CN115847690A

CN115847690A - Die pressing device for heat-conducting silica gel production and die pressing method thereof

Info

Publication number: CN115847690A
Application number: CN202211368379.2A
Authority: CN
Inventors: 潘拥兵; 徐龙; 李康
Original assignee: Kunshan Jin Yue Electronics Co ltd
Current assignee: Kunshan Jin Yue Electronics Co ltd
Priority date: 2022-11-03
Filing date: 2022-11-03
Publication date: 2023-03-28

Abstract

The invention discloses a die assembly for producing heat-conducting silica gel and a die assembly method thereof, wherein the die assembly comprises an open slot, a die assembly body and a die assembly body, wherein the open slot is arranged on a device main body, and a material conveying belt is arranged inside the device main body; the device comprises a device body, a pressure plate, a first hydraulic cylinder, a lifting seat, a lifting cavity, a supporting seat and a lifting seat, wherein the pressure plate is arranged inside the device body; jet-propelled dish, it sets up one side of clamp plate, the top of device main part is provided with the air-cooler subassembly, the air-cooler subassembly sets up with jet-propelled dish intercommunication, and this die assembly combines die pressing mechanism and cooling body to set up, carries out the unloading on the product with the help of the mode of conveyer belt, can cool down the shaping immediately to the product behind the moulding-die, can also carry out the moulding-die to another product when the shaping, greatly increased product moulding-die efficiency, die pressing device effect is better.

Description

Die pressing device for heat-conducting silica gel production and die pressing method thereof

Technical Field

The invention relates to the technical field of heat-conducting silica gel production, in particular to a die assembly for heat-conducting silica gel production and a die assembly method thereof.

Background

The heat-conducting silica gel is a silica gel formed by adding a specific conductive filler on the basis of silicon rubber, is a high-end heat-conducting compound, cannot be solidified, and can avoid risks such as circuit short circuit due to the characteristic of no electric conduction. The heat-conducting bonding sealing silicone rubber is a single-component, heat-conducting and room-temperature curing organosilicon bonding sealant, and is vulcanized into a high-performance elastomer through condensation reaction of moisture in the air to release low molecules to cause crosslinking and curing. The production of the heat-conducting silica gel needs to carry out die pressing treatment on the surface of the heat-conducting silica gel by means of a die pressing device

Chinese patent publication is CN210590189U, and the grant announcement day is 2020 months 05 22 days, a die assembly for heat conduction silica gel production, comprising a box body, the top inner wall and the bottom inner wall of box are fixed with same division board, and the both sides outer wall of division board all is provided with the cold wind dish, the top outer wall of box is provided with the air-cooler, and the output of air-cooler is provided with the pipe, the other end of pipe is connected with two cold wind pipes that the specification is the same through the three-way pipe, and the other end of cold wind pipe sets up in one side inner wall of cold wind dish, the bottom outer wall of box is fixed with moving mechanism, and the top inner wall both sides of box all are provided with die pressing mechanism, the bottom inner wall of box is fixed with the elastic mechanism of equidistance distribution, moving mechanism is including the connecting frame. The utility model discloses a be provided with air-cooler, cold wind dish, pipe and cold air hose, open the air-cooler after carrying out the moulding-die, cool down heat conduction silica gel, the cooling shaping can improve heat conduction silica gel's moulding-die quality.

The existing die assembly is cooled by air cooling on the basis of a die pressing mechanism, the die pressing mechanism adopts a manual feeding and discharging mode, products need to be taken down and replaced after the products are thoroughly molded to carry out die pressing, the product molding time is prolonged by adopting the mode, the feeding and discharging time is increased, the production efficiency of the heat-conducting silica gel is reduced, and the use requirements cannot be met.

Disclosure of Invention

The invention aims to provide a die assembly for producing heat-conducting silica gel and a die assembly method thereof, and aims to solve the problems that the existing die assembly in the background art is used for carrying out air cooling on the basis of a die mechanism, the die mechanism adopts a manual feeding and discharging mode, a product needs to be taken down and replaced for die assembly after the product is completely formed, the product forming time is prolonged by adopting the mode, the feeding and discharging time consumption is increased, the production efficiency of the heat-conducting silica gel is reduced, and the use requirement cannot be met.

In order to achieve the purpose, the invention provides the following technical scheme: a die assembly for producing heat-conducting silica gel comprises an assembly body and a carrying plate,

the device comprises a device body, an open slot, a touch panel and a power line, wherein the device body is provided with the open slot, the open slot is arranged on the device body and is arranged at two sides of the device body, the material conveying belt is arranged inside the device body and is movably connected with the device body, the touch panel is arranged at one side of the device body and is fixedly connected with the device body, and the power line is arranged at one side of the device body and is connected with the device body into an integral structure;

the device comprises a device main body, a pressure plate, a first hydraulic cylinder, a lifting seat, a lifting cavity, a supporting seat and a lifting seat, wherein the pressure plate is arranged inside the device main body and above a material conveying belt;

and the air injection plate is arranged on one side of the pressing plate and is connected with the device main body through screws, an air cooler assembly is arranged above the device main body and is connected with the device main body through screws, and the air cooler assembly is communicated with the air injection plate.

Preferably, be provided with the constant head tank on the defeated material area, the constant head tank is provided with six at least, and the constant head tank equidistance setting on defeated material area, the four corners of carrying the thing board all is provided with the locating piece, and the locating piece with carry thing board fixed connection, the locating piece corresponds the setting with the constant head tank, the both sides of carrying the thing board all are provided with the handle frame, and handle frame and carry thing board fixed connection.

Preferably, the both sides of device main part all are provided with the mounting bracket, and the mounting bracket passes through screw connection with the device main part, be provided with defeated material roller on the mounting bracket, and defeated material roller rotates with the mounting bracket to be connected, defeated material area is connected with defeated material roller transmission, one side of mounting bracket is provided with the motor, and the motor passes through screw connection with the mounting bracket, the output of motor is connected structure as an organic whole with the one end of defeated material roller.

Preferably, the upper end of carrying the thing board is provided with the slipmat, and the slipmat is connected with carrying the thing board laminating, the lower extreme of carrying the thing board is provided with the recess, and the recess corresponds the setting with the supporting seat, the inside in lift chamber is provided with the spring part, and the both ends of spring part respectively with lift seat and supporting seat elastic connection, the below of lift seat is provided with the second pneumatic cylinder, and the both ends of second pneumatic cylinder respectively with device main part and lift seat fixed connection.

Preferably, one side of the device main body is provided with a transparent door, the transparent door is rotatably connected with the device main body, the two sides of the pressing plate are respectively provided with a first guide rod, the first guide rods are connected with the device main body through screws, and the first guide rods are slidably connected with the pressing plate.

Preferably, the both sides of second pneumatic cylinder all are provided with the second guide bar, and second guide bar and device main part fixed connection, second guide bar and lift seat sliding connection, be provided with the spout on the lateral wall of supporting seat, the both sides of supporting seat all are provided with the slider, and the slider setting is in the inside in lift chamber, slider and lift seat fixed connection, the one end of slider extends to the inside of spout, and slider and supporting seat sliding connection.

Preferably, a vibration damping plate is arranged below the device main body and connected with the device main body through screws, four moving wheel assemblies are arranged below the vibration damping plate and connected with the vibration damping plate through screws, and the four moving wheel assemblies are arranged at four corners of the vibration damping plate.

A die pressing method of a die pressing device for producing heat-conducting silica gel comprises the following steps:

the method comprises the following steps: placing the product on a carrying plate, and then installing the carrying plate with the product on a conveying belt;

step two: starting a motor to drive a material conveying roller to rotate, realizing the movement of a material conveying belt along with the rotation of the material conveying roller, and moving the carrying plate to the position right below the pressing plate by means of the moving material conveying belt;

step three: driving a second hydraulic cylinder to drive the lifting seat to lift, and inserting the supporting seat into the groove to be in contact with the object carrying plate;

step four: driving a first hydraulic cylinder to drive a pressing plate to descend, enabling the pressing plate to be in contact with a product to be extruded, and realizing pressing die by means of extrusion force between the pressing plate and the product;

step five: after the die pressing is finished, the second hydraulic cylinder is driven to separate the supporting seat from the carrying plate, the first step and the second step are repeated, and at the moment, the product which is finished by the die pressing is moved to the position right below the air injection disc;

step six: starting an air cooler assembly to spray cold air onto the product from an air injection disc to cool, and quickly forming the product after die pressing;

step seven: the first hydraulic cylinder is driven to drive the pressing plate to descend during shaping so as to press the product, and the pressing and shaping are performed simultaneously, so that the pressing efficiency is improved.

Compared with the prior art, the invention has the beneficial effects that:

1. according to the device, the pressing plate is driven to lift under the action of the first hydraulic cylinder through the arrangement of the pressing plate, the first hydraulic cylinder, the air cooler assembly and the air injection disc, the pressing plate is pressed by the aid of extrusion force generated by contact of the lowered pressing plate and a product, cold air is rapidly injected to the product after the pressing plate through the air injection disc under the action of the air cooler assembly to cool, the product is quickly shaped, pressing and cooling processes can be simultaneously carried out, and the production efficiency of the heat-conducting silica gel is improved;

2. according to the device, the positioning block is aligned to the positioning groove and inserted through the arrangement of the motor, the material conveying roller, the material conveying belt, the positioning groove and the positioning block, the material carrying plate and the material conveying belt can be quickly and accurately assembled, the material conveying roller is driven to rotate under the action of the motor, the material conveying belt is driven to move along with the rotation of the material conveying roller, so that the conveying of products is realized, the feeding and discharging processing of the products is realized, and the product die pressing efficiency is improved;

3. according to the device, through the arrangement of the non-slip pad, the lifting seat, the supporting seat, the second hydraulic cylinder and the spring part, the non-slip pad increases the product friction force, the product is effectively prevented from shaking during die pressing, the quality of the die pressing can be improved, the lifting seat and the supporting seat form a supporting mechanism, the supporting mechanism can be supported during die pressing, the supporting mechanism is driven to lift under the action of the second hydraulic cylinder, the supporting seat is contacted with the object carrying plate, the spring part enables the supporting seat and the lifting seat to be movably adjusted, the spring part plays a role in buffering when the product is stressed too much, the product is protected, and the quality of the product die pressing is improved;

4. according to the device, the die assembly is convenient to move and carry by virtue of the moving wheel assembly through the arrangement of the vibration reduction plate and the moving wheel assembly, and the vibration reduction performance of the bottom of the die assembly is improved by the vibration reduction plate, so that the stability of the die assembly is ensured in the using process.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a cross-sectional view of the present invention;

FIG. 3 is a view showing a connection relationship between a feed roller and a feed belt according to the present invention;

FIG. 4 is a front view of the carrier plate of the present invention;

FIG. 5 is an enlarged view of a portion of the area A of FIG. 1 in accordance with the present invention;

fig. 6 is a partially enlarged view of the area B of fig. 2 according to the present invention.

In the figure: 1. a device main body; 2. a transparent door; 3. a mounting frame; 4. a touch panel; 5. a vibration damping plate; 6. a moving wheel assembly; 7. a power line; 8. an open slot; 9. a delivery roller; 10. a material conveying belt; 11. a first hydraulic cylinder; 12. an air cooler assembly; 13. an air jet disc; 14. pressing a plate; 15. a first guide bar; 16. a loading plate; 17. a lifting seat; 18. a second hydraulic cylinder; 19. positioning a groove; 20. positioning blocks; 21. a handle frame; 22. a non-slip mat; 23. a motor; 24. a groove; 25. a slider; 26. a second guide bar; 27. a supporting seat; 28. a lifting cavity; 29. a spring member; 30. a chute.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments.

Referring to fig. 1-6, an embodiment of the present invention is shown: a die assembly for producing heat-conducting silica gel comprises an assembly body 1 and a carrying plate 16,

the device comprises a device body 1, an open slot 8, a material conveying belt 10, a touch panel 4, a power line 7 and a power line switch, wherein the open slot 8 is formed in the device body 1, the open slot 8 is formed in two sides of the device body 1, the material conveying belt 10 is arranged inside the device body 1, the material conveying belt 10 is movably connected with the device body 1, the touch panel 4 is arranged on one side of the device body 1, the touch panel 4 is fixedly connected with the device body 1, and the power line 7 is connected with the device body 1 into an integral structure;

the device comprises a pressing plate 14, a first hydraulic cylinder 11, a device body 1 and the pressing plate 14, wherein the pressing plate 14 is arranged above a material conveying belt 10, the first hydraulic cylinder 11 is arranged between the pressing plate 14 and the device body 1, the first hydraulic cylinder 11 is fixedly connected with the device body 1 and the pressing plate 14, the pressing plate 14 is driven by the first hydraulic cylinder 11 to lift, the pressing plate 14 which descends is contacted with a product to generate extrusion force, pressing is realized by virtue of the extrusion force, a lifting seat 17 is arranged below the pressing plate 14, the lifting seat 17 is arranged below the material conveying belt 10, a lifting cavity 28 is arranged at the upper end of the lifting seat 17, a supporting seat 27 is arranged above the lifting seat 17, one end of the supporting seat 27 extends into the lifting cavity 28, the supporting seat 27 is movably connected with the lifting seat 17, and the supporting seat 27 and the lifting seat 17 form a supporting mechanism to support the material carrying plate 16;

jet-propelled dish 13, it sets up in one side of clamp plate 14, and jet-propelled dish 13 passes through bolted connection with device main part 1, and the top of device main part 1 is provided with air-cooler subassembly 12, and air-cooler subassembly 12 passes through bolted connection with device main part 1, and air-cooler subassembly 12 and jet-propelled dish 13 intercommunication set up, and the effect of air-cooler subassembly 12 is cooled down on spraying the product with cold air through jet-propelled dish 13 for the moulding-die product shaping.

Please refer to fig. 3 and 4, a positioning groove 19 is disposed on the material conveying belt 10, the positioning groove 19 is at least six, the positioning groove 19 is equidistantly disposed on the material conveying belt 10, positioning blocks 20 are disposed at four corners of the object carrying plate 16, the positioning blocks 20 are fixedly connected to the object carrying plate 16, the positioning blocks 20 are correspondingly disposed to the positioning grooves 19, handle frames 21 are disposed on two sides of the object carrying plate 16, the handle frames 21 are fixedly connected to the object carrying plate 16, the positioning blocks 20 are inserted into the positioning grooves 19 in an aligning manner, the object carrying plate 16 can be rapidly and accurately assembled to the material conveying belt 10, and loading and unloading are facilitated.

Please refer to fig. 1 and 5, both sides of the device main body 1 are provided with mounting brackets 3, and the mounting brackets 3 are connected with the device main body 1 through screws, the mounting brackets 3 are provided with material conveying rollers 9, and the material conveying rollers 9 are rotatably connected with the mounting brackets 3, the material conveying belt 10 is in transmission connection with the material conveying rollers 9, one side of the mounting brackets 3 is provided with a motor 23, and the motor 23 is in screw connection with the mounting brackets 3, the output end of the motor 23 is connected with one end of the material conveying rollers 9 into an integral structure, the motor 23 drives the material conveying rollers 9 to rotate, the material conveying belt 10 is driven to move along with the rotation of the material conveying rollers 9, then, the conveying of the object carrying plate 16 is realized, and the assembly line of the pressing mold can be carried out.

Referring to fig. 3, 4 and 6, the upper end of the loading plate 16 is provided with the anti-slip pad 22, the anti-slip pad 22 is attached to the loading plate 16, the lower end of the loading plate 16 is provided with the groove 24, the groove 24 is disposed corresponding to the supporting seat 27, the lifting cavity 28 is internally provided with the spring part 29, two ends of the spring part 29 are respectively elastically connected to the lifting seat 17 and the supporting seat 27, the second hydraulic cylinder 18 is disposed below the lifting seat 17, two ends of the second hydraulic cylinder 18 are respectively fixedly connected to the device body 1 and the lifting seat 17, the supporting mechanism is driven to lift by the second hydraulic cylinder 18, the supporting seat 27 can be precisely connected to the loading plate 16 due to the groove 24, the supporting seat 27 and the lifting seat 17 can be movably adjusted by the spring part 29, when the product is stressed too much, the cushioning adjustment can be performed by the spring part 29, the product of the pressing mold can be protected, and the product quality can be improved.

Referring to fig. 1 and 2, a transparent door 2 is disposed on one side of a device body 1, the transparent door 2 is rotatably connected with the device body 1, first guide rods 15 are disposed on two sides of a pressing plate 14, the first guide rods 15 are connected with the device body 1 through screws, the first guide rods 15 are slidably connected with the pressing plate 14, the working condition inside the device can be observed from the outside through the transparent door 2, the first guide rods 15 can guide and limit the lifting pressing plate 14, so that the lifting and lowering of the pressing plate 14 are ensured to be stable, and product die pressing is facilitated.

Referring to fig. 2 and 6, the second hydraulic cylinder 18 is provided at both sides with second guide rods 26, the second guide rods 26 are fixedly connected to the device body 1, the second guide rods 26 are slidably connected to the lifting seat 17, the side walls of the supporting seat 27 are provided with sliding grooves 30, the two sides of the supporting seat 27 are provided with sliding blocks 25, the sliding blocks 25 are disposed inside the lifting cavity 28, the sliding blocks 25 are fixedly connected to the lifting seat 17, one end of the sliding blocks 25 extends into the sliding grooves 30, and the sliding blocks 25 are slidably connected to the supporting seat 27, the lifting seat 17 can be guided and limited by the second guide rods 26, so as to ensure that the lifting seat 17 is lifted stably, and the sliding blocks 25 and the sliding grooves 30 can be guided and limited to the adjusted supporting seat 27, thereby ensuring the adjustment stability of the supporting seat 27.

Referring to fig. 1 and 2, a vibration damping plate 5 is disposed below a device body 1, the vibration damping plate 5 is connected to the device body 1 through screws, moving wheel assemblies 6 are disposed below the vibration damping plate 5, four moving wheel assemblies 6 are disposed, the moving wheel assemblies 6 are connected to the vibration damping plate 5 through screws, the four moving wheel assemblies 6 are disposed at four corners of the vibration damping plate 5, the die assembly is moved and transported conveniently through the moving wheel assemblies 6, the vibration damping plate 5 increases the vibration damping performance of the die assembly, and the stability of the die assembly in the use process is improved.

the method comprises the following steps: placing the products on the carrier plate 16, and then mounting the carrier plate 16 with the products on the conveyor belt 10;

step two: starting a motor 23 to drive a material conveying roller 9 to rotate, realizing the movement of a material conveying belt 10 along with the rotation of the material conveying roller 9, and moving a loading plate 16 to be right below a pressing plate 14 by virtue of the moving material conveying belt 10;

step three: the second hydraulic cylinder 18 is driven to drive the lifting seat 17 to lift, and the supporting seat 27 is inserted into the groove 24 to be contacted with the carrying plate 16;

step four: driving a first hydraulic cylinder 11 to drive a pressing plate 14 to descend, enabling the pressing plate 14 to be in contact with a product to be extruded, and realizing pressing die by means of extrusion force between the pressing plate 14 and the product;

step five: after the compression molding is finished, the second hydraulic cylinder 18 is driven to separate the supporting seat 27 from the carrying plate 16, and the first step and the second step are repeated, wherein the product which is subjected to the compression molding is moved to the position right below the air injection disc 13;

step six: starting the air cooler assembly 12 to spray cold air onto the product from the air injection disc 13 for cooling, and quickly forming the product after die pressing;

step seven: the first hydraulic cylinder 11 is driven to drive the pressing plate 14 to descend during shaping so as to press the product, and the pressing and shaping are performed simultaneously, so that the pressing efficiency is improved.

Those not described in detail in this specification are within the skill of the art.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a die assembly is used in production of heat conduction silica gel, includes device main part (1) and carries thing board (16), its characterized in that:

the device comprises an open slot (8) which is arranged on the device main body (1), wherein the open slot (8) is arranged on two sides of the device main body (1), a material conveying belt (10) is arranged inside the device main body (1), the material conveying belt (10) is movably connected with the device main body (1), a touch panel (4) is arranged on one side of the device main body (1), the touch panel (4) is fixedly connected with the device main body (1), a power line (7) is arranged on one side of the device main body (1), and the power line (7) is connected with the device main body (1) into an integral structure;

the device comprises a device main body (1), a pressing plate (14), a first hydraulic cylinder (11), a first lifting seat (17), a lifting cavity (28), a supporting seat (27), a lifting seat (27) and a lifting base (17), wherein the pressing plate (14) is arranged inside the device main body (1), the pressing plate (14) is arranged above a material conveying belt (10), the first hydraulic cylinder (11) is fixedly connected with the device main body (1) and the pressing plate (14), the lifting seat (17) is arranged below the material conveying belt (10), the upper end of the lifting seat (17) is provided with the lifting cavity (28), one end of the supporting seat (27) extends into the lifting cavity (28), and the supporting seat (27) is movably connected with the lifting seat (17);

air-jet disk (13), it sets up one side of clamp plate (14), and air-jet disk (13) and device main part (1) pass through the screw connection, the top of device main part (1) is provided with air-cooler subassembly (12), and air-cooler subassembly (12) and device main part (1) pass through the screw connection, air-cooler subassembly (12) and air-jet disk (13) intercommunication setting.

2. The die assembly for producing heat-conducting silica gel according to claim 1, wherein: be provided with constant head tank (19) on conveying belt (10), constant head tank (19) are provided with six at least, and constant head tank (19) equidistance setting on conveying belt (10), the four corners of carrying thing board (16) all is provided with locating piece (20), and locating piece (20) and year thing board (16) fixed connection, locating piece (20) correspond the setting with constant head tank (19), the both sides of carrying thing board (16) all are provided with handle frame (21), and handle frame (21) and carry thing board (16) fixed connection.

3. The die assembly for producing heat-conducting silica gel according to claim 2, wherein: the device is characterized in that mounting frames (3) are arranged on two sides of a device main body (1), the mounting frames (3) are connected with the device main body (1) through screws, material conveying rollers (9) are arranged on the mounting frames (3), the material conveying rollers (9) are rotatably connected with the mounting frames (3), material conveying belts (10) are in transmission connection with the material conveying rollers (9), a motor (23) is arranged on one side of the mounting frames (3), the motor (23) is connected with the mounting frames (3) through screws, and the output end of the motor (23) is connected with one end of each material conveying roller (9) into a whole.

4. The die assembly for producing heat-conducting silica gel according to claim 3, wherein: the upper end of carrying thing board (16) is provided with slipmat (22), and slipmat (22) with carry thing board (16) laminating and be connected, the lower extreme of carrying thing board (16) is provided with recess (24), and recess (24) and supporting seat (27) correspond the setting, the inside in lift chamber (28) is provided with spring part (29), and the both ends of spring part (29) respectively with lift seat (17) and supporting seat (27) elastic connection, the below of lift seat (17) is provided with second hydraulic cylinder (18), and the both ends of second hydraulic cylinder (18) respectively with device main part (1) and lift seat (17) fixed connection.

5. The die assembly for producing heat-conducting silica gel according to claim 1, wherein: one side of device main part (1) is provided with transparent door (2), and transparent door (2) and device main part (1) rotate to be connected, the both sides of clamp plate (14) all are provided with first guide bar (15), and just first guide bar (15) pass through screw connection with device main part (1), first guide bar (15) and clamp plate (14) sliding connection.

6. The die assembly for producing heat-conducting silica gel according to claim 4, wherein: the both sides of second pneumatic cylinder (18) all are provided with second guide bar (26), and second guide bar (26) and device main part (1) fixed connection, second guide bar (26) and lift seat (17) sliding connection, be provided with spout (30) on the lateral wall of supporting seat (27), the both sides of supporting seat (27) all are provided with slider (25), and slider (25) set up the inside in lift chamber (28), slider (25) and lift seat (17) fixed connection, the one end of slider (25) extends to the inside of spout (30), and slider (25) and supporting seat (27) sliding connection.

7. The die assembly for producing heat-conducting silica gel according to claim 1, wherein: the vibration damping device is characterized in that a vibration damping plate (5) is arranged below the device main body (1), the vibration damping plate (5) is connected with the device main body (1) through screws, a movable wheel assembly (6) is arranged below the vibration damping plate (5), four movable wheel assemblies (6) are arranged, the movable wheel assemblies (6) are connected with the vibration damping plate (5) through screws, and the four movable wheel assemblies (6) are arranged at four corners of the vibration damping plate (5).

8. The die pressing method of the die pressing device for producing the heat conductive silica gel according to claim 4, characterized in that: the method comprises the following steps:

the method comprises the following steps: placing the products on the carrying plate (16), and then installing the carrying plate (16) with the products on the material conveying belt (10);

step two: starting a motor (23) to drive a material conveying roller (9) to rotate, realizing the movement of a material conveying belt (10) along with the rotation of the material conveying roller (9), and moving a loading plate (16) to the position right below a pressing plate (14) by means of the moving material conveying belt (10);

step three: the second hydraulic cylinder (18) is driven to drive the lifting seat (17) to lift, and the supporting seat (27) is inserted into the groove (24) to be contacted with the object carrying plate (16);

step four: the first hydraulic cylinder (11) is driven to drive the pressing plate (14) to descend, the pressing plate (14) is in contact with a product to be extruded, and pressing die is realized by means of the extrusion force between the pressing plate (14) and the product;

step five: after the die pressing is finished, the second hydraulic cylinder (18) is driven to separate the supporting seat (27) from the carrying plate (16), the first step and the second step are repeated, and the product which is finished by the die pressing at the moment moves to the position right below the air injection disc (13);

step six: starting an air cooler assembly (12) to spray cold air onto a product from an air injection disc (13) for cooling, and quickly forming the product after die pressing;

step seven: the first hydraulic cylinder (11) is driven to drive the pressing plate (14) to descend during shaping so as to press the product, and the pressing and shaping are performed simultaneously, so that the pressing efficiency is improved.