Method for compression-molding foamed polymer article

Abstract

The present invention provides a method for compression-molding a foamed polymer article, where compared with the shape of a final product to be molded, a foamed blank article has a redundant protruding part at a particular position, which is different from the shape of the final product; and when the foamed blank is hot-melt-molded again by using a mold, an external force is applied to compress the redundant protruding part to reduce the volume and increase the density, so that the final product obtained has a higher density at the position corresponding to the redundant protruding part than other parts. Thereby, the final product can have different densities at different positions, so as to meet the requirements in practical application.

Claims

1. A method comprising the steps of: placing a prefoamed blank article into a mold cavity inside a mold, hot-melt-molding the prefoamed blank article in the mold cavity, and cooling and setting to give a final product; wherein the mold further comprises an extension cavity, adjacent to and in communication with the mold cavity and having an inner dimension smaller than an equivalent inner dimension of the mold cavity, and a movable member movable in the extension cavity under an external force; wherein in the step of placing the prefoamed blank article into the mold cavity inside the mold, the prefoamed blank article is a prefoamed article having a first block and a second block that are integrally molded, the first block of the prefoamed blank article is a three-dimensional quadrilateral block, the second block protrudes out of a central part of the first block, when the prefoamed blank article is inside the mold, the first block of the prefoamed blank article is located inside the mold cavity and the second block of the prefoamed blank article is located inside the extension cavity between the movable member and the first block; wherein in the step of hot-melt-molding the prefoamed blank article, the external force is applied to cause the movable member to move inside the extension cavity, the moveable member exerting a pressure on the second block causing the second block to move toward the mold cavity and compressing the second block and the central part of the first block, wherein when being compressed, the second block partially or completely moves from the extension cavity into the mold cavity such that the central part of the first block is compressed together with the second block, and wherein a region of the final product in which the first block is compressed together with the second block has a density different from regions of the final product in which the first and second blocks are not compressed together.

2. The method according to claim 1, wherein the first block fills up a space of the mold cavity.

3. The method according to claim 1, wherein the second block fills up a space of the extension cavity before being compressed by the movable member.

4. The method according to claim 1, wherein the pressure exerted by the movable member to compress the second block is maintained until the cooling procedure.

5. The method according to claim 1, wherein the first block and the second block are made of a same raw material.

6. The method according to claim 1, wherein the movable member is a slide block, and is capable of reciprocating displacement inside the extension cavity under the external force.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a schematic flow chart of a preferred embodiment of the present invention.

(2) 10: mold; 11: upper mold; 12: lower mold; 13: mold cavity; 14: extension cavity; 15: movable member; 20: blank article; 21: first block; 211: local part of first block; 22: second block; 30: final product.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(3) Herein, a preferred embodiment of the present invention is given and illustrated in detail with reference to the accompanying drawings.

(4) A method for compression-molding a foamed polymer article that is provided in a preferred embodiment of the present invention includes the following steps:

(5) Step a: Providing a mold 10.

(6) The mold 10 has: an upper mold 11 and a lower mold 12 that are vertically stacked; a mold cavity 13 between the upper mold 11 and the lower mold 12; an extension cavity 14, provided inside the lower mold 12, having one end in communication with the mold cavity 13, and having an inner diameter smaller than the inner diameter of the mold cavity 13; and a movable member 15, which is a slide block slidably connected to a circumferential wall of the extension cavity 14 by means of its circumferential end face, and capable of reciprocating linear displacement inside the extension cavity 14 toward or away from the mold cavity under an external force.

(7) Step b: Opening the mold.

(8) The upper mold 11 and the lower mold 12 are separated apart from each other, so as to expose the mold cavity 13 and the extension cavity 14.

(9) Step c: Filling.

(10) A prefoamed blank article 20 is placed into the mold 10 in the open state, so that a first block 21 of the blank article 20 is located inside the mold cavity 13, and a second block 22 of the blank article 20 protrudes out of a local part 211 of the first block 21 and is embedded in the extension cavity 14.

(11) The first block 21 and the second block 22 of the blank article 20 are a foam formed by integral molding of a same raw material. Specifically, the first block 21 is a three-dimensional quadrilateral block, and the second block 22 protrudes out of the local part 211 of the first block 21.

(12) Step d: Closing the mold.

(13) The upper mold 11 and the lower mold 12 are closed, so that the first block 21 fills up the mold cavity 13, and the second block 22 is embedded in the extension cavity 14 and between the mold cavity 13 and the movable member 15.

(14) Step e: Heating, applying pressure, and melt-molding.

(15) Heat and pressure are provided to the mold 10 to increase the temperature of the blank article 20, so that the blank article 20 can be heated and melt inside the mold 10 and takes the shape of the mold cavity 13.

(16) Step f: Forming different densities.

(17) When the melt-molding procedure in the step e is carried out to such an extent that the blank article 20 can be molded, an external force is applied to drive the movable member 15 to move toward the mold cavity 13, so as to push the second block 22 toward the mold cavity 13, so that the second block 22 can be moved from the extension cavity 14 into the mold cavity 13. As the second block 22 moves, the local part 211 of the first block is continuously compressed. Thereby, a force can be applied to the second block 22 by means of the movable member 15, to compress the second block 22 and the local part 211 of the first block, so as to increase the density of these parts.

(18) In this embodiment, the external force is continuously applied to the movable member 15 until the movable member 15 moves to the junction between the extension cavity 14 and the mold cavity 13. When the movable member 15 moves to the junction and blocks the communication between the extension cavity 14 and the mold cavity 13, the second block 22 is completely pushed into the mold cavity 13. Thereby, the blank article 20 can have different densities at different parts.

(19) Step g: Cooling.

(20) After the blank article 20 is molded in the mold 10 into the shape of the mold cavity 13 and the densities of the second block 22 and the local part 221 of the first block adjacent to the second block 22 are controlled by means of the movable member 15, the remolded blank article 20 can be cooled and set by means of water cooling, air cooling or other cooling methods, so as to obtain a multi-density final product 30 of the same shape as that of the mold cavity 13.

(21) Thereby, although the blank article fabricated in advance in the foaming procedure has similar densities at different parts due to its fixed expansion ratio, the implementation of the above-mentioned method can change the blank article originally having a single density into an article having different densities at different parts. Compared with the prior art where a multi-density foamed article is fabricated by means of joining, the technical content provided in the present invention can improve the quality of the final product.

(22) In addition, in the prior art, the size of the blank article is increased in order to ensure the integrity of the final product. When the blank article is squeezed into the space of the mold cavity of the secondary processing mold with a small volume, the change in density is not sufficient because the difference between the size and the volume is not large enough. In other words, as only a small compression effect is achieved by means of the difference between the size and the volume, there is no teaching or disclosure in the prior art about changing the density by means of the difference between the size and the volume. Therefore, the present invention has an inventive step as compared with the prior art.