CN112936700A

CN112936700A - Amorphous metal encapsulation forming device and forming process

Info

Publication number: CN112936700A
Application number: CN202110284858.5A
Authority: CN
Inventors: 张仪
Original assignee: Kunshan Xuzhan Rubber & Plastic Co ltd
Current assignee: Kunshan Xuzhan Rubber & Plastic Co ltd
Priority date: 2021-03-17
Filing date: 2021-03-17
Publication date: 2021-06-11

Abstract

The invention relates to the technical field of silica gel forming, in particular to an amorphous metal rubber coating forming device and a forming process, wherein firstly, an operator drives 9 amorphous metals into a first lower die and puts on a silica gel raw material; then, the feeding mechanism drives the first lower die to move to the position below the upper die, and the hydraulic cylinder drives the upper die and the first lower die to carry out die assembly vulcanization molding operation; then, after the machine station is opened, an operator drives the next 9 amorphous metals into a second lower die, and then puts on the silica gel raw material; when the third step is carried out, an operator takes out the finished product in the first lower die; the feeding mechanism drives the second lower die to move to the position below the upper die, and the hydraulic cylinder drives the upper die and the second lower die to perform die assembly vulcanization molding operation. The invention realizes the synchronous operation of workpiece placement and product vulcanization molding, greatly shortens the production cycle of products, and improves the working efficiency and the productivity benefit.

Description

Amorphous metal encapsulation forming device and forming process

Technical Field

The invention relates to the technical field of silica gel forming, in particular to an amorphous metal rubber coating forming device and a forming process.

Background

The existing amorphous metal rubber-coated component generally comprises 9 amorphous metals, 27 metal rubber-coated components are manufactured in a die in normal production, and due to the fact that the time for placing workpieces is long, the processes are multiple, working efficiency is low, the temperature of the die is reduced, the vulcanizing time in the die is increased additionally, the production period is prolonged, and production cost is increased.

Disclosure of Invention

The invention aims to provide an amorphous metal encapsulation forming device aiming at the defects of the prior art, so that the work piece placing operation and the product vulcanization forming operation are synchronously performed, the production period of the product is greatly shortened, and the working efficiency and the productivity benefit are improved.

In order to achieve the purpose, the amorphous metal rubber coating forming device comprises a machine table and a support frame vertically arranged at the top of the machine table, wherein the support frame is provided with a driving piece, the output end of the driving piece penetrates through the support frame to be connected with a movable plate, the movable plate is provided with an upper die heating piece and an upper die connected with the upper die heating piece, a feeding mechanism used for conveying materials is arranged below the support frame, the output end of the feeding mechanism is connected with a first lower die heating piece and a second lower die heating piece in a driving mode, and the first lower die heating piece and the second lower die heating piece are respectively connected with a first lower die and a second lower die.

Preferably, feeding mechanism includes the casing, the spout has been seted up at the top of casing, be provided with first mount pad and second mount pad in the casing, first mount pad and second mount pad are provided with first synchronizing wheel and second synchronizing wheel respectively, the side of first mount pad is provided with servo motor, servo motor is connected with first synchronizing wheel drive, the transmission is connected with the drive belt between first synchronizing wheel and the second synchronizing wheel, the drive belt interval is provided with first removal seat and second and removes the seat, first lower mould generates heat the piece and generates heat the piece with the second lower mould and set up respectively in the inside that first removal seat and second removed the seat, the bottom that first removal seat and second removed the seat all is provided with the slider with spout sliding connection.

Preferably, a first lifting cylinder and a second lifting cylinder are respectively arranged in the first movable seat and the second movable seat, and power output ends of the first lifting cylinder and the second lifting cylinder are respectively in driving connection with the first lower die heating piece and the second lower die heating piece.

Preferably, first die cavity and second die cavity have been seted up respectively to the inside of first bed die and second bed die, the edge of first die cavity and second die cavity all is provided with the material stopper, the outside of going up the mould is provided with the pressure plywood, the shape of pressure plywood and the shape phase-match of first die cavity, second die cavity, be provided with the material inductor in the pressure plywood, be provided with respectively in first die cavity and the second die cavity and respond to the piece with the first response piece and the second of material inductor matching work.

Preferably, the corners of the upper die are provided with positioning columns, and the corners of the first lower die and the second lower die are respectively provided with a first positioning hole and a second positioning hole which are connected with the positioning columns.

Preferably, the first lower die heating element and the second lower die heating element are internally provided with electric heating tubes at intervals, the outer parts of the electric heating tubes are provided with nano electric heating films, and the inner walls of the first lower die heating element and the second lower die heating element are stacked to form a heat conduction layer and a uniform heating layer.

Preferably, the movable plate is provided with a position adjusting assembly, the position adjusting assembly comprises a first positioning groove and a second positioning groove which are parallel and arranged at intervals, the first positioning groove is identical to the second positioning groove in structure, a plurality of clamping grooves are formed in the inner wall of the first positioning groove at intervals, a positioning block is arranged in the first positioning groove and connected with an upper die heating element, grooves are formed in two sides of the positioning block, a reset spring is arranged in each groove, and one end of each reset spring is connected with a clamping head connected with each clamping groove.

Preferably, the driving member is a hydraulic cylinder or an air cylinder.

Preferably, the bottom fixedly connected with truckle of board, the side of truckle is provided with the telescopic link, the tip of telescopic link is provided with the callus on the sole.

An amorphous metal encapsulation forming process comprises the following steps: the method comprises the following steps: firstly, an operator drives 9 amorphous metals into a first lower die and puts a silica gel raw material; step two: then, the feeding mechanism drives the first lower die to move to the position below the upper die, and the hydraulic cylinder drives the upper die and the first lower die to carry out die assembly vulcanization molding operation; step three: then, after the machine station is opened, an operator drives the next 9 amorphous metals into a second lower die, and then puts on the silica gel raw material; step four: when the third step is carried out, an operator takes out the finished product in the first lower die; step five: the feeding mechanism drives the second lower die to move to the position below the upper die, and the hydraulic cylinder drives the upper die and the second lower die to perform die assembly vulcanization molding operation.

The invention has the beneficial effects that: firstly, an operator drives 9 amorphous metals into a first lower die and puts a silica gel raw material; then, the feeding mechanism drives the first lower die to move to the position below the upper die, and the hydraulic cylinder drives the upper die and the first lower die to carry out die assembly vulcanization molding operation; then, after the machine station is opened, an operator drives the next 9 amorphous metals into a second lower die, and then puts on the silica gel raw material; when the third step is carried out, an operator takes out the finished product in the first lower die; the feeding mechanism drives the second lower die to move to the position below the upper die, and the hydraulic cylinder drives the upper die and the second lower die to perform die assembly vulcanization molding operation. The invention realizes the synchronous operation of workpiece placement and product vulcanization molding, greatly shortens the production cycle of products, and improves the working efficiency and the productivity benefit.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of the position adjustment assembly of the present invention.

FIG. 3 is a schematic structural diagram of a positioning block of the present invention.

Fig. 4 is an exploded structural schematic view of the feeding mechanism of the present invention.

FIG. 5 is a schematic view of the internal structure of the first lower mold heating element and the second lower mold heating element of the present invention.

The reference numerals include:

1-machine table 10-truckle 11-expansion link

12-foot pad

2-support frame 20-driving piece 21-moving plate

22-upper mould heating element 23-upper mould 24-laminated plate

25-Material sensor 26-positioning post

27-position adjusting assembly 270-first positioning groove 271-second positioning groove

272 clamping groove 273, positioning block 274 and groove

275-return spring 276-chuck

3-feeding mechanism 30-first lower die heating element 31-second lower die heating element

32-first lower die 320-first cavity 321-first induction block

33-second lower mold 330-second cavity 331-second induction block

34-shell 35-chute 36-first mounting seat

37-second mounting base 38-first synchronizing wheel 39-second synchronizing wheel

310-servo motor 311-transmission belt 312-first movable base

313-second movable base 314-sliding block 315-first lifting cylinder

316-second lifting cylinder 317-material limiting block 318-first positioning hole

319-second positioning hole

322-electrothermal tube 323-nano electrothermal film 324-heat conducting layer

325 — soaking layer.

Detailed Description

The present invention is described in detail below with reference to the attached drawings.

As shown in fig. 1 to 5, the amorphous metal encapsulation molding device of the present invention includes a machine table 1 and a support frame 2 vertically disposed on the top of the machine table 1, wherein the support frame 2 is provided with a driving member 20, an output end of the driving member 20 penetrates through the support frame 2 and is connected with a moving plate 21, the moving plate 21 is provided with an upper mold heating member 22 and an upper mold 23 connected with the upper mold heating member 22, a feeding mechanism 3 for conveying a material is disposed below the support frame 2, an output end of the feeding mechanism 3 is connected with a first lower mold heating member 30 and a second lower mold heating member 31 in a driving manner, and the first lower mold heating member 30 and the second lower mold heating member 31 are respectively connected with a first lower mold 32 and a second lower mold 33.

When the device works, 9 amorphous metals are driven into the first lower die 32 by a worker, then the silica gel raw material is placed, the output end of the driving piece 20 penetrates through the support frame 2 to drive the moving plate 21 to move up and down, the moving plate 21 drives the upper die heating piece 22 and the upper die 23 connected with the upper die heating piece 22 to move up and down, and the feeding mechanism 3 drives the first lower die 32 to move to the position right below the upper die 23 to enable the upper die 23 and the first lower die 32 to be matched and vulcanized for forming; meanwhile, the worker drives 9 amorphous metals of the next batch into the second lower die 33, then puts on the silica gel raw material, after the die is opened, the feeding mechanism 3 not only drives the first lower die 32 to move out of the die, but also drives the second lower die 33 to move to the position right below the upper die 23, and then drives the upper die 23 and the second lower die 33 to be closed and vulcanized to form through the driving piece 20; finally, the staff takes out the finished product in the first lower mould 32 and then continues to hit a new round of 9 amorphous metals into the first lower mould 32, the silica gel raw material is put on, the upper mould 23 and the first lower mould 32 are made to be matched with each other for vulcanization forming through the driving piece 20, the above operation steps are repeatedly circulated, i take out the original single-slide machine 1 to be changed into the double-slide machine 1, and a heating system is added on the double-slide plate, so that the forming mould temperature of the mould can not be reduced due to overlong time outside the mould, the vulcanization temperature of the product is stable, the vulcanization operation can be controlled to be completed in a shorter time, the productivity is improved, and the work piece placing operation and the product vulcanization forming operation are carried out synchronously. The invention realizes the synchronous operation of workpiece placement and product vulcanization molding, greatly shortens the production cycle of products, and improves the working efficiency and the productivity benefit.

As shown in fig. 1 and 4, the feeding mechanism 3 of the present embodiment includes a housing 34, a sliding slot 35 is opened at the top of the housing 34, a first mounting seat 36 and a second mounting seat 37 are arranged in the housing 34, the first mounting seat 36 and the second mounting seat 37 are respectively provided with a first synchronizing wheel 38 and a second synchronizing wheel 39, a servo motor 310 is arranged beside the first mounting seat 36, the servo motor 310 is in driving connection with the first synchronous wheel 38, a transmission belt 311 is connected between the first synchronizing wheel 38 and the second synchronizing wheel 39 in a transmission way, the driving belt 311 is provided with a first movable base 312 and a second movable base 313 at intervals, the first lower mold heating element 30 and the second lower mold heating element 31 are respectively disposed inside the first movable base 312 and the second movable base 313, the first movable seat 312 and the second movable seat 313 are provided at their bottoms with sliders 314 slidably connected to the slide slots 35. Specifically, the servo motor 310 drives the first synchronizing wheel 38 to rotate, the first synchronizing wheel 38 drives the second synchronizing wheel 39 to rotate synchronously through the transmission belt 311, the first moving seat 312 and the second moving seat 313 are driven to move back and forth through the transmission belt 311, the bottoms of the first moving seat 312 and the second moving seat 313 are connected with the sliding groove 35 in a sliding mode through the sliding block 314, the moving is stable and rapid, the transmission efficiency is high, and the work is stable and reliable.

As shown in fig. 1 and 4, a first lifting cylinder 315 and a second lifting cylinder 316 are respectively disposed in the first moving base 312 and the second moving base 313 of the present embodiment, and power output ends of the first lifting cylinder 315 and the second lifting cylinder 316 are respectively in driving connection with the first lower mold heating element 30 and the second lower mold heating element 31. Specifically, a first lifting cylinder 315 and a second lifting cylinder 316 are respectively arranged in the first moving seat 312 and the second moving seat 313, and power output ends of the first lifting cylinder 315 and the second lifting cylinder 316 respectively drive the first lower mold heating element 30 and the second lower mold heating element 31 to move up and down, so that the first lower mold 32 and the second lower mold 33 are further driven by the first lower mold heating element 30 and the second lower mold heating element 31 to move up and down to be tightly attached to the upper mold 23, and the mold closing vulcanization molding quality and the working efficiency of the first lower mold 32, the second lower mold 33 and the upper mold 23 are effectively improved.

As shown in fig. 1 and 4, a first cavity 320 and a second cavity 330 are respectively disposed inside the first lower mold 32 and the second lower mold 33 of this embodiment, the corners of the first cavity 320 and the second cavity 330 are respectively provided with a material stopper 317, the outside of the upper mold 23 is provided with a press plate 24, the shape of the press plate 24 is matched with the shapes of the first cavity 320 and the second cavity 330, a material sensor 25 is disposed in the press plate 24, and a first induction block 321 and a second induction block 331 which are matched with the material sensor 25 are respectively disposed in the first cavity 320 and the second cavity 330. Specifically, the staff squeezes into first die cavity 320 or second die cavity 330 with 9 amorphous metals in, restrict fixedly through material stopper 317 to 9 amorphous metal's position, location effect is good, the pressure plywood 24 detects the position of sensing first response piece 321 or second response piece 331 through material inductor 25, and then send work order in order to control upper die 23 through the first die cavity 320 of the inseparable pressfitting of pressure plywood 24 or second die cavity 330, impel the compound die vulcanization shaping between 9 amorphous metals and the silica gel raw materials, work precision is high, the shaping is of high quality.

As shown in fig. 1 and 4, the upper mold 23 of the present embodiment is provided with positioning posts 26 at the corners, and the first lower mold 32 and the second lower mold 33 are respectively provided with a first positioning hole 318 and a second positioning hole 319 connected to the positioning posts 26 at the corners. Specifically, the upper mold 23 is connected with the first positioning hole 318 through the positioning column 26 in a matching manner, and the upper mold 23 is connected with the second positioning hole 319 through the positioning column 26 in a matching manner, so that accurate mold closing and forming operations between the upper mold 23 and the first lower mold 32 and between the upper mold 23 and the second lower mold 33 are realized, the position of the mold is prevented from being deviated in the working process, and the positioning effect is good.

As shown in fig. 1, 4 and 5, the electric heating tubes 322 are disposed in the first lower mold heating element 30 and the second lower mold heating element 31 at intervals, the nano electric heating film 323 is disposed outside the electric heating tubes 322, and the heat conducting layer 324 and the heat equalizing layer 325 are stacked on the inner walls of the first lower mold heating element 30 and the second lower mold heating element 31. Specifically, a plurality of electric heating tubes 322 arranged at intervals are arranged in the first lower die heating piece 30 and the second lower die heating piece 31, the electric heating tubes 322 are heated in a columnar large area, the heating efficiency is high, a nano electric heating film 323 is arranged outside each electric heating tube 322, the heating mode of the nano electric heating film 323 is adopted, the temperature rise is fast, the heating is more uniform, the electric heating conversion efficiency is high, the work is stable and reliable, and the comprehensive and efficient heating work of the first lower die heating piece 30 and the second lower die heating piece 31 is realized by stacking the heat conduction layer 324 and the soaking layer 325 which are arranged on the inner walls of the first lower die heating piece 30 and the second lower die heating piece 31.

As shown in fig. 1, 2 and 3, the moving plate 21 of the present embodiment is provided with a position adjusting assembly 27, the position adjusting assembly 27 includes a first positioning groove 270 and a second positioning groove 271 that are parallel and arranged at an interval, the first positioning groove 270 and the second positioning groove 271 have the same structure, a plurality of clamping grooves 272 are arranged at intervals on an inner wall of the first positioning groove 270, a positioning block 273 is arranged in the first positioning groove 270, the positioning block 273 is connected with the upper mold heating element 22, grooves 274 are respectively arranged on both sides of the positioning block 273, a return spring 275 is arranged in each groove 274, and one end of the return spring 275 is connected with a clamping head 276 connected with the clamping groove 272. Specifically, the first positioning grooves 270 and the second positioning grooves 271 which are arranged in parallel and at intervals are respectively arranged at two sides of the moving plate 21, the first positioning grooves 270 and the second positioning grooves 271 have the same structure and the same working principle, the positioning block 273 is connected with the upper mold heating element 22, compared with the situation that the feeding mechanism 3 drives the first lower mold heating element 30 and the second lower mold heating element 31 to move transversely, the upper mold heating element 22 is driven to move longitudinally along the first positioning grooves 270 through the positioning block 273, the positioning block 273 interacts with the clamping groove 272 through the clamping head 276, the position fixing of the upper mold heating element 22 is completed under the elastic action of the return spring 275, so that the working position of the upper mold heating element 22 can be adjusted and changed according to different actual working conditions, the upper mold 23 connected with the upper mold heating element 22 is enabled to be accurately aligned with the working positions of the first lower mold 32 and the second lower mold 33, the combination degree is high, greatly improving the effect of die assembly and vulcanization molding.

As shown in fig. 1, the driving member 20 of the present embodiment is a hydraulic cylinder or an air cylinder. Specifically, the driving member 20 is preferably a hydraulic cylinder, which has a simple structure, a strong driving force, and a smooth and reliable reciprocating motion.

As shown in fig. 1, a caster 10 is fixedly connected to the bottom of the machine table 1 of the present embodiment, a telescopic rod 11 is disposed beside the caster 10, and a foot pad 12 is disposed at an end of the telescopic rod 11. Specifically, the machine table 1 moves through the caster wheels 10, so that labor-saving carrying is facilitated, daily maintenance and overhaul are facilitated, and the operation is simple and convenient. Can change the height of callus on the sole 12 through telescopic link 11, make the fixed butt of callus on the sole 12 in ground, increase contact friction power plays the support positioning action to board 1.

An amorphous metal encapsulation forming process comprises the following steps: the method comprises the following steps: firstly, an operator drives 9 amorphous metals into a first lower die 32, and then puts on a silica gel raw material; step two: then, the feeding mechanism 3 drives the first lower die 32 to move to a position below the upper die 23, and the hydraulic cylinder drives the upper die 23 and the first lower die 32 to perform a die closing vulcanization molding operation; step three: then, after the machine table 1 is opened, an operator drives the next 9 amorphous metals into the second lower die 33, and then puts the silica gel raw material on the second lower die; step four: while the third step is performed, the operator takes out the finished product in the first lower mold 32; step five: the feeding mechanism 3 drives the second lower die 33 to move to a position below the upper die 23, and the hydraulic cylinder drives the upper die 23 and the second lower die 33 to carry out die assembly vulcanization molding operation.

Specifically, during work, 9 amorphous metals are driven into the first lower die 32 by a worker, then the silica gel raw material is placed, the output end of the driving piece 20 penetrates through the support frame 2 to drive the moving plate 21 to move up and down, the moving plate 21 drives the upper die heating piece 22 and the upper die 23 connected with the upper die heating piece 22 to move up and down, and the feeding mechanism 3 drives the first lower die 32 to move to the position right below the upper die 23 to enable the upper die 23 and the first lower die 32 to be matched and vulcanized for forming; meanwhile, the worker drives 9 amorphous metals of the next batch into the second lower die 33, then puts on the silica gel raw material, after the die is opened, the feeding mechanism 3 not only drives the first lower die 32 to move out of the die, but also drives the second lower die 33 to move to the position right below the upper die 23, and then drives the upper die 23 and the second lower die 33 to be closed and vulcanized to form through the driving piece 20; finally, the staff takes out the finished product in the first lower mould 32 and then continues to hit a new round of 9 amorphous metals into the first lower mould 32, the silica gel raw material is put on, the upper mould 23 and the first lower mould 32 are made to be matched with each other for vulcanization forming through the driving piece 20, the above operation steps are repeatedly circulated, i take out the original single-slide machine 1 to be changed into the double-slide machine 1, and a heating system is added on the double-slide plate, so that the forming mould temperature of the mould can not be reduced due to overlong time outside the mould, the vulcanization temperature of the product is stable, the vulcanization operation can be controlled to be completed in a shorter time, the productivity is improved, and the work piece placing operation and the product vulcanization forming operation are carried out synchronously. The invention realizes the synchronous operation of workpiece placement and product vulcanization molding, greatly shortens the production cycle of products, and improves the working efficiency and the productivity benefit.

The above description is only a preferred embodiment of the present invention, and for those skilled in the art, the present invention should not be limited by the description of the present invention, which should be interpreted as a limitation.

Claims

1. The utility model provides an amorphous metal rubber coating forming device, includes the board, sets up perpendicularly in the support frame at board top, its characterized in that: the support frame is provided with the driving piece, the output of driving piece passes the support frame and is connected with the movable plate, the movable plate is provided with the last mould that the piece and the last mould that is connected that generates heat of last mould generate heat, the below of support frame is provided with the feeding mechanism who is used for carrying the material, feeding mechanism's output drive is connected with first lower mould and generates heat the piece with the second lower mould, first lower mould generates heat the piece and generates heat the piece with the second lower mould and is connected with first lower mould and second lower mould respectively.

2. The amorphous metal over-molding device according to claim 1, wherein: the feeding mechanism comprises a shell, a sliding groove is formed in the top of the shell, a first mounting seat and a second mounting seat are arranged in the shell, a first synchronizing wheel and a second synchronizing wheel are respectively arranged on the first mounting seat and the second mounting seat, a servo motor is arranged beside the first mounting seat and is in driving connection with the first synchronizing wheel, a transmission belt is connected between the first synchronizing wheel and the second synchronizing wheel in a transmission mode, a first moving seat and a second moving seat are arranged at intervals of the transmission belt, a first lower die heating piece and a second lower die heating piece are respectively arranged inside the first moving seat and the second moving seat, and sliding blocks which are in sliding connection with the sliding groove are arranged at the bottoms of the first moving seat and the second moving seat.

3. The amorphous metal over-molding device according to claim 2, wherein: and the power output ends of the first lifting cylinder and the second lifting cylinder are respectively in driving connection with the first lower die heating piece and the second lower die heating piece.

4. The amorphous metal over-molding device according to claim 1, wherein: first die cavity and second die cavity have been seted up respectively to the inside of first bed die and second bed die, the edge of first die cavity and second die cavity all is provided with the material stopper, the outside of going up the mould is provided with the pressure plywood, the shape of pressure plywood and the shape phase-match of first die cavity, second die cavity, be provided with the material inductor in the pressure plywood, first die cavity and second die cavity are provided with respectively and respond to the piece with first response piece and the second of material inductor matching work.

5. The amorphous metal over-molding device according to claim 4, wherein: and the corners of the upper die are provided with positioning columns, and the corners of the first lower die and the second lower die are respectively provided with a first positioning hole and a second positioning hole which are connected with the positioning columns.

6. The amorphous metal over-molding device according to claim 1, wherein: the first lower die heating piece and the second lower die heating piece are internally provided with electric heating tubes at intervals, the outer parts of the electric heating tubes are provided with nano electric heating films, and the inner walls of the first lower die heating piece and the second lower die heating piece are stacked to form a heat conduction layer and a heat equalizing layer.

7. The amorphous metal over-molding device according to claim 1, wherein: the movable plate is provided with position control assembly, position control assembly includes first constant head tank and the second constant head tank that parallel and interval set up, first constant head tank is the same with second constant head tank structure, the inner wall interval of first constant head tank is provided with a plurality of draw-in groove, be provided with the locating piece in the first constant head tank, the locating piece is connected with last mould heating element, the both sides of locating piece are all seted up flutedly, be provided with reset spring in the recess, reset spring's one end is connected with the dop of being connected with the draw-in groove.

8. The amorphous metal over-molding device according to claim 1, wherein: the driving piece is a hydraulic cylinder or an air cylinder.

9. The amorphous metal over-molding device according to claim 1, wherein: the bottom fixedly connected with truckle of board, the side of truckle is provided with the telescopic link, the tip of telescopic link is provided with the callus on the sole.

10. An over-molding process for manufacturing amorphous metal by using the molding device of any one of claims 1 to 9, wherein: the method comprises the following steps:

the method comprises the following steps: firstly, an operator drives 9 amorphous metals into a first lower die and puts a silica gel raw material;

step two: then, the feeding mechanism drives the first lower die to move to the position below the upper die, and the hydraulic cylinder drives the upper die and the first lower die to carry out die assembly vulcanization molding operation;

step three: then, after the machine station is opened, an operator drives the next 9 amorphous metals into a second lower die, and then puts on the silica gel raw material;

step four: when the third step is carried out, an operator takes out the finished product in the first lower die;

step five: the feeding mechanism drives the second lower die to move to the position below the upper die, and the hydraulic cylinder drives the upper die and the second lower die to perform die assembly vulcanization molding operation.