Supporting mechanism for pressure thermoforming machine

Abstract

Claims

1. A pressure thermoforming machine, comprising: a lower bracket having a molding half moveably supported thereon; an upper bracket securely connected to the lower bracket, an upper molding half being moveably supported thereon; supporting means arranged between the lower molding half and the lower bracket such that the lower molding half is supported to prevent any unbalancing during molding process.

2. The pressure thermoforming machine as recited in claim 1, wherein the supporting means includes rollers securely attached to the lower molding half, and driving blocks attached to the lower bracket, each driving block including an inclined surface with respect to the roller.

3. The pressure thermoforming machine as recited in claim 2, wherein the driving blocks are arranged opposite to each other such that when the driving blocks move toward each other, the lower molding half is driven upward by the arranged between the rollers and the inclined surface.

4. The pressure thermoforming machine as recited in claim 1, wherein the supporting means includes a pair of driving blocks oppositely on the lower bracket, the driving blocks being moveably connected to move simultaneously toward and away from each other.

5. The pressure thermoforming machine as recited in claim 4, wherein said driving blocks are connected by rack and gear to move simultaneously to push the lower molding half upward when the driving blocks move toward each and lower the lower molding half down when the driving blocks move away from each other.

6. The pressure thermoforming machine as recited in claim 2, wherein the inclined surface of the driving block includes several sections.

7. A pressure thermoforming machine, comprising: a lower bracket having a molding half moveably supported thereon; an upper bracket securely connected to the lower bracket, an upper molding half being moveably supported thereon; driving blocks moveably and oppositely mounted on the lower bracket, each driving block including an inclined surface, said driving blocks being moveably interconnected such that the driving blocks move toward and away from each other simultaneously; rollers mounted on the lower molding half and supported by the inclined surface of the driving block such that the lower molding half moves upward when the driving blocks move toward each other, and lower downward when the driving blocks move away from each other.

8. The pressure thermoforming machine as recited in claim 7, wherein the driving blocks are interconnected by racks and gears such that the driving blocks move simultaneously.

9. A pressure thermoforming machine, comprising: a lower bracket having a molding half moveably supported thereon; an upper bracket securely connected to the lower bracket, an upper molding half being moveably supported thereon; driving blocks moveably mounted on each side of the lower bracket, each driving block including an inclined surface, driving blocks on both sides being moveably conjugated interconnected such that the driving blocks move toward and away from each other simultaneously; rollers mounted on the lower molding half and supported by the inclined surfaces of the driving blocks such that the lower molding half moves upward when the driving blocks move toward each other, and lower downward when the driving blocks move away from each other.

Description

[0001] The present invention relates to a supporting mechanism, and more particularly to a supporting mechanism for a pressure thermoforming machine.

DESCRIPTION OF THE PRIOR ART

[0002] As showing in FIG. 4, a conventional pressure thermoforming machine generally includes a lower bracket (b) and an upper bracket (a) corresponding to the lower bracket (b). A lower molding half (f) moveably driven by a lower cylinder (e) is mounted on the lower bracket (b); while an upper molding half (d) moveably driven by an upper cylinder (c) is mounted on the upper bracket (a). The upper and lower molding halves (d, f) are moved toward each other for forming an article therebetween, and moved away from each other for releasing the formed article therefrom.

[0003] Once the upper and lower molding halves (d, f) are closed, a molding cavity defined therebetween is undergone a vacuuming process such that a molten material can adequately flow to completely fill the cavity. In case of an asymmetric molding cavity, after the molten material filled in the cavity, an unbalanced situation of the lower molding half (f) will be encountered since the lower molding half (f) is simply supported by a piston of the lower cylinder (e). As a result, the unbalanced situation of the lower molding half (f) will cause separation of the upper and lower molding halves (d, f) such that the article formed therebetween will become defective, for example, a gap generated therefore will cause a variation of dimension of the article.

SUMMARY OF THE INVENTION

[0004] It is an object of this invention is to provide a supporting mechanism for a pressure thermoforming machine in which a lower molding half is adequately supported to prevent any unbalanced situation during molding process.

[0005] In order to achieve the object set forth, a pressure thermoforming machine in accordance with the present invention comprises a lower bracket having a molding half moveably supported thereon. An upper bracket is securely connected to the lower bracket. An upper molding half is moveably supported thereon. Driving blocks are moveably and oppositely mounted on the lower bracket. Each driving block includes an inclined surface and the driving blocks are moveably interconnected such that the driving blocks move toward and away from each other simultaneously. Rollers are mounted on the lower molding half with respect to the inclined surface of the driving block such that the lower molding half moves upward when the driving blocks move toward each other, and lower downward when the driving blocks move away from each other.

SUMMARY OF THE DRAWINGS

[0006] Other objects and further features of the present invention will be apparent from the following detailed description when read in conjunction with the accompanying drawings, in which:

[0007] FIG. 1 is a side elevational view of a pressure thermoforming machine in accordance with the present invention;

[0008] FIG. 2 is a top view of FIG. 1;

[0009] FIG. 3 is a driving block in accordance with a second embodiment of the present invention; and

[0010] FIG. 4 is a side elevational view of a conventional pressure thermoforming machine.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0011] Referring to FIGS. 1 to 3, a pressure thermoforming machine in accordance with the present invention includes an upper bracket 1 and a lower bracket 2. An upper molding half 11 is moveably mounted to the upper bracket 1, while a lower molding half 21 is moveably mounted on the lower bracket 2 by means of a supporting mechanism 3.

[0012] The supporting mechanism 3 includes four rollers 31 mounted on corners of the lower molding half 21. Each roller 31 is rotationally supported on a driving block 32 moveably mounted on the lower bracket 2. Each driving block 32 is further provided with a rack 33 moveably conjugated with to a driving rack 33a by means of a gear 34. The driving rack 33a is then connected to a piton 361 of a cylinder 36.

[0013] There are totally four driving blocks 32 mounted on the lower bracket 2, two on each side. As shown in FIG. 2, each driving block 32 is provided with a rack 33 on an inner wall thereof. In order to make those two driving blocks 32 to move simultaneously, the inner rack 33 of the driving block 32 is connected to a corresponding driving rack 33a by means of a corresponding gear 34. The driving racks 33a are then connected to the piston 361 of the cylinder 36. By this arrangement, when the driving racks 33a are moved by the piston 361, the driving blocks 32 are moved simultaneously.

[0014] As described above, each side of the lower bracket 2 is provided with two driving blocks 32 which move toward and away from each other by the control of the piston 361 of the cylinder 36. When the opposite driving blocks 32 are moved toward each by the actuation of the piston 361 of the cylinder 36, the lower molding half 21 is moved upward because inclined surfaces 321 of the driving block 32 move into bottom of the lower molding half 21. From another point of view, if we take driving block 32 as stationary without moving, it looks like that the roller 31 climbs upward along the inclined surface 321. By the arrangement, when four driving blocks 32 are moved toward each other simultaneously, the lower molding half 21 is driven upward. To the contrary, when the driving blocks 32 move away from each other, the lower molding half 21 lowers down as the rollers 31 roll down along the inclined surface 321.

[0015] The upper molding half 11 is driving by a cylinder 12 to move toward and away the lower molding half 21.

[0016] Since the lower molding half 21 is adequately supported by the arrangement of the rollers 31 and the driving blocks 32, the lower molding half 21 is kept in a leveling position during upward and downward movements. In addition, since the lower molding half 21 is supported by its four corners, the lower half molding 21 can bear more downward load, especially when the molding cavity is design asymmetrically. By this arrangement, the problem encountered by the prior art is completely solved. As a result, the upper and lower molding halves 11, 21 are correctly engaged during molding process, burrs resulted gab between halves 11, 21 are completely prevented.

[0017] In addition, since the lower molding half 21 is supported by the inclined surfaces 321 of the driving block 32, the driving power of the piston 36 can be also reduced thereby saving more electricity and reducing cost.

[0018] Referring to FIG. 3, the inclined surface 321 can be arranged into different sections 321 thereby lifting up the lower molding half 21 in different speed.

[0019] It will be understood that the invention may be embodied in other specific forms without departing from the spirit or central characteristics thereof. The present examples and embodiments, therefore, are to be considered in all respects as illustrative and not restrictive, and the invention is not to be limited to the details given herein.