended period of time under ambient conditions in both a machine and a cross direction after an initial aging period and the tensile elongation values are greater than or equal to five percent over an extended period of time under ambient conditions in both a machine and a cross direction.
7. A process as claimed in any one of Claims 1 to 6, wherein the styrenic polymer is polystyrene.
8. A process as claimed in any one of Claims 1 to 7, wherein the die temperature in step d. is from 130° to 145°C.
9. A process as claimed in any one of the preceding Claims, wherein the process is carried out such that the resulting thermoplastic foam has corrugation less than fifteen percent.
10. A process as claimed in any one of the preceding Claims, wherein the thermoplastic foam has a density of 2 to 10 pounds per cubic foot (32 to 160 kg/m³).
11. A process as claimed in Claim 10, wherein the thermoplastic foam has a density of 3 to 6 pounds per cubic foot (48 to 96 kg/m³).
12. A process as claimed in any one of the preceding Claims, wherein the thermoplastic foam sheet has a thickness less than 0.25" (0.63 cm).
13. A process as claimed in any one of the preceding Claims, wherein the thermoplastic foam has a cell size, in any direction of less than 0.5mm.
14. A process as claimed in any one of the preceding Claims, wherein the thermoplastic foam has a blow-up ratio of at least 2.0:1.