JP2551854B2 - Forming method of expanded polyethylene terephthalate sheet - Google Patents

Description

TECHNICAL FIELD The present invention relates to a molding method for molding a foamed polyethylene terephthalate sheet into a predetermined shape.

<Prior art> In order to impart heat resistance to a molded product such as a tray that has been conventionally produced by forming a foamed polystyrene sheet, a foamed polyethylene terephthalate sheet (foamed PET sheet) is used instead of the foamed polystyrene sheet. Various attempts have been made.

In order to form the foamed PET sheet into a predetermined shape, usually, the sheet is preheated to a temperature at which it can be formed by passing through an oven or the like, and then the preheated sheet is used with a mold having a predetermined shape. Is being molded.

<Problems to be Solved by the Invention> However, in the above method, since the thermal efficiency of preheating by the oven is low, the heat-insulating property is high, and the foamed PET sheet having a small specific heat is set in the oven in order to sufficiently preheat it to the inside. You have to raise the temperature. However, if the set temperature in the oven is set higher than the crystallization temperature of the foamed PET sheet, before the inside of the sheet is sufficiently preheated,
Crystallization of the surface of the sheet progresses, the elongation of the sheet deteriorates, and molding failure may occur. Further, in the preheating by the oven, the sheet cannot be preheated uniformly,
There is a possibility that heating unevenness may occur and a partial molding defect may occur. Therefore, it is conceivable to set the temperature in the oven lower than the crystallization temperature of the foamed PET sheet to prevent the progress of crystallization, and to lengthen the preheating time to prevent uneven heating. However, in that case, there is a problem that productivity is lowered, a long oven is required, an apparatus becomes large in size, and cost is increased.

Further, the mold for molding the expanded PET sheet preheated by the oven, like the mold in the conventional expanded polystyrene sheet, at room temperature, the crystallinity of the obtained molded product is insufficient. Therefore, sufficient heat resistance cannot be obtained. Therefore, it is conceivable to heat the mold, but in that case, it takes a long time to cool the molded product, and there is a problem that productivity is reduced. It is possible to forcibly cool the molded product with cooling air or the like, but in that case, uneven cooling may occur and the molded product may be deformed.

The present invention has been made in view of the above circumstances, and a molded article made of a foamed PET sheet, which has excellent heat resistance, can be manufactured with high productivity and low cost without causing defective molding. It is an object of the present invention to provide a method for forming a foamed PET sheet that enables the above.

<Means for Solving the Problems> In order to solve the above problems, the method for forming a foamed PET sheet of the present invention is a foamed PET sheet having a low crystallinity, at a temperature not higher than the temperature for promoting crystallization of the sheet, And by sandwiching with a pair of surface heating plates heated to the temperature required for molding,
Preheating necessary for molding is performed to the inside of the sheet without promoting crystallization of the surface of the sheet, and then the sheet is formed into a predetermined shape by a pair of molds heated to a temperature that promotes crystallization of the sheet or more. It is characterized in that it is molded into, and then cooled by a pair of molds maintained at a temperature required for molding or lower.

<Function> According to the method for forming a foamed PET sheet of the present invention having the above-described configuration, the foamed PET sheet is sandwiched between a pair of surface heating plates, and the surface contact preheats the temperature to a temperature required for molding. Therefore, the thermal efficiency of preheating is high. Further, since the surface heating plate is heated to a temperature that is below the temperature that promotes crystallization of the sheet and to a temperature necessary for molding, it preheats sufficiently to the inside without promoting the crystallization of the sheet surface. be able to. Since the preheated sheet is molded by a pair of molds heated to a temperature that promotes crystallization of the sheet, the obtained molded article has high crystallinity,
It has excellent heat resistance. Further, since the molded product molded by the mold is cooled by the pair of molds maintained at the temperature required for molding or less, the molded product is cooled in a short time without causing uneven cooling and deformation.

<Example> An example of a method for molding a foamed PET sheet according to the present invention will be described below with reference to the drawings showing an example of a molding apparatus used for carrying out the method.

FIG. 1 shows an example of the molding apparatus 1, and the molding apparatus 1 includes a preheating unit 3 for preheating the foamed PET sheet S.
A heating mold 4 for molding the foamed PET sheet S preheated in the preheating part 3; and a foamed PE formed by the heating mold 4.
A cooling die 5 for cooling the T-sheet S, and a feeding / conveying portion 2 for intermittently conveying the foamed PET sheet S supplied from the rewinding roll to the preheating portion 3, the heating die 4, and the cooling die 5. It is equipped with. The preheating unit 3, the heating mold 4, and the cooling mold 5 are arranged at equal intervals along the feeding direction of the foamed PET sheet S by the feeding and feeding unit 2. Then, while the foaming PET sheet S is intermittently transported by the supply transporting section 2, the preheating section 3, the heating die 4, and the cooling die 5 preheat and form different parts of the foaming PET sheet S. The steps of crystallization, crystallization, and cooling are performed almost simultaneously.

The supply / conveyance unit 2 supplies the shaft 21 to which the rewind of the foamed PET sheet S is mounted, a pair of supply rollers 22 for unwinding the foamed PET sheet S from the rewind, and the unwound foamed PET sheet S to the conveyance path. Conveyor that sequentially and intermittently conveys to the preheating unit 3, the heating mold 4, and the cooling mold 5 along
23, and a cutter 24 provided at the end of the conveyor 23 for cutting the foamed PET sheet S after molding. The transport conveyors 23 are provided on both sides of the transport path of the sheet S so that both side edges of the foamed PET sheet S can be held between them.

The preheating unit 3 is a foamed PE conveyed by the supply and conveyance unit 2.
The T-sheet S is composed of a pair of surface heating plates 31 and 32 arranged above and below the T-sheet S so as to face each other. The surface heating plates 31, 32 are
The heating die 4 described later is formed to have a size that covers the entire area where one molding is performed.

The heating die 4 is disposed above and below the foamed PET sheet S so as to face each other, and is composed of a cavity 41 and a core 42 for molding the foamed PET sheet S preheated by the preheating unit 3 into a predetermined shape, and a vacuum. Molding and other known sheet molding methods are used.

The cooling die 5 is composed of a cavity 51 and a core 52, which are arranged above and below the foamed PET sheet S so as to face each other and have the same shape as the heating die 4.

A surface heating plate 31, which is located above the foamed PET sheet S, among the preheating unit 3, the heating mold 4, and the cooling mold 5.
The cavity 41 and the cavity 51 are a pair of drive units 61, 6 provided above and below the conveyance path of the foamed PET sheet S.
Of the two, on the support portion 61a of the upper drive portion 61, they are arranged at equal intervals along the conveying direction of the foamed PET sheet S, and are integrally moved up and down by the drive of the hydraulic cylinder 61b.

Further, the surface heating plate 32, the core 42, and the core 52, which are arranged below the foamed PET sheet S, are respectively attached to the supporting portion 62a of the lower drive unit 62, the surface heating plate 31, the cavity 41, and
Further, they are arranged at equal intervals along the conveyance direction of the foamed PET sheet S so as to correspond to the cavities 51, and are moved up and down integrally by driving the hydraulic cylinder 62b.

The method of molding the foamed PET sheet S of the present invention using the molding apparatus 1 is generally performed in the following steps.

First, the roll of the foamed PET sheet S is mounted on the shaft 21 of the supply / conveyance unit 2.

The foamed PET sheet S used in the present invention preferably has a thickness of 1 to 5 mm, a foaming ratio of 2 to 6 times, and a crystallinity of 5 to 13%.

The reason why the thickness of the foamed PET sheet S is preferably 1 to 5 mm is as follows. That is, if the thickness of the foamed PET sheet S is less than 1 mm, it may not be possible to obtain a molded product having a sufficient thickness, depending on the degree of subsequent secondary foaming. On the other hand, if the thickness of the foamed PET sheet S exceeds 5 mm, it may not be possible to sufficiently heat the inside due to the heat insulating property of the foamed PET sheet S.

Further, the reason why the expansion ratio of the expanded PET sheet S is preferably 2 to 6 is as follows. That is, when the expansion ratio of the expanded PET sheet S is less than 2, there is a possibility that a molded product having a sufficient expansion ratio cannot be obtained due to the secondary expansion. On the contrary, the expansion ratio of the expanded PET sheet S is 6
If it exceeds twice, due to the heat insulating property of the foamed PET sheet S,
There is a possibility that the inside cannot be heated sufficiently.

Furthermore, the reason why the crystallinity of the expanded PET sheet S is preferably 5 to 13% is as follows. That is,
If the crystallinity of the foamed PET sheet S is less than 5%, the crystallinity of the foamed PET sheet S cannot be sufficiently increased at the time of molding the foamed PET sheet S by the heating mold 4, and the molded product is inferior in heat resistance. There is a risk of becoming. On the contrary, when the crystallinity of the expanded PET sheet S exceeds 13%, the elongation of the sheet S may be deteriorated and the formability may be deteriorated. The crystallinity is 8 to 11
It is more preferable to be in the range of%.

The crystallinity is the cold crystallization heat amount of the expanded PET sheet S measured by the heat flux differential scanning calorimetry (heat flux DSC) method described in JIS K-7122 "Method for measuring dislocation heat of plastics". It is calculated by the following formula from the heat of fusion.

Crystallinity (%) = [(heat of fusion per mole−heat of cold crystallization per mole) / heat of fusion per mole of completely crystallized PET resin] × 100 As the foamed PET sheet S, one side or both sides thereof It is also possible to use a laminate of a non-foamed film.

Next, the foamed PET sheet S is unwound from the roll by the supply rollers 22 of the supply / conveyance unit 2 and supplied to the preheat component 3. Then, the upper and lower drive parts 61, 62 are driven to heat the foamed PET sheet S to a temperature not higher than the temperature for promoting the crystallization of the foamed PET sheet S and a temperature necessary for molding the foamed PET sheet S. It is held by the pair of surface heating plates 31 and 32 thus prepared and preheated.

The foamed PET sheet S has a thermal deformation temperature (moldable temperature) of 76 ° C. or higher, and when the heating temperature exceeds 150 ° C., crystallization proceeds rapidly in a short time (for example, about 10 seconds). Therefore, the heating temperature of the pair of surface heating plates 31, 32 is preferably in the range of 130 ° C. or higher and lower than 150 ° C., particularly preferably around 140 ° C. . The heating temperature of the pair of surface heating plates 31 and 32 is shortened by shortening the heating time to a temperature suitable for crystallization of the foamed PET sheet S in the molding step described later to shorten the molding cycle. Therefore, it is preferable to set the temperature as close as possible to the crystallization temperature within the above range. The temperatures of the pair of surface heating plates 31, 32 are usually set to be the same,
For example, when a foamed PET sheet in which a non-foamed film is laminated on one surface is used, or the heating temperatures of the upper and lower surface heating plates 31 and 32 may be different depending on the shape of the molded product.

The sandwiching surface pressure of the foamed PET sheet S by the pair of surface heating plates 31 and 32 enables the foamed PET sheet S to be firmly sandwiched by the pair of surface heating plates 31 and 32.
It is preferably 0.15 kg / cm ² or more.

The preheating time of the foamed PET sheet S by the preheating unit 3 is
The optimum range can be selected according to the thickness of the foamed PET sheet S, the expansion ratio, etc. However, when the molding apparatus 1 of FIG. 1 is used, as described above, the preheating section 3 and the heating mold are used. Four
Are simultaneously driven by the same driving units 61 and 62, it is necessary to match the preheating time of the foamed PET sheet S by the preheating unit 3 and the molding time by the heating die 4. Usually, it takes a longer time to crystallize than preheating, and as described above, the preheating by the surface heating plates 31 and 32 does not cause the temperature of the foamed PET sheet to become higher than or equal to the crystallization temperature. Since there is no problem even if it is extended, the preheating time of the foamed PET sheet S by the preheating unit 3 may be extended according to the crystallization time.

Next, the preheating by the preheating unit 3 for a predetermined time is completed,
Of the foamed PET sheet S, the portion held by the surface heating plates 31, 32 is preheated to a temperature at which molding can be performed, and the upper and lower drive units 61, 62 are driven to drive the pair of surface heating plates 31. The holding of the foamed PET sheet S by 32 is released.

When the holding is released, the foamed PET sheet S is secondarily foamed and becomes about 1.8 to 2.4 times the original thickness.

Next, the foamed PET sheet S is conveyed, and the portion preheated by the preheating unit 3 is heated to a temperature higher than the temperature for promoting the crystallization of the foamed PET sheet S. Transport between.

Then, the upper and lower drive parts 61, 62 are driven to shape the above-mentioned portion into a predetermined shape by the cavity 41 and the core 42, and to promote crystallization of the formed expanded PET sheet S. At this time, a new portion of the foamed PET sheet S is supplied to the preheating unit 3, and preheating by the pair of surface heating plates 31, 32 is started.

The steps from the end of preheating by the preheating unit 3 to the start of molding by the heating die 4 described above are performed on the foamed PET sheet S.
It is preferable to carry out the heating within 2 to 3 seconds in order to prevent the preheated portion of (3) from being cooled and to improve the productivity.

As described above, the foamed PET sheet S has a heating temperature of 150 ° C.
When it exceeds, it has a property of increasing the crystallization speed. Therefore, the heating temperature of the heating mold 4 (mold temperature) is
It should be 150 ℃ or higher, but for a short time (around 10 seconds)
In order to surely crystallize the inside of the expanded PET sheet S without unevenness, the heating temperature of the heating die 4 is 160
It is preferably at least ° C. Further, the higher the heating temperature of the heating die 4 is, the shorter the crystallization time can be. However, when the heating temperature exceeds 190 ° C.
The releasability of the sheet S from the heating die 4 deteriorates, and the foamed PET sheet S may adhere to the heating die 4 to cause defective molding. Therefore, the heating temperature of the heating mold 4 is preferably in the range of 160 to 190 ° C. The temperatures of the cavity 41 and the core 42 are usually set to be the same, but similar to the case of the surface heating plates 31 and 32, foamed PET having a non-foamed film laminated on one surface thereof.
The heating temperature may be varied depending on the use of the sheet and the shape of the molded product.

The crystallization time of the foamed PET sheet S by the heating mold 4 varies depending on the heating temperature as described above and also depends on the thickness of the foamed PET sheet S.
In order to fully crystallize the inside of the sheet S, 8 to
It is preferably within the range of 10 seconds.

As described above, the higher the crystallinity,
Although the heat resistance of the molded product improves, if the crystallinity is too high,
There is a possibility that a new physical problem such as a decrease in impact resistance may occur. Considering both heat resistance and impact resistance, the crystallinity of the molded product is preferably around 20%. Therefore, at the time of crystallization by the heating die 4, the crystallization degree of the molded product does not greatly exceed the above 20% while considering the crystallization degree of the foamed PET sheet before crystallization. It is desirable to set the conditions, that is, the combination of the heating temperature and the crystallization time, from the preferable range described above.

The clearance between the cavity 41 and the core 42 of the heating mold 4 is 10 to 20 times larger than the thickness of the foamed PET sheet S secondarily foamed by preheating in consideration of the elongation of the foamed PET sheet S accompanying molding. % Is preferably small.

Next, at the stage when the molding by the heating mold 4 and the crystallization promoting step are completed, the upper and lower driving parts 61, 62 are driven to release the holding of the foamed PET sheet S by the cavity 41 and the core 42.

When the holding is released, the foamed PET sheet S is thirdly foamed. This tertiary foaming is a foamed PET sheet S produced by the preheating unit 3.
Since the preheating temperature of (2) is kept low as described above, it tends to be insufficient, which helps increase the thickness due to secondary foaming and is effective for foaming the molded product to a predetermined thickness.

Then, the foamed PET sheet is conveyed, and the portion molded by the heating mold 4 is maintained at a temperature equal to or lower than the temperature required for molding the foamed PET sheet S. The cavity of the cooling mold 5.
It is conveyed between 51 and the core 42.

Then, the upper and lower drive parts 61, 62 are driven to cool the molded part by the cavity 51 and the core 52. At this time, the foaming PET sheet S is attached to the heating die 4.
Of the above, a new part preheated in the preheating section 3 is supplied,
The molding and crystallization acceleration process is started. Further, a new portion of the foamed PET sheet S fed from the rewind is supplied to the preheating unit 3, and preheating by the pair of surface heating plates 31 and 32 is started.

Since the foamable PET sheet S has a moldable temperature of 76 ° C. or higher as described above, the cooling mold 5 may be cooled to 76 ° C. or lower. But short time (around 10 seconds)
In order to reliably and evenly cool the inside of the foamed PET sheet S, the temperature of the cooling mold 4 should be lower than 70
It is preferably not higher than 0 ° C, more preferably in the range of 40 to 50 ° C.

After the cooling by the cooling mold 5 is completed, the upper and lower driving units 61 and 62 are driven to release the sandwiching of the foamed PET sheet S by the cavity 51 and the core 52 and to convey it.

Then, of the foamed PET sheet S, the molded and cooled portion is cut into a predetermined length by the cutter 24 to complete the molded product. In the case of molding a large number of pieces, trimming may be performed after completion of molding and cooling.

According to the method for forming a foamed PET sheet of this embodiment, which includes the above-described steps, the foamed PET sheet S is formed into a pair of surface heating plates 3
Since it is held between 1 and 32 and its surface contact preheats to the temperature required for molding, the preheating thermal efficiency is high. For this reason,
The foamed PET sheet S can be reliably preheated to the inside in a short time.

The surface heating plates 31 and 32 are heated to a temperature lower than the temperature for promoting the crystallization of the foamed PET sheet S and a temperature necessary for molding, so that the surface of the foamed PET sheet S is not crystallized. Moreover, since the inside can be sufficiently preheated, the preparation for molding can be sufficiently performed, and there is no fear of causing molding failure.

The preheated foamed PET sheet S is the foamed PET sheet S.
Mold 4 heated above the temperature that promotes crystallization of
Since it is molded by the cavity 41 and the core 42, the molded product obtained has high crystallinity and excellent heat resistance.

Further, the molded product molded by the heating mold 4 is
Since it is cooled by the cavity 51 and the core 52 of the cooling mold 5 which is maintained at the temperature required for molding or less, unnecessary foaming is suppressed after molding, and cooling is performed in a short time without causing uneven cooling and deformation. can do.

In the above embodiment, the pair of surface heating plates 3 of the preheating unit 3 are used.
1, 32, the cavity 41 and the core 42 of the heating mold 4, and the cavity 51 and the core 52 of the cooling mold 5 are integrally driven by a pair of upper and lower drive units 61 and 62, respectively. The case where it was used was illustrated.

However, as the molding apparatus 1 for carrying out the present invention, as shown in FIG. 2, it is also possible to use the molding apparatus 1 in which the above respective parts are driven independently of each other.

In the illustrated apparatus, a pair of surface heating plates 31, 32 of the preheating unit 3 among the preheating unit 3, the heating mold 4, and the cooling mold 5 arranged at equal intervals along the conveyance direction of the foamed PET sheet S. Is driven by a pair of hydraulic cylinders 33, 34, and the heating mold 4
Cavity 41 and core 42 of the pair of hydraulic cylinders 43,44
Driven by the cavity 51 of the cooling mold 5, the core 52
Are driven by a pair of hydraulic cylinders 53, 54.

The above apparatus compares the preheating time of the foamed PET sheet by the preheating unit 3, the molding and crystallization time by the heating mold 4, and the cooling time by the cooling mold 5 within a range in which the above steps can be continuously performed. It has the advantage that it can be set freely.

In addition, various modifications can be made without departing from the spirit of the invention.

<Test Example> Test Example 1 A pair of surface heating plates obtained by heating a foamed PET sheet (28 days after production) having a thickness of 1 mm, a foaming ratio of 5.2 times and a crystallinity of 8% to each temperature shown in FIG. Depending on the holding surface pressure 0.19kg / c
It was preheated under the condition of m ² and the thickness was measured after a lapse of a predetermined time.
Results are shown in FIG.

From the results in the figure, when the temperature of the surface heating plate is 150 ° C or higher,
Six seconds after the start of preheating, the thickness of the foamed PET sheet after secondary foaming could be 1.8 times or more that of the original fabric. Further, the higher the temperature of the surface heating plate, the higher the expansion ratio of the secondary expansion.

Test Example 2 A sandwiched surface of a foamed PET sheet having a thickness of 1 mm, a foaming ratio of 5.2 times, and a crystallinity of 10% (28 days after production) was heated to each temperature shown in FIG. 4 by a pair of surface heating plates. Pressure 1.9kg / cm
^The degree of crystallinity after preheating under the condition of ^{2 and} the lapse of a predetermined time was calculated by the above formula from the cold crystallization heat quantity and the melting heat quantity of the foamed PET sheet measured by the above-mentioned heat flux DSC method. In addition, SEIK is used for the measurement of the heat of cold crystallization and the heat of fusion.
Using the differential scanning calorimeter DSC200 manufactured by O company, the data on the heat of fusion per mol of the fully crystallized PET resin is 26.9 in the Polymer Data Handbook (Published by: Baifukan Co., Ltd.).
kJ / mol was adopted.

 Results are shown in FIG.

From the results in the figure, when the temperature of the surface heating plate is 150 ° C or higher,
Crystallization proceeded rapidly from about 6 seconds after the start of preheating, and the crystallinity exceeded 20% at the stage 10 seconds after the start of preheating. On the other hand, when the temperature of the surface heating plate was 130 to 140 ° C, the crystallinity was almost the same as before preheating even after 10 seconds from the start of preheating. From this, in the case of the foamed PET sheet, if the preheating temperature is lower than 150 ° C., crystallization proceeds even if the preheating time is slightly extended due to molding with a heating mold, the crystallization process, etc. It was found that the foamed PET sheet can be preheated to a temperature at which it can be molded without causing any damage.

Test Example 3 Foamed PET with a thickness of 1.0 mm, a foaming ratio of 5.2 and a crystallinity of 10%
The sheet (28 days after production) was held at a holding surface pressure of 1.9 kg / cm ² by a pair of surface heating plates heated to 140 ° C.
Preheated for 6 seconds. The thickness after preheating was 1.7 mm.

Next, the foamed PET sheet is composed of a cavity and a core in which mold cavities are formed in order to form the cross-sectional shape shown in FIG. 6, and is held by a heating mold heated to 180 ° C., and after a predetermined time elapses. , Sheet surface (position A and B in FIG. 6)
Position) and the crystallinity at the central portion in the thickness direction (position C in FIG. 6) were calculated in the same manner as in Test Example 2 above. Results are shown in FIG. In addition, in the figure, ◯ is A in FIG.
The position, ● represents the B position, and ⊚ represents the C position. The thickness of the foamed PET sheet after molding was 2.2 mm.

From the results in the figure, under the above conditions, 8 seconds after the start of molding,
It was found that the inside of the foamed PET sheet could be crystallized almost uniformly.

<Specific Example> Hereinafter, the present invention will be described with reference to specific examples and comparative examples.

Example 1 Foamed PET sheet (thickness 1.6mm, width 64c)
m) of the rewinding, the feeding and conveying section 2 of the molding apparatus 1 shown in FIG.
It was attached to the shaft 21 of.

* Properties of foamed PET sheet Crystallinity: 8% Foaming ratio: 5.2 times Density: 0.25g / cm ³ Raw fabric weight: 400g / m ² Next, a pair of the above-mentioned foamed PET sheets heated to 140 ° C Preheating was performed by the surface heating plates 31 and 32 under the condition of the clamping surface pressure of 0.34 kg / cm ² for 6.6 seconds. The thickness after preheating was 2.3 mm.

Next, the preheated foamed PET sheet is 202 mm long and 129 m wide.
It is composed of a cavity 41 and a core 42 in which a mold cavity is formed to form a tray shape having a concave portion with a depth of 35 mm and a depth of 180 mm.
Molding was performed by a heating mold 4 (mold clearance 2 mm) heated to 0 ° C., and crystallization of the expanded PET sheet was promoted. With the heating die 4, the molding cycle from mold closing to pressing (press time is the same as preheating time of 6.6 seconds), mold opening and sheet conveyance is 1 cycle 8 seconds, and the thickness of the foamed PET sheet after crystallization is It was 2.6 mm.

Next, the foamed PET sheet molded in the above shape was cooled by a cooling mold having the same shape as the heating mold and maintained at 55 ° C. The cooling cycle by the cooling mold 5 was 8 seconds per cycle (of which, the pressing time was 6.6 seconds), like the molding cycle by the heating mold 4.

Then, after cooling, the foamed PET sheet was cut into a predetermined length by a cutter 24 to obtain a molded product. The thickness of the obtained molded product was 2.2 mm.

The obtained molded product did not show molding defects and was molded into a predetermined shape and had an average crystallinity in the thickness direction.
It was as high as 22% and had excellent heat resistance.

Comparative Example 1 The same foamed PET sheet as in Example 1 above was used to manufacture a molded product by a conventional method using a tunnel oven and a molding die at room temperature, and the temperature inside the oven was set to 220 ° C. In some cases, the crystallization of the surface of the sheet proceeded before molding, the elongation of the sheet deteriorated, and molding defects frequently occurred. Moreover, when the temperature in the oven was lowered to 150 ° C. to manufacture a molded product, one cycle required 30 seconds, and the production efficiency was lowered. Further, the obtained molded product had a low average crystallinity in the thickness direction of 13% and had insufficient heat resistance. Furthermore, when the mold was heated to 180 ° C. for molding, and the molded product was forcibly cooled by cooling air, the heat resistance of the molded product was improved, but deformation frequently occurred during cooling.

Example 2 A foamed PET sheet (thickness 1.25 mm, width 64 cm) having the following properties, with a non-foamed PET sheet laminated on one side
The winding roll of No. 1 was attached to the shaft 21 of the supply / conveyance unit 2 of the molding apparatus 1 shown in FIG.

* Properties of foamed PET sheet Total weight of raw fabric: 415g / m ² · Foamed sheet part Thickness: 1.20mm Crystallinity: 9% Foaming ratio: 4.7 times Density: 0.28g / cm ³ · Non-foamed film part thickness : 50 μm Crystallinity: 7% Next, the above-mentioned foamed PET sheet was laminated at 145 ° C,
A pair of surface heating plates 31, the non-laminating side of which was heated to 140 ° C,
32, preheating was performed for 7.5 seconds under the condition that the holding surface pressure was 0.34 kg / cm ² . The thickness after preheating was 2.3 mm.

Next, the preheated foamed PET sheet is 202 mm long and 129 m wide.
It is composed of a cavity 41 and a core 42 in which a mold cavity is formed to form a tray shape having a concave portion with a depth of 35 mm and a depth of 180 mm.
By the heating die 4 heated to 0 ° C., the laminate side was formed with the cavity 41 facing, and the crystallization of the foamed PET sheet was promoted. From the mold closing to pressing with the above heating mold 4 (pressing time is the same as preheating time 7.5
Seconds), the molding cycle from mold opening to sheet conveyance is 8.9 seconds per cycle, and the thickness of the foamed PET sheet after crystallization is 2.2 mm.
Met.

Next, the foamed PET sheet molded in the above shape was cooled by a cooling mold having the same shape as the heating mold and maintained at 40 ° C. The cycle of cooling by the cooling die 5 was 8.9 seconds per cycle (of which the pressing time was 7.5 seconds), like the molding cycle by the heating die 4.

Then, after cooling, the foamed PET sheet was cut into a predetermined length by a cutter 24 to obtain a molded product.

The obtained molded product did not show molding defects and was molded into a predetermined shape, and the average degree of crystallinity in the thickness direction of the foamed sheet portion was as high as 23%, and it was excellent in heat resistance. It was

Comparative Example 2 When the same foamed PET sheet as in Example 2 above was manufactured by a conventional method using a tunnel oven and a molding die at room temperature, the temperature inside the oven was set to 220 ° C. In this case, the crystallization of the surface of the sheet progresses before molding, and the elongation of the sheet on the laminate side particularly deteriorates,
Many molding defects occurred. Also, the temperature inside the oven is 160 ℃
When a molded product was manufactured by lowering it to 26 seconds, it took 26 seconds per cycle and the production efficiency decreased. In addition, the obtained molded product is
The average crystallinity in the thickness direction of the foamed sheet portion was as low as 12%, and the heat resistance was insufficient. Furthermore, when the mold was heated to 180 ° C and molded, and the molded product was forcedly cooled by cooling air, the heat resistance of the molded product improved, but shrinkage on the laminate side and non-laminate side Due to the difference in the rate, deformation frequently occurred during cooling.

<Effects of the Invention> The method for molding a foamed PET sheet of the present invention is configured as described above, and the foamed PET sheet having a low crystallinity is at a temperature not higher than the temperature for promoting crystallization and at a temperature required for molding. By holding the heated surface heating plate by the surface contact, the preheating necessary for forming the inside of the sheet is performed without promoting the crystallization of the surface of the sheet. It is possible to reliably preheat the foamed PET sheet of crystallinity to the inside in a short time. As a result, the preparation for molding can be sufficiently performed, and the risk of defective molding can be eliminated.

The preheated foamed PET sheet is molded by a pair of heating dies heated to a temperature that promotes crystallization of the foamed PET sheet, so that the obtained molded article has high crystallinity and heat resistance. It will be excellent.

Further, since the molded product molded by the heating mold is cooled by the pair of cooling molds 5 maintained at a temperature required for molding or less, unnecessary foaming after molding can be suppressed, and cooling unevenness, In addition, the product can be cooled in a short time without causing deformation, and the molded product can be stabilized.

Therefore, according to the method for molding a foamed PET sheet of the present invention, a molded article having excellent heat resistance can be manufactured with high productivity and low cost without causing defective molding.

[Brief description of drawings]

FIG. 1 is a schematic front view showing an example of a molding apparatus for carrying out the method for molding a foamed PET sheet of the present invention, FIG. 2 is a schematic front view showing another example of the molding apparatus, and FIG. 3 is surface heating. Fig. 4 is a graph showing the relationship between the preheating time by the plate and the increase in the thickness of the expanded PET sheet due to secondary expansion. Fig. 4 is a graph showing the relationship between the preheating time by the surface heating plate and the crystallinity of the expanded PET sheet, 5 Fig. 6 is a graph showing the relationship between the thermoforming time by the heating mold and the crystallinity of the foamed PET sheet. Fig. 6 shows Test Example 3
FIG. 6 is a cross-sectional view showing a cross-sectional shape of the molded product in FIG. S ... Foamed PET sheet, 3 ... Preheating part, 31, 32 ... Surface heating plate, 4
... Heating mold, 41 ... Cavity, 42 ... Core, 5 ... Cooling mold, 51 ... Cavity, 52 ... Core.

Claims (2)

(57) [Claims] 1. A sheet surface of a foamed polyethylene terephthalate sheet having a low crystallinity, which is sandwiched by a pair of surface heating plates heated to a temperature lower than the temperature for promoting the crystallization of the sheet and a temperature required for molding. The preheating necessary for molding is performed to the inside of the sheet without promoting the crystallization of the sheet, and then the sheet is formed into a predetermined shape by a pair of molds heated to a temperature that promotes the crystallization of the sheet or more. Then, thereafter, the method for molding a foamed polyethylene terephthalate sheet, which comprises cooling with a pair of molds maintained at a temperature required for molding or less. 2. A pair of surface heating plates obtained by heating a foamed polyethylene terephthalate sheet having a thickness of 1 to 5 mm, a foaming ratio of 2 to 6 times and a crystallinity of 5 to 13% to a temperature of 130 ° C. or higher and lower than 150 ° C. The sheet is fed to a preheating section equipped with, held between the surface heating plates, preheated by the surface contact, and then this sheet is formed into a predetermined shape by a pair of molds heated to 160 to 190 ° C. Then, thereafter, the method for molding a foamed polyethylene terephthalate sheet, which comprises cooling with a pair of molds maintained at 70 ° C. or lower.