CN219686361U - Demoulding device suitable for silica gel mould - Google Patents

Abstract

The utility model provides a demolding device suitable for a silica gel mold, which comprises a main body frame, a feeding part, a demolding part, a storage part, a transfer box part and a control part. The main body frame comprises a base and a working seat; the demoulding part comprises an H-shaped demoulding frame, a comb plate, a demoulding column and an inclined plate; the storage part comprises a mould storage area and a product storage area; the transfer box part comprises a rectangular container III and a movable backing plate. The mechanical feeding of the die to be disassembled can be realized, and the labor intensity is obviously reduced; the part of the mold to be disassembled, which is not transferred to the working seat, is stored in the working seat, and the disassembled mold and product are also stored in the working seat before transferring, so that a large amount of upper space can be saved; in the demolding process, personnel do not need to move, the process distance is shortened, part of demolding tools are fixed on the workbench, the tools cannot be lost, the working process is optimized, the working time is saved, and the working efficiency is greatly improved.

Description

Demoulding device suitable for silica gel mould

Technical Field

The utility model relates to the field of molds, in particular to a demolding device suitable for a silica gel mold.

Background

The silica gel mold is a special mold for manufacturing artware, has high temperature resistance, corrosion resistance, strong tearing resistance and high simulation fineness, and is widely applied to the production of artificial stone at present. The artificial stone is also called imitation stone, which is formed by adding high molecular materials such as accelerator, thickener and the like into environment-friendly aggregate and a series of processes such as stirring, injection molding, hardening, demolding and the like, and has the characteristics of fire resistance, water resistance, acid and alkali resistance, pollution resistance, innocuity, tasteless, strong adhesive force, fastness and the like, and also has the advantages of simple construction, time saving and the like.

In the demoulding process flow of imitation stone production, a small mould demoulding method adopts manual demoulding, and has the following defects:

firstly, the imitation stone has a certain weight, and the hardened mould needs to be frequently grabbed onto a workbench, so that the labor intensity is high.

Secondly, the demolding process comprises the steps of grabbing the mold, demolding, transferring the mold and the product, so that a large amount of space is occupied, and a large amount of manpower resources are occupied for supplying and transferring.

Thirdly, the traditional demolding tool is separated from the workbench, so that the tool is easy to lose, and the work efficiency is also affected due to the fact that the tool is required to be found everywhere.

Disclosure of Invention

The utility model provides a demoulding device suitable for a silica gel mould, which solves the problems of high labor intensity, large occupied space, low working efficiency and the like.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

a demolding device suitable for a silica gel mold comprises a main body frame, a feeding part, a demolding part, a storage part, a transfer box part and a control part.

The main body frame comprises a base and a working seat. The base comprises a cuboid hollow container I, and a rectangular through hole I, a rectangular through hole II and a rectangular through hole VI are formed in an upper bottom plate of the base; the working seat is arranged on the base and comprises an inverted rectangular container I, a feeding through hole and a die pad discharging hole are formed in the right side plate of the working seat, a die discharging hole and a discharging through hole are formed in the left side plate of the working seat, and a feeding through hole, a die pad through hole, a product through hole, a die through hole and a strip-shaped through hole I are formed in the upper bottom plate of the working seat.

The feeding part comprises a lower layer feeding area and an upper layer feeding area.

The lower layer feeding area comprises a guide rail I, a feeding car and an electric lifting device I. The first guide rail is arranged on the base, and the left end of the first guide rail is positioned in the working seat; the feeding car is connected to the first guide rail through a grooved pulley in a sliding manner, and a rectangular through hole III is formed in the bottom plate of the feeding car.

The upper layer feeding area comprises a first screw motor, a first pushing rod, a second screw motor and a second pushing rod. The first screw rod motor is arranged on the upper bottom plate of the working seat, and the rotor of the first screw rod motor is provided with a connecting rod; the first pushing rod is arranged on a rotor of the screw motor through a reset spring and a connecting rod, and comprises an H-shaped rod, and a limiting groove is formed in a side plate of the H-shaped rod; the screw rod motor I is positioned below the L-shaped protection plate; the screw rod motor II is arranged on the inner wall of the upper bottom plate of the rectangular container I through a mounting frame, and an L-shaped connecting rod is arranged on the rotor of the screw rod motor II; the second pushing rod is arranged on the second rotor of the screw motor through a reset spring and a connecting rod and is positioned above the upper bottom plate of the rectangular container I, and comprises an H-shaped rod I, and a limiting groove I is formed in a side plate of the H-shaped rod I.

The demoulding part comprises an H-shaped demoulding frame, a comb plate, a demoulding column and an inclined panel. The H-shaped stripper frame is arranged on the upper bottom plate of the working seat and positioned at the front side of the feeding through hole; the inclined panel is arranged in a groove at the front side of the H-shaped demoulding frame; the comb plate is arranged on a side plate of the H-shaped demoulding frame; the demoulding column is arranged on the inclined panel and is perpendicular to an upper bottom plate of the rectangular container.

The storage section includes a mold storage area and a product storage area.

The mold storage area includes a mold pad storage mechanism and a mold storage mechanism. The die pad storage mechanism comprises a storage bin, a screw rod motor III, an electric lifting device II, a push rod motor I and a movable carrier plate. The screw rod motor III is arranged on the base and is positioned below the rectangular container; the storage bin is detachably connected to the first carrier vehicle; the lower bottom surface of the first carrier vehicle is detachably connected to a rotor of the screw motor III; the storage bin comprises a rectangular container II, wherein a U-shaped opening through groove I is formed in one side plate of the rectangular container II, and partition plates are arranged in the rectangular container II at equal intervals; the second electric lifting device is arranged in the base; the first push rod motor is arranged at the movable end of the second electric lifting device, the movable ends of the first push rod motor are respectively provided with a movable carrier plate, and the movable carrier plates are matched with the first U-shaped opening through groove; the front movable carrier plate is provided with a circular through hole I. The mould storage mechanism comprises a carrier vehicle II which is connected to the base in a sliding way through a guide rail II, and the right end of the guide rail II is positioned below the rectangular container.

The product storage area comprises an electric lifting device III, a guide rail III and a discharging car. The guide rail III is arranged on the base, and the right end of the guide rail III is positioned in the working seat; the discharging car is connected to the guide rail III through a grooved pulley in a sliding way, and a rectangular through hole IV is formed in the bottom plate of the discharging car; the electric lifting device III is arranged in the base, and the movable end of the electric lifting device III is connected in the rectangular through hole II in a sliding manner.

The transfer box part comprises a rectangular container III and a movable backing plate. A rectangular through hole V is formed in the lower bottom plate of the rectangular container III; the movable backing plate is detachably connected in the rectangular groove.

The control part comprises a control mechanism, a feedback mechanism and a PLC controller. The control mechanism comprises a starting switch, a feeding switch, a discharging switch, a die pad replacing switch and a pause switch. The feedback mechanism comprises a first distance sensor module, a second distance sensor module, a third distance sensor module, a fourth distance sensor module and a fifth distance sensor module.

Further, a mold auxiliary portion is added. The auxiliary part of the die comprises a screw motor five, a screw motor six, a movable plate and a push rod motor two. The screw motor five is arranged in the C-shaped pipe, the screw motor six is arranged on a rotor of the screw motor five through a mounting frame, the movable plate is arranged on the screw motor six, and the push rod motor two is arranged on the movable plate.

Preferably, the second pushing rod and the second screw motor are replaced by a conveyor belt device.

Furthermore, a universal ball structure is additionally arranged on the upper bottom plate of the working seat.

Compared with the prior art, the beneficial effects are that:

in the utility model, through the integrated arrangement of the main body frame, the feeding part, the demolding part, the storage part, the transfer box part and the control part, the following functions are realized:

firstly, realize the mechanical material loading of waiting to dismantle the mould, show reduced intensity of labour.

Secondly, the part of the mold to be disassembled, which is not transferred to the working seat, is stored in the working seat, and the disassembled mold and product are also stored in the working seat before transferring, so that a large amount of upper space is saved, and the demolding operation is convenient.

Thirdly, the staff only needs to carry out demoulding operation on the working seat, such as grabbing a mould, demoulding, transferring the mould and products, and the staff does not need to move, so that the process distance is shortened, the time is saved, and the working efficiency is greatly improved.

Fourthly, part of demolding tools are fixed on the workbench, the tools cannot be lost, meanwhile, the functions of the tools in the working area are clear, the working flow is optimized, and the working efficiency is improved.

Drawings

FIG. 1 is a schematic view of a top view partially in section of the present utility model;

FIG. 2 is a schematic view of a front partial cross-sectional structure of the present utility model;

FIG. 3 is a schematic top view of a portion of a silicone mold according to the present utility model;

FIG. 4 is a schematic diagram of a system architecture according to the present utility model;

fig. 5 is a circuit wiring diagram of the present utility model.

In the figure: 101. base, 102, rectangular through hole I, 103, rectangular through hole II, 104, rectangular through hole VI, 105, working seat, 106, bar through hole I, 107, L-shaped guard, 108, C-shaped tube, 109, bar stop plate, 201, guide rail I, 202, skip, 203, electric lifter I, 204, lead screw motor I, 205, stripper rod I, 206, lead screw motor II, 207, stripper rod II, 301, H-shaped stripper frame, 302, comb plate, 303, stripper column, 304, ramp plate, 401, storage bin, 402, lead screw motor III, 403, electric lifter II, 404, push rod motor I, 405, carrier II, 406, electric lifter III, 407, guide rail III, 408, skip, 501, rectangular container III, 502, movable pad, 601.

Description of the embodiments

Embodiment 1 referring to fig. 1 to 5, a demolding device suitable for a silica gel mold comprises a main body frame, a feeding part, a demolding part, a storage part, a transfer box part and a control part.

The main body frame includes a base 101 and a work seat 105.

The base 101 includes a rectangular hollow container one.

The upper bottom plate of the first cuboid hollow container is provided with a first rectangular through hole 102, a second rectangular through hole 103 and a sixth rectangular through hole 104.

The working base 105 is disposed on the base 101.

The work seat 105 comprises an inverted rectangular container one.

A right side plate of the rectangular container is provided with a feeding through hole and a die pad discharging hole.

And a left side plate of the rectangular container is provided with a die discharging hole and a discharging through hole.

The upper bottom plate of the rectangular container I is provided with a feeding through hole, a die pad through hole, a product through hole, a die through hole, a strip-shaped through hole I106, an L-shaped protection plate 107 and a C-shaped pipe 108.

The feed through is located above the rectangular through one 102.

The product through hole is positioned above the second rectangular through hole 103.

A strip-shaped limiting plate 109 is arranged on the first upper bottom plate of the rectangular container, and the strip-shaped limiting plate 109 is positioned on two sides of the feeding through hole.

The feeding part comprises a lower layer feeding area and an upper layer feeding area.

The lower layer feeding area comprises a first guide rail 201, a feeding car 202 and a first electric lifting device 203.

The first guide rail 201 is disposed on the base 101, and the left end of the first guide rail 201 is located in the working seat 105 for transferring the loading vehicle 202.

The feeding car 202 is connected to the first guide rail 201 in a sliding manner through a grooved pulley; a rectangular through hole III is arranged on the bottom plate of the feeding vehicle 202.

The upper layer feeding area comprises a first screw motor 204, a first pushing rod 205, a second screw motor 206 and a second pushing rod 207

The first screw motor 204 is arranged on the upper bottom plate of the working seat 105.

A connecting rod is arranged on a rotor of the screw motor I204.

The first pushing rod 205 is arranged on the first rotor of the screw motor 204 through a return spring and a connecting rod.

The first pushing rod 205 comprises an H-shaped rod, and a limiting groove is formed in a side plate of the H-shaped rod and used for accommodating a reset spring and a connecting rod.

The first screw motor 204 is located below the "L" -shaped shield 107.

The second screw motor 206 is arranged on the inner wall of the upper bottom plate of the rectangular container I through a mounting frame, and an L-shaped connecting rod is arranged on a rotor of the second screw motor 206.

And the second pushing rod 207 is arranged on the rotor of the second screw motor 206 through a return spring and a connecting rod.

The second pushing rod 207 is located above the first upper bottom plate of the rectangular container.

The second pushing rod 207 comprises an H-shaped rod I, a limiting groove I is formed in a side plate of the H-shaped rod I, and the limiting groove I is used for accommodating a reset spring and an L-shaped connecting rod.

The demolding section includes an "H" shaped demolding frame 301, a comb plate 302, demolding posts 303, and a slope plate 304.

The "H" shaped demoulding frame 301 is arranged on the upper bottom plate of the working seat 105 and is positioned at the front side of the feeding through hole.

The inclined plate 304 is disposed in a groove on the front side of the H-shaped mold release frame 301, and is used for facilitating dust removal and mold unloading.

The comb plate 302 is disposed on a side plate of the "H" -shaped mold release frame 301.

The stripper column 303 is disposed on the inclined plate 304 and is perpendicular to an upper bottom plate of the rectangular container.

The demolding columns 303 respectively form a triangle, an L shape and a straight shape and are used for adapting to demolding operations of different types of molds.

The storage section includes a mold storage area and a product storage area.

The mold storage area includes a mold pad storage mechanism and a mold storage mechanism.

The die pad storage mechanism comprises a storage bin 401, a screw motor III 402, an electric lifting device II 403, a push rod motor I404 and a movable carrier plate.

The third screw motor 402 is disposed on the base 101 and is located below the rectangular container.

The storage bin 401 is detachably connected to the first carrier vehicle.

The lower bottom surface of the carrier vehicle I is detachably connected to a rotor of the screw motor III 402.

The storage bin 401 comprises a second rectangular container, a side plate of the second rectangular container is provided with a first U-shaped opening through groove, and partition plates are arranged in the second rectangular container at equal intervals.

The second electric lifting device 403 is disposed in the base 101 and located between the third screw motor 402 and below the sixth rectangular through hole 104.

The first push rod motor 404 is arranged at the movable end of the second electric lifting device 403, the movable ends of the first push rod motor 404 are respectively provided with a movable carrier plate, and the movable carrier plates are matched with the first U-shaped opening through groove; the front movable carrier plate is provided with a circular through hole I for installing a distance sensor module and detecting the type of the die.

The mold storage mechanism includes a carrier cart two 405.

The second carrier vehicle 405 is slidably connected to the base 101 through a second guide rail, and the right end of the second guide rail is located below the rectangular container.

The product storage area includes an electric lift device three 406, a rail three 407, and a skip car 408.

The third guide rail 407 is disposed on the base 101, and the right end of the third guide rail 407 is located in the working seat 105 for transferring the discharging car 408.

The discharging car 408 is connected to the guide rail III 407 in a sliding manner through a grooved pulley; a rectangular through hole IV is arranged on the bottom plate of the discharging car 408.

The third electric lifting device 406 is disposed in the base 101, and the movable end of the third electric lifting device 406 is slidably connected to the second rectangular through hole 103.

The transfer box section includes a third rectangular container 501 and a movable pallet 502.

A rectangular groove is formed in the lower bottom plate of the rectangular container III 501, and a rectangular through hole V is formed in the rectangular groove; the inner diameter of the rectangular through hole V is larger than the outer diameter of the movable end of the electric lifting device III 406.

The outer diameter of the lower bottom plate of the rectangular container III 501 is larger than the inner diameter of the rectangular through hole IV.

The movable backing plate 502 is detachably connected in the rectangular groove.

The control part comprises a control mechanism, a feedback mechanism and a PLC controller.

The control mechanism comprises a starting switch, a feeding switch, a discharging switch, a die pad replacing switch and a pause switch.

The start switch, the feed switch, the discharge switch, the die pad replacement switch and the pause switch are arranged on the upper bottom plate of the working seat 105.

The feedback mechanism comprises a first distance sensor module, a second distance sensor module, a third distance sensor module, a fourth distance sensor module and a fifth distance sensor module.

The first distance sensor module is arranged on the L-shaped protection plate 107 and used for detecting the position of the mold to be disassembled and feeding back the position to the PLC.

And the second distance sensor module is arranged on the second pushing rod 207 and used for detecting the position of the mold to be disassembled and feeding back the position to the PLC.

And the third distance sensor module is arranged on the H-shaped demoulding frame 301 and is used for detecting the position of the mould to be dismantled and feeding back the position to the PLC.

The fourth distance sensor module is arranged in the first circular through hole and used for detecting the type of the die pad.

The distance sensor module five is arranged on the inner wall of a lower bottom plate of the rectangular container and is positioned on one side of the through hole of the die pad and used for detecting the position of the die pad.

The PLC controller is disposed within the base 101.

The first electric lifting device, the first screw motor 204, the second screw motor 206, the third screw motor 402, the second electric lifting device 403, the first push rod motor 404, the third electric lifting device 406, the starting switch, the feeding switch, the discharging switch, the die pad replacing switch, the pause switch, the first distance sensor module, the second distance sensor module, the third distance sensor module, the fourth distance sensor module and the fifth distance sensor module are electrically connected with the PLC controller.

The working principle and the using method are as follows:

first, presetting:

the device of the utility model is powered, the starting switch is pressed, and no-load debugging is carried out.

The empty transfer box sections are placed on the skip car 408 and the second carrier car 405, respectively, and pushed under the rectangular containers.

The transfer box section loaded with the injection molded and hardened mold to be disassembled is placed on a carrier vehicle one and pushed under the rectangular container.

Secondly, feeding:

the feeding switch is pressed, the microprocessor outputs a signal to the first electric lifting device 203, and the first electric lifting device 203 drives the die to be disassembled to move upwards in sequence. After the first distance sensor module collects the mold signal to be disassembled, a signal is output to the PLC, and the PLC outputs the signal to the first screw motor 204.

The screw motor I204 is started, and the mold to be disassembled is transferred to the area where the screw motor II 206 is located through the pushing rod I205.

After the second distance sensor module collects the mold signal to be disassembled, outputting a signal to a PLC (programmable logic controller), and outputting a signal to the second screw motor 206 by the PLC; the screw motor II 206 is started, and the die to be disassembled is transferred to the H-shaped die-releasing frame 301 through the pushing rod II 207, so that the die is convenient for a worker to take.

When the taking of the mold to be disassembled at the H-shaped demolding frame 301 is finished, the distance sensor module III outputs the acquired signal to the PLC controller, and the PLC controller outputs the signal to the screw motor II 206; the screw motor II 206 is started, and the mold to be disassembled is transferred to the H-shaped mold releasing frame 301 area through the pushing rod II 207.

And (5) reciprocating the operation until the taking is finished. Then, the electric lifting device moves up by one unit distance, and the process is repeated.

Third, disassembling and storing:

the worker removes the imitation stone (finished product, component or member) from the silicone mold 601, and in the process, the comb plate 302 and the demolding column 303 are utilized to demold (eject) the grooves and the through holes of the silicone mold 601.

The die pad (see the hexagonal silica gel die in fig. 3) is placed in the corresponding die pad through hole, and after the distance sensor module five acquires signals, signals are output to the PLC, and the PLC outputs signals to the screw motor three 402, the electric lifting device two 403 and the push rod motor one 404.

The second electric lifting device 403 drives the movable carrier plate to sequentially move downwards, the first push rod motor 404 drives the movable carrier plate to retract after reaching the lowest end, the third screw rod motor 402 drives the storage bin 401 to move outwards by a unit distance, and then the second electric lifting device 403 and the first push rod motor 404 reset, and the process is repeated.

And when the die pad replacement switch is pressed, the PLC controller outputs a signal to the screw motor III 402, and the screw motor III 402 transfers the storage bin 401 out of the rectangular container I.

The demolded imitation stone is placed on the movable base plate 502 of the corresponding transfer box part, after being fully filled, the unloading switch is pressed down, the PLC controller outputs a signal to the third electric lifting device 406, and the third electric lifting device 406 moves downwards by a unit distance, so that subsequent stacking is facilitated.

Example 2 on the basis of example 1, a mould auxiliary part was added for evenly distributing the moulds in the transfer box part.

The auxiliary part of the die comprises a screw motor five, a screw motor six, a movable plate and a push rod motor two.

The screw motor five is disposed within the "C" tube 108.

The screw motor six is arranged on a rotor of the screw motor five through a mounting frame.

The movable plate is arranged on the screw motor six.

The second push rod motor is arranged on the movable plate.

Example 3 based on example 1, the second pushing rod 207 and the second screw motor 206 were replaced with a conveyor belt device to make the power better.

In embodiment 4, on the basis of embodiment 1, a universal ball structure is added on the upper bottom plate of the working seat 105, so that the friction force at the bottom of the die is further reduced, and the operation efficiency is improved.

Claims (10)

1. The utility model provides a shedder suitable for silica gel mould which characterized in that: the device comprises a main body frame, a feeding part, a demolding part, a storage part, a transfer box part and a control part; the main body frame comprises a base and a working seat; the feeding part comprises a lower layer feeding area and an upper layer feeding area; the lower layer feeding area comprises a guide rail I, a feeding car and an electric lifting device I; the upper layer feeding area comprises a first screw motor, a first pushing rod, a second screw motor and a second pushing rod; the screw rod motor I is arranged on the upper bottom plate of the working seat and below the L-shaped protection plate, and a connecting rod is arranged on the rotor of the screw rod motor I; the first pushing rod is arranged on a first rotor of the screw motor through a return spring and a connecting rod; the screw rod motor II is arranged on the inner wall of the upper bottom plate of the rectangular container I through a mounting frame, and an L-shaped connecting rod is arranged on the rotor of the screw rod motor II; the pushing rod is arranged above the upper bottom plate of the rectangular container I and is arranged on the second rotor of the screw motor through a reset spring and a connecting rod; the demoulding part comprises an H-shaped demoulding frame, a comb plate, a demoulding column and an inclined plate; the storage part comprises a mould storage area and a product storage area; the mold storage area includes a mold pad storage mechanism and a mold storage mechanism.

2. The demolding device suitable for a silica gel mold according to claim 1, wherein: the H-shaped stripper frame is arranged on the upper bottom plate of the working seat and positioned at the front side of the feeding through hole; the inclined panel is arranged in a groove at the front side of the H-shaped demoulding frame; the comb plate is arranged on a side plate of the H-shaped demoulding frame; the demoulding column is arranged on the inclined panel and is perpendicular to an upper bottom plate of the rectangular container.

3. The demolding device suitable for a silica gel mold according to claim 1, wherein: the die pad storage mechanism comprises a storage bin, a screw rod motor III, an electric lifting device II, a push rod motor I and a movable carrier plate; the screw rod motor III is positioned below the rectangular container; the storage bin is connected to the first carrier vehicle; the lower bottom surface of the first carrier vehicle is connected to a rotor of the screw motor III; the storage bin comprises a rectangular container II, a side plate of the rectangular container II is provided with a U-shaped opening through groove I, and a partition plate is arranged in the rectangular container II; the first push rod motor is arranged at the movable end of the second electric lifting device, the movable end of the first push rod motor is provided with a movable carrier plate, and the movable carrier plate is matched with the first U-shaped opening through groove; the front movable carrier plate is provided with a circular through hole I.

4. The demolding device suitable for a silica gel mold according to claim 1, wherein: the die storage mechanism comprises a carrier vehicle II which is connected to the base in a sliding manner through a guide rail II, and the right end of the guide rail II is positioned below the rectangular container.

5. The demolding device suitable for a silica gel mold according to claim 1, wherein: the product storage area comprises an electric lifting device III, a guide rail III and a discharging car; the guide rail III is arranged on the base, and the right end of the guide rail III is positioned in the working seat; the discharging car is connected to the guide rail III through a grooved pulley in a sliding way, and a rectangular through hole IV is formed in the bottom plate of the discharging car; the electric lifting device III is arranged in the base, and the movable end of the electric lifting device III is connected in the rectangular through hole II in a sliding manner.

6. The demolding device suitable for a silica gel mold according to claim 1, wherein: the transfer box part comprises a rectangular container III and a movable backing plate; a rectangular groove is formed in the lower bottom plate of the rectangular container III, and a rectangular through hole V is formed in the rectangular groove; the inner diameter of the rectangular through hole V is larger than the outer diameter of the three movable ends of the electric lifting device; the outer diameter of the lower bottom plate of the rectangular container III is larger than the inner diameter of the rectangular through hole IV; the movable backing plate is connected in the rectangular groove.

7. The demolding device suitable for a silica gel mold according to claim 1, wherein: the lower layer feeding area comprises a guide rail I, a feeding car and an electric lifting device I; the first guide rail is arranged on the base, and the left end of the first guide rail is positioned in the working seat; the feeding car is connected to the first guide rail through a grooved pulley in a sliding manner, and a rectangular through hole III is formed in the bottom plate of the feeding car.

8. The demolding device suitable for a silica gel mold according to claim 1, wherein: the first pushing rod comprises an H-shaped rod, and a limit groove is formed in a side plate of the first pushing rod; the second pushing rod comprises an H-shaped rod I, and a limiting groove I is arranged on a side plate of the H-shaped rod I.

9. The demolding device suitable for a silica gel mold according to claim 1, wherein: the mold auxiliary part is additionally arranged and comprises a screw motor five, a screw motor six, a movable plate and a push rod motor two; the screw rod motor is arranged on the working seat; the screw motor six is arranged on a rotor of the screw motor five through a mounting frame; the movable plate is arranged on the screw rod motor six; the second push rod motor is arranged on the movable plate.

10. The demolding device suitable for a silica gel mold according to claim 1, wherein: the universal ball structure is additionally arranged on the upper bottom plate of the working seat.