CN114454400B - Wrinkle-proof and shift-proof high-heat-conductivity insulating plate forming equipment and forming method thereof - Google Patents

Abstract

The invention relates to the field of PCB (printed circuit board) base materials, in particular to a fold-preventing and shift-preventing high-heat-conductivity insulating plate forming device and a forming method thereof. The technical problems are as follows: the silicon collagen liquid falls down to impact the polyimide film, so that the polyimide film is easy to fold, the upper part of the glass fiber mesh cloth is not blocked, and the glass fiber mesh cloth can deviate in the silica gel stock solution. The technical proposal is as follows: a wrinkle-proof and shift-proof high-heat-conductivity insulating plate forming device comprises a second fixing plate, a transfer system and the like; and the upper sides of the two second fixing plates are connected with a transfer system for adjusting the position of the insulating plate. The invention realizes that polyimide film laid on the bottom layer can not be impacted by the added silicon collagen liquid to generate wrinkles when the silicon collagen liquid of the bottom layer is added, and can not generate deflection and floating phenomena when the glass fiber mesh cloth is placed on the upper surface of the silicon collagen liquid of the bottom layer.

Description

Wrinkle-proof and shift-proof high-heat-conductivity insulating plate forming equipment and forming method thereof

Technical Field

The invention relates to the field of PCB (printed circuit board) base materials, in particular to a fold-preventing and shift-preventing high-heat-conductivity insulating plate forming device and a forming method thereof.

Background

In the process of manufacturing the PCB substrate, a plurality of layers of different materials are pressed by using a press, and in the process of pressing by using the press, a single pressing operation is often required to simultaneously press a plurality of circuit board substrates, and in order that the plurality of circuit board substrates are not affected by each other in the process of pressing, it is required to laminate them and insert a special insulating board between them.

The existing insulating board is manufactured by paving a polyimide film at the bottom of a die cavity, pouring a bottom silicon collagen liquid, then adding glass fiber mesh cloth, and pouring an upper silicon collagen liquid, thereby realizing the molding of the insulating board;

however, since the polyimide film is paved at the bottom of the die cavity, the silica gel stock solution is directly poured into the die cavity, so that the silica gel stock solution falls down to impact the polyimide film, the polyimide film is easy to fold, the surface of the manufactured insulating plate forms folds, the product is scrapped, and after the glass fiber mesh cloth is added, the glass fiber mesh cloth is not blocked above the glass fiber mesh cloth, so that the glass fiber mesh cloth in the manufactured insulating plate is deviated in the silica gel stock solution, the position of the glass fiber mesh cloth in the manufactured insulating plate is unstable, and the production quality of the insulating plate is not guaranteed.

In order to solve the above problems, there is a need for a wrinkle-preventing and shift-preventing molding apparatus for an insulating plate with high thermal conductivity and a molding method thereof.

Disclosure of Invention

In order to overcome the defect that the polyimide film is easy to cause wrinkling of the polyimide film due to falling of the silicon collagen liquid and offset of the glass fiber mesh cloth in the silica gel stock solution due to no blocking above the glass fiber mesh cloth, the invention provides crease-resistant and shift-resistant high-heat-conductivity insulating plate forming equipment and a forming method thereof.

The technical proposal is as follows: a wrinkle-proof and shift-proof high-heat-conductivity insulating plate forming device comprises a first fixed plate, a second fixed plate, a transfer system, a glue solution feeding system and a cloth placing system; two first fixing plates are arranged and are symmetrical front and back; two second fixing plates are arranged and are bilaterally symmetrical; the two second fixing plates are positioned between the two first fixing plates; the upper sides of the two second fixing plates are connected with a transfer system for adjusting the position of the insulating plate; the left parts of the upper sides of the two first fixing plates are connected with a glue solution feeding system for adding glue solution; the right parts of the upper sides of the two first fixing plates are connected with a cloth placing system for bending and placing the grid cloth.

Further, the transfer system comprises a third fixed plate, an electric sliding rail, an electric sliding block, a supporting carrier plate and a forming die box; the upper front part and the upper rear part of the two second fixing plates are fixedly connected with a third fixing plate respectively; the upper sides of the two third fixing plates are fixedly connected with an electric sliding rail respectively; two electric sliding blocks are respectively connected to the two electric sliding rails in a sliding way; the upper sides of the four electric sliding blocks are fixedly connected with a supporting carrier plate; a forming die box is arranged on the upper side of the supporting carrier plate.

Further, a groove is formed in the middle of the inner left wall and the middle of the inner right wall of the forming die box respectively, and the lower surfaces of the two grooves are inclined planes.

Further, the glue feeding system comprises a first supporting side plate, a first bearing plate, a second supporting side plate, a first wedge block, a first electric push rod, a glue blanking frame, a positioning linkage assembly, a connecting slat, a second spring, a limiting plate and a baffle plate; the left parts of the upper sides of the two first fixing plates are fixedly connected with two first supporting side plates respectively; the four first supporting side plates are fixedly connected with a first bearing plate; the middle part of the left side and the middle part of the right side of the first bearing plate are respectively fixedly connected with a second supporting side plate; the lower parts of the opposite sides of the two second support side plates are fixedly connected with a first wedge-shaped block respectively; the left part and the right part of the lower side of the first bearing plate are fixedly connected with a first electric push rod respectively; the two first electric push rod telescopic parts are fixedly connected with a glue solution blanking frame; the left part and the right part of the glue solution blanking frame are respectively connected with a positioning linkage assembly; the two positioning linkage components are bilaterally symmetrical; the two positioning linkage assemblies are respectively contacted with a first wedge-shaped block; two connecting laths are connected between the two positioning linkage assemblies; the two connecting battens are symmetrical front and back; two second springs are respectively connected to the lower sides of the two connecting laths; the lower sides of the front two second springs and the lower sides of the rear two second springs are respectively connected with a limiting plate; the two limiting plates are symmetrical front and back; the upper sides of the two limiting plates are respectively fixedly connected with a baffle plate.

Further, the left positioning linkage assembly comprises a fixed frame, a turnover plate, a first spring, a second wedge block, a first linkage plate, a second linkage plate, a first connecting column and a first connecting plate; the left part of the glue solution blanking frame is fixedly connected with a fixed frame; the left side of the fixed frame is rotationally connected with a turnover plate through a bearing seat; the overturning plate is contacted with the first wedge block at the left side; a first spring is connected between the lower part of the right side of the turnover plate and the fixed frame; the upper part of the right side of the overturning plate is fixedly connected with a second wedge block; the lower part of the fixed frame is rotatably connected with a first linkage plate; the lower part of the fixed frame is rotatably connected with a second linkage plate; the first linkage plate and the second linkage plate are crossed, and the first linkage plate is positioned in front of the second linkage plate; the left lower part of the first linkage plate and the left lower part of the second linkage plate are respectively fixedly connected with a first connecting column; the left sides of the two first connecting columns are fixedly connected with a first connecting plate respectively; the right sides of the two first connecting plates are fixedly connected with one connecting slat respectively.

Further, the cloth placing system comprises a third supporting side plate, a second bearing plate, a second electric push rod, a third bearing plate, a third electric push rod, a connecting frame, a first clamping column, a first L-shaped plate, a collecting seat, a second connecting column, a second connecting plate and a second clamping column; the right parts of the upper sides of the two first fixing plates are fixedly connected with a third supporting side plate respectively; a second bearing plate is fixedly connected to the upper side between the two third support side plates; the four corners of the lower side of the second bearing plate are fixedly connected with a second electric push rod respectively; the four second electric push rod telescopic parts are fixedly connected with a third bearing plate; two third electric push rods are fixedly connected to the left side and the right side of the third bearing plate respectively; the left two third electric push rod telescopic parts and the right two third electric push rod telescopic parts are respectively fixedly connected with a connecting frame; the opposite sides of the two connecting frames are fixedly connected with a first clamping column respectively; the left part and the right part of the upper side of the third bearing plate are fixedly connected with two first L-shaped plates respectively; the opposite sides of the left two first L-shaped plates and the right two first L-shaped plates are fixedly connected with a collecting seat respectively; the lower parts of the two collecting seats are fixedly connected with a second connecting column; the front part and the rear part of the two second connecting columns are respectively connected with a second connecting plate through torsion springs; the left two second connecting plates are positioned at the outer sides of the left collecting seat, and the right two second connecting plates are positioned at the outer sides of the right collecting seat; and a second clamping column is fixedly connected between the two second connecting plates at the left and the two second connecting plates at the right respectively.

Further, the lowest point of the first clamping post is located between the highest point and the middle of the second clamping post.

Further, the device also comprises a residual material cleaning system, the left part and the right part of the third bearing plate are respectively connected with a residual material cleaning system, the left excess material cleaning system comprises a second L-shaped plate, a motor, a disc, a third L-shaped plate, a sliding column, a third spring, a transmission plate, a first connecting plate, a first wedge-shaped slat, a first material shoveling plate, a second connecting plate, a connecting sliding block, a spring rod, a second wedge-shaped slat and a second material shoveling plate; the middle part of the right side in the third bearing plate is fixedly connected with a second L-shaped plate; the upper side of the second L-shaped plate is fixedly connected with a motor; the output shaft of the motor is fixedly connected with a disc; the middle part of the right side of the third bearing plate is fixedly connected with a third L-shaped plate; the upper part of the third L-shaped plate is connected with a sliding column in a sliding way; the left side of the sliding column is fixedly connected with a transmission plate; the transmission plate is contacted with the disc; a third spring is connected between the third L-shaped plate and the transmission plate; the third spring is sleeved on the sliding column; the right side of the sliding column is fixedly connected with a first connecting plate; the lower part of the right side of the first connecting plate is fixedly connected with a first wedge-shaped slat; the upper part of the right side of the first connecting plate is fixedly connected with a first shovel plate; the upper part of the right side of the second L-shaped plate is fixedly connected with a second connecting plate; the right part of the lower side of the second connecting plate is fixedly connected with two connecting sliding blocks; the lower sides of the two connecting sliding blocks are respectively connected with a spring rod; two through sliding grooves are formed in the first shovel plate, and two connecting sliding blocks are respectively arranged in one through sliding groove in a sliding manner; the lower sides of the two spring rods are connected with a second wedge-shaped slat; the right side of the second wedge-shaped slat is fixedly connected with a second shovel plate.

Further, the disc is eccentrically rotated.

Further, the forming method of the crease-resistant and shift-resistant high-heat-conductivity insulating plate comprises the following steps of:

step one: laying a film, namely firstly laying a polyimide film in a transfer system manually;

step two: adding silicon collagen liquid, adding a bottom layer of silicon gel stock solution into a transfer system through a glue solution feeding system, and ensuring that polyimide films paved on the bottom layer cannot be impacted by the added silicon collagen liquid to generate wrinkles;

step three: placing the grid cloth, manually paving the glass fiber grid cloth in a transfer system, and adjusting the position of the glass fiber grid cloth through a cloth placing system;

step four: adding liquid for the second time, and adding the upper layer of silica gel stock solution into the transfer system through a glue solution feeding system;

step five: solidifying the glue solution, and solidifying the silica gel stock solution in the transfer system through external heating equipment to form an insulating plate;

step six: and separating, namely separating and taking away the insulating plate in the transfer system through a peripheral punching device.

The beneficial effects of the invention are as follows:

(1) The invention realizes that polyimide film laid on the bottom layer can not be impacted by the added silicon collagen liquid to generate folds when the silicon collagen liquid of the bottom layer is added, and can not generate deflection and floating phenomena when the glass fiber mesh cloth is placed on the upper surface of the silicon collagen liquid of the bottom layer;

(2) According to the invention, the impact of the residual materials in the grooves of the molding die box is replaced by manual work, so that the residual materials in the grooves are loosened, the situation that the grooves of the molding die box are inconvenient to apply force by manual work is avoided, and the residual materials can be taken out rapidly.

Drawings

Fig. 1 is a schematic perspective view showing a wrinkle-proof and shift-proof high-heat-conductivity insulating plate forming device according to the present invention;

FIG. 2 is a schematic perspective view of a transfer system according to the present invention;

FIG. 3 shows a cross-sectional view of a molding box of the present invention;

FIG. 4 is a schematic perspective view of the glue feeding system of the present invention;

FIG. 5 is a schematic view showing a first partial perspective structure of the glue feeding system of the present invention;

FIG. 6 is a schematic view showing a second partial perspective structure of the glue feeding system of the present invention;

FIG. 7 is a schematic view showing a third partial perspective structure of the glue feeding system of the present invention;

FIG. 8 is a schematic perspective view showing a combination of the cloth loading system and the remainder cleaning system according to the present invention;

FIG. 9 is a schematic view showing a first partial perspective view of the cloth feeding system of the present invention;

FIG. 10 is a schematic view showing a second partial perspective view of the cloth feeding system according to the present invention;

FIG. 11 is a schematic view showing a third partial perspective view of the cloth feeding system according to the present invention;

FIG. 12 is a schematic view showing a first perspective structure of the cull cleaning system of the present invention;

FIG. 13 is a schematic view showing a second perspective structure of the cull cleaning system of the present invention;

fig. 14 is a schematic view showing a third perspective structure of the residue cleaning system according to the present invention.

Reference numerals: 1-first fixed plate, 2-second fixed plate, 101-third fixed plate, 102-electric slide rail, 103-electric slide, 104-support carrier plate, 105-forming die box, 201-first support side plate, 202-first load-bearing plate, 203-second support side plate, 204-first wedge block, 205-first electric push rod, 206-glue blanking frame, 207-fixed frame, 208-turnover plate, 209-first spring, 210-second wedge block, 211-first linkage plate, 212-second linkage plate, 213-first connecting plate, 214-first connecting plate, 215-connecting slat, 216-second spring, 217-limit plate, 218-baffle, 301-third support side plate, 302-second load-bearing plate, 303-second electric push rod, 304-third load-bearing plate, 305-third electric push rod, 306-connecting frame, 307-first clamping post, 308-first L, 309-seat, 310-second connecting post, 311-second connecting plate, 312-second motor, 401-L, 401-second connecting plate, 401-L, 402-second connecting plate, 401-second connecting plate, 404-second wedge plate, 408-second connecting plate, 404-second connecting plate, 411-second wedge plate, 405-second connecting plate, 405-wedge-connecting plate, 405-second connecting plate, 405-connecting plate, and connecting plate, 405-connecting plate, etc.

Detailed Description

The present invention will be described in detail with reference to the accompanying drawings.

Example 1

The equipment for forming the crease-resistant and shift-resistant high-heat-conductivity insulating plate comprises a first fixed plate 1, a second fixed plate 2, a transfer system, a glue solution feeding system and a cloth putting system, wherein the first fixed plate is a plate; two first fixing plates 1 are arranged, and the two first fixing plates 1 are symmetrical front and back; two second fixing plates 2 are arranged, and the two second fixing plates 2 are bilaterally symmetrical; the two second fixing plates 2 are positioned between the two first fixing plates 1; the upper sides of the two second fixing plates 2 are connected with a transfer system; the left parts of the upper sides of the two first fixing plates 1 are connected with a glue solution feeding system; the right parts of the upper sides of the two first fixing plates 1 are connected with a cloth feeding system.

Working principle: when the anti-wrinkling and anti-shifting high-heat-conductivity insulating plate forming equipment is used, polyimide films are paved in a transfer system manually, then a bottom layer of silica gel stock solution is added into the transfer system through a glue solution feeding system, the polyimide films paved on the bottom layer are prevented from being impacted by the added silica gel stock solution to be wrinkled, then glass fiber mesh cloth is paved in the transfer system manually, the position of the glass fiber mesh cloth is adjusted through a cloth placement system, then an upper layer of silica gel stock solution is added into the transfer system through the glue solution feeding system, then the silica gel stock solution in the transfer system is solidified through a peripheral heating device to form an insulating plate, and then the insulating plate in the transfer system is separated and taken away through a peripheral punching device, so that the phenomenon that the polyimide films paved on the bottom layer are prevented from being impacted by the added silica gel stock solution when the silicon collagen solution is added is realized, and the glass fiber mesh cloth is prevented from being offset and floating when the glass fiber mesh cloth is placed on the upper surface of the bottom layer of the silicon collagen solution is ensured.

The transfer system comprises a third fixed plate 101, an electric sliding rail 102, an electric sliding block 103, a supporting carrier plate 104 and a forming die box 105; the upper front part and the upper rear part of the two second fixing plates 2 are fixedly connected with a third fixing plate 101 respectively; each of the upper sides of the two third fixing plates 101 is connected with an electric sliding rail 102 through bolts; two electric sliding blocks 103 are respectively connected to the two electric sliding rails 102 in a sliding manner; the upper sides of the four electric sliding blocks 103 are fixedly connected with a supporting carrier plate 104; a molding box 105 is placed on the upper side of the support carrier plate 104.

The middle part of the inner left wall and the middle part of the inner right wall of the molding die box 105 are respectively provided with a groove, and the lower surfaces of the two grooves are inclined planes.

The glue feeding system comprises a first supporting side plate 201, a first bearing plate 202, a second supporting side plate 203, a first wedge block 204, a first electric push rod 205, a glue blanking frame 206, a positioning linkage assembly, a connecting slat 215, a second spring 216, a limiting plate 217 and a baffle 218; two first supporting side plates 201 are welded on the left parts of the upper sides of the two first fixing plates 1 respectively; a first bearing plate 202 is welded between the four first supporting side plates 201; a second supporting side plate 203 is welded at the middle part of the left side and the middle part of the right side of the first bearing plate 202 respectively; a first wedge block 204 is welded to the lower parts of the opposite sides of the two second support side plates 203; a first electric push rod 205 is connected to the left part of the lower side and the right part of the lower side of the first bearing plate 202 through bolts; the telescopic parts of the two first electric push rods 205 are fixedly connected with a glue solution blanking frame 206; the left part and the right part of the glue solution blanking frame 206 are respectively connected with a positioning linkage assembly; the two positioning linkage components are bilaterally symmetrical; two positioning linkage assemblies each contact one of the first wedge blocks 204; two connecting laths 215 are connected between the two positioning linkage assemblies; the two connecting strips 215 are symmetrical back and forth; two second springs 216 are respectively connected to the lower sides of the two connecting strips 215; the lower sides of the front two second springs 216 and the lower sides of the rear two second springs 216 are respectively connected with a limiting plate 217; the two limiting plates 217 are symmetrical front and back; a baffle 218 is welded on the upper side of each of the two limiting plates 217.

The left positioning linkage assembly comprises a fixed frame 207, a turnover plate 208, a first spring 209, a second wedge block 210, a first linkage plate 211, a second linkage plate 212, a first connecting column 213 and a first connecting plate 214; a fixed frame 207 is fixedly connected to the left part of the glue solution blanking frame 206; the left side of the fixed frame 207 is rotatably connected with a turnover plate 208 through a bearing seat; the flipping plate 208 is in contact with the first wedge block 204 to the left; a first spring 209 is connected between the lower right side of the turnover plate 208 and the fixed frame 207; the second wedge block 210 is welded at the upper right side of the turnover plate 208; the lower part of the fixed frame 207 is rotatably connected with a first linkage plate 211; the lower part of the fixed frame 207 is rotatably connected with a second linkage plate 212; the first linkage plate 211 and the second linkage plate 212 are crossed, and the first linkage plate 211 is positioned in front of the second linkage plate 212; a first connecting column 213 is welded at the left lower part of the first linkage plate 211 and the left lower part of the second linkage plate 212 respectively; a first connecting plate 214 is welded on the left side of each of the two first connecting columns 213; the right side of each of the two first connecting plates 214 is welded to one connecting slat 215.

The cloth loading system comprises a third supporting side plate 301, a second bearing plate 302, a second electric push rod 303, a third bearing plate 304, a third electric push rod 305, a connecting frame 306, a first clamping column 307, a first L-shaped plate 308, a collecting seat 309, a second connecting column 310, a second connecting plate 311 and a second clamping column 312; a third supporting side plate 301 is welded on the right part of the upper side of the two first fixing plates 1 respectively; a second bearing plate 302 is welded on the upper side between the two third supporting side plates 301; four corners of the lower side of the second bearing plate 302 are respectively connected with a second electric push rod 303 through bolts; the telescopic parts of the four second electric push rods 303 are fixedly connected with a third bearing plate 304; two third electric push rods 305 are connected to the left side and the right side of the third bearing plate 304 through bolts respectively; the telescopic parts of the left two third electric push rods 305 and the telescopic parts of the right two third electric push rods 305 are respectively fixedly connected with a connecting frame 306; the opposite sides of the two connecting frames 306 are fixedly connected with a first clamping column 307 respectively; two first L-shaped plates 308 are welded on the left part and the right part of the upper side of the third bearing plate 304 respectively; the left two first L-shaped plates 308 and the right two first L-shaped plates 308 are welded with a collecting seat 309 respectively on the opposite sides; the lower parts of the two collecting seats 309 are fixedly connected with a second connecting column 310; the front and rear parts of the two second connection posts 310 are respectively connected with a second connection plate 311 through torsion springs; the left two second connecting plates 311 are positioned outside the left collecting seat 309, and the right two second connecting plates 311 are positioned outside the right collecting seat 309; a second clamping column 312 is fixedly connected between the two second connecting plates 311 on the left and between the two second connecting plates 311 on the right.

The lowest point of the first clamping post 307 is located between the highest point and the middle of the second clamping post 312.

Working principle: firstly, an operator lays a polyimide film on the inner bottom wall of the molding die box 105, and then controls two first electric push rods 205 to push a glue solution blanking frame 206 downwards, so that the glue solution blanking frame 206 drives a positioning linkage assembly, a connecting slat 215, a second spring 216, a limiting plate 217 and a baffle 218 to move downwards synchronously;

taking the left positioning linkage assembly as an example, the initial position of the overturning plate 208 is located above the first wedge block 204, at this time, the first spring 209 is in a normal state, the overturning plate 208 is inclined, when the operation starts, the glue solution blanking frame 206 is pushed to move downwards by the first electric push rod 205, the positioning linkage assembly moves downwards, the overturning plate 208 moves downwards to the bottom to be in contact with the first wedge block 204, then the overturning plate 208 moves on the inclined surface of the first wedge block 204, and the overturning plate 208 is extruded by the first wedge block 204 to rotate, at this time, the first spring 209 is compressed, when the overturning plate 208 rotates to be in a vertical state, the overturning plate 208 just moves downwards to be in contact with the side wall of the molding die box 105, the side wall of the molding die box 105 continues to extrude the overturning plate 208, so that the overturning plate 208 moves downwards in a vertical state on the side wall of the molding die box 105, when the overturning plate 208 moves to the side wall groove position of the molding die box 105, due to the resilience of the first spring 209, the turnover plate 208 turns to an initial inclined state, at this time, the turnover plate 208 drives the second wedge block 210 to move synchronously, so that the second wedge block 210 moves rightwards, the second wedge block 210 pushes the first linkage plate 211 and the second linkage plate 212, the first linkage plate 211 and the second linkage plate 212 rotate in opposite directions on the fixed frame 207, at this time, the first linkage plate 211 and the second linkage plate 212 drive each first connecting column 213 to move, so that the two first connecting columns 213 are far away from each other and offset, the first connecting column 213 drives the first connecting plate 214, the connecting slat 215, the second spring 216, the limiting plate 217 and the baffle 218 to move synchronously, at this time, the two limiting plates 217 move in an arc track, when the two limiting plates 217 pass through the lowest point of the arc track, touch the polyimide film of the bottom wall in the molding die box 105, when the two limiting plates 217 move far away from each other, the middle part of the polyimide film is relaxed, then the silicon collagen liquid is poured into the glue solution blanking frame 206 through the external feeding equipment, at the moment, the silicon collagen liquid falls into the position between the two limiting plates 217 through the lower outlet of the glue solution blanking frame 206, and the middle part of the polyimide film is stretched and kept flat by the two limiting plates 217, when the silicon collagen liquid falls, the silicon collagen liquid contacts the flat polyimide film, thereby avoiding the situation that the polyimide film is wrinkled, and the silicon collagen liquid can only pass through the lower parts of the two limiting plates 217 due to the action of the two baffles 218, so that the silicon collagen liquid is diffused from the middle part of the polyimide film to the left and right sides, the polyimide film is automatically flattened in the flowing process of the silicon collagen liquid, the phenomenon that the silicon collagen liquid is directly poured into the polyimide film to impact the polyimide film is avoided, the polyimide film is wrinkled is avoided, when the silicon collagen liquid flows through the limiting plate 217, the limiting plate 217 is elastically buffered by the second spring 216, the limiting plate 217 can float up and down, the damage of the limiting plate 217 is avoided, when the whole polyimide film is fully covered with the silicon collagen liquid, the first electric push rod 205 is controlled to pull the glue solution blanking frame 206 upwards, the positioning linkage assembly, the connecting slat 215, the second spring 216, the limiting plate 217 and the baffle 218 are enabled to move upwards, and meanwhile, the silicon collagen liquid continuously flows down until feeding of the bottom silicon collagen liquid is completed; the middle part of the inner left wall and the middle part of the inner right wall of the molding die box 105 are respectively provided with a groove, the lower surfaces of the two grooves are inclined planes, so that glass fiber mesh cloth is placed in the grooves and cannot float in glue solution, and the lower surfaces of the grooves are inclined planes, so that the residual materials in the grooves can be cleaned conveniently, and the residual materials can slide downwards along the inclined planes;

then, the glass fiber mesh cloth is required to be placed in the groove position of the molding die box 105, the worker firstly places the glass fiber mesh cloth on the upper surface of the molding die box 105, at this time, because the transverse length of the glass fiber mesh cloth is matched with the maximum distance between the left groove and the right groove of the molding die box 105, the two ends of the glass fiber mesh cloth are required to be bent to be placed in the molding die box 105, the electric sliding block 103 on the electric sliding rail 102 is controlled to move, so that the electric sliding block 103 drives the supporting carrier plate 104 to move, the supporting carrier plate 104 drives the molding die box 105 to move, the molding die box 105 is moved to the lower position of the cloth placing system, then the second electric push rod 303 is controlled to move downwards, the third carrier plate 304 is driven to move downwards, the third electric push rod 305, the connecting frame 306, the first clamping column 307, the first L-shaped plate 308, the collecting seat 309, the second connecting column 310, the second connecting plate 311 and the second clamping column 312 are synchronously moved downwards, at this time, the third electric push rods 305 are in an extended state, the two first clamping columns 307 are positioned at the outer side positions of the two second clamping columns 312, when the two second clamping columns 312 move downwards to contact with the glass fiber mesh cloth, the glass fiber mesh cloth is pressed into the molding die box 105, the left end and the right end of the glass fiber mesh cloth are turned upwards by utilizing the side wall of the molding die box 105, the turned-up part of the glass fiber mesh cloth is positioned between the first clamping columns 307 and the second clamping columns 312, then the four third electric push rods 305 are controlled to shrink, the two first clamping columns 307 move close to each other, the first clamping columns 307 move to the upper part of the second clamping columns 312, the lowest point of the first clamping columns 307 is positioned between the highest point and the middle part of the second clamping columns 312, the first clamping column 307 presses the tilted part of the glass fiber mesh cloth on the second clamping column 312, the second clamping column 312 is extruded and deflected by the first clamping column 307, the second clamping column 312 drives the second connecting plate 311 to rotate on the second connecting column 310, a torsion spring between the second connecting column 310 and the second connecting plate 311 is twisted, at the moment, the tilted part of the glass fiber mesh cloth is clamped by the first clamping column 307 and the second clamping column 312, then the tilted part of the glass fiber mesh cloth is clamped by the first clamping column 307 and the second clamping column 312 to continuously move downwards, when the glass fiber mesh cloth is clamped and moved to the groove position of the forming die box 105, the four third electric push rods 305 are controlled to further contract, the first clamping column 307 passes over the second clamping column 312, the second clamping column 312 loses the extrusion of the first clamping column 307, then the torsion spring between the second connecting column 310 and the second connecting plate 311 is twisted and reset, the second clamping column 312 is deflected and reset, the tilted part of the glass fiber mesh cloth is clamped by the first clamping column 307 and the second clamping column 312, then the tilted part of the glass fiber mesh cloth is clamped by the second clamping column 307 and the second clamping column 312 is controlled to clamp the second clamping column, then the third electric push rods are controlled to press the glass fiber mesh cloth into the forming die box to be completely pressed into the groove position of the forming die box 105, the glass fiber mesh cloth is heated, the second electric push rods is heated, the glass mesh cloth is stretched and then the glass mesh cloth is stretched into the outer part is stretched, the second electric push rod is cooled, and the glass fiber mesh cloth is further stretched, and the glass mesh cloth is further is deformed, and the glass mesh cloth is deformed.

Example 2

Based on embodiment 1, as shown in fig. 1 and fig. 12-14, the left and right parts of the third bearing plate 304 are respectively connected with a residue cleaning system, and the right residue cleaning system comprises a second L-shaped plate 401, a motor 402, a disc 403, a third L-shaped plate 404, a slide column 405, a third spring 406, a transmission plate 407, a first joint plate 408, a first wedge-shaped plate 409, a first shovel plate 410, a second joint plate 411, a connecting sliding block 412, a spring rod 413, a second wedge-shaped plate 414 and a second shovel plate 415; a second L-shaped plate 401 is welded in the middle of the right side in the third bearing plate 304; a motor 402 is connected to the upper side of the second L-shaped plate 401 through bolts; the output shaft of the motor 402 is fixedly connected with a disc 403; a third L-shaped plate 404 is welded in the middle of the right side of the third bearing plate 304; the upper part of the third L-shaped plate 404 is connected with a sliding column 405 in a sliding way; a transmission plate 407 is welded on the left side of the sliding column 405; the drive plate 407 is in contact with the disk 403; a third spring 406 is connected between the third L-shaped plate 404 and the transmission plate 407; the third spring 406 is sleeved on the sliding column 405; a first connector plate 408 is welded to the right side of the spool 405; a first wedge slat 409 is welded to the lower right side of the first connector plate 408; a first shovel plate 410 is welded to the upper right side of the first joint plate 408; a second joint plate 411 is welded to the upper right side of the second L-shaped plate 401; two connecting sliding blocks 412 are welded on the right part of the lower side of the second connecting plate 411; a spring rod 413 is connected to the lower sides of the two connecting sliding blocks 412 respectively; the first shovel plate 410 is provided with two through sliding grooves, and the two connecting sliding blocks 412 are respectively arranged in one through sliding groove in a sliding way; the lower sides of the two spring rods 413 are connected with second wedge-shaped slats 414; a second shovel plate 415 is welded to the right side of the second wedge plate 414.

The disc 403 is eccentrically rotated.

Working principle: when the insulating plate is separated and removed, as the residual materials are left in the groove of the molding die box 105, the residual materials are required to be taken out at the moment, the second electric push rod 303 is controlled to push the third bearing plate 304 downwards, so that the third bearing plate 304 drives the two residual material cleaning systems to move downwards, and the first shovel material plate 410 and the second shovel material plate 415 are aligned to the upper side and the lower side of the groove of the molding die box 105 respectively;

taking the right-hand excess material cleaning system as an example, the second L-shaped plate 401 is controlled to drive the disc 403 to rotate, because the disc 403 eccentrically rotates, the disc 403 can push the transmission plate 407 when rotating, so that the transmission plate 407 drives the first connecting plate 408 to move through the sliding column 405, the sliding column 405 slides in the third L-shaped plate 404, the third spring 406 is compressed, the first material shoveling plate 410 and the first wedge-shaped plate 409 are driven to synchronously move through the first connecting plate 408, the first wedge-shaped plate 409 impacts the upper side of the groove of the molding box 105 through the first material shoveling plate 410, and meanwhile, the first wedge-shaped plate 409 moves to the right to push the second wedge-shaped plate 414, so that the second wedge-shaped plate 414 moves upwards, the spring rod 413 is compressed, the second material shoveling plate 415 moves synchronously through the second wedge-shaped plate 414, so that the second material shoveling plate 415 moves synchronously to the upper side of the groove of the molding box 105, and the disc 403 continuously rotates, the transmission plate 407 is reset through the rebound of the third spring 406, so that the excess material in the groove of the molding box 105 is replaced by manpower, the rapid movement of the excess material in the groove of the molding box 105 is avoided, and the rapid force loosening of the molding box is avoided.

A wrinkle-proof and shift-proof high-heat-conductivity insulating plate forming method comprises the following steps:

step one: laying a film, namely firstly laying a polyimide film in a transfer system manually;

step two: adding silicon collagen liquid, adding a bottom layer of silicon gel stock solution into a transfer system through a glue solution feeding system, and ensuring that polyimide films paved on the bottom layer cannot be impacted by the added silicon collagen liquid to generate wrinkles;

step three: placing the grid cloth, manually paving the glass fiber grid cloth in a transfer system, and adjusting the position of the glass fiber grid cloth through a cloth placing system;

step four: adding liquid for the second time, and adding the upper layer of silica gel stock solution into the transfer system through a glue solution feeding system;

step five: solidifying the glue solution, and solidifying the silica gel stock solution in the transfer system through external heating equipment to form an insulating plate;

step six: and separating, namely separating and taking away the insulating plate in the transfer system through a peripheral punching device.

Finally, it should be noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the scope of the present invention, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solution of the present invention may be modified or substituted equally without departing from the spirit and scope of the technical solution of the present invention.

Claims (5)

1. A wrinkle-proof and shift-proof high-heat-conductivity insulating plate forming device comprises a first fixing plate (1) and a second fixing plate (2); two first fixing plates (1) are arranged, and the two first fixing plates (1) are symmetrical front and back; two second fixing plates (2) are arranged, and the two second fixing plates (2) are bilaterally symmetrical; the two second fixing plates (2) are positioned between the two first fixing plates (1); the method is characterized in that: the device also comprises a transfer system, a glue solution feeding system and a cloth putting system; the upper sides of the two second fixing plates (2) are connected with a transfer system for adjusting the position of the insulating plate; the left parts of the upper sides of the two first fixing plates (1) are connected with a glue solution feeding system for adding glue solution; the right parts of the upper sides of the two first fixing plates (1) are connected with a cloth placing system for bending and placing grid cloth;

the transfer system comprises a third fixed plate (101), an electric sliding rail (102), an electric sliding block (103), a supporting carrier plate (104) and a forming die box (105); the upper front part and the upper rear part of the two second fixing plates (2) are fixedly connected with a third fixing plate (101) respectively; the upper sides of the two third fixing plates (101) are fixedly connected with an electric sliding rail (102) respectively; two electric sliding blocks (103) are respectively connected to the two electric sliding rails (102) in a sliding way; the upper sides of the four electric sliding blocks (103) are fixedly connected with a supporting carrier plate (104); a molding die box (105) is arranged on the upper side of the supporting carrier plate (104);

the middle part of the inner left wall and the middle part of the inner right wall of the forming die box (105) are respectively provided with a groove, and the lower surfaces of the two grooves are inclined planes;

the glue feeding system comprises a first supporting side plate (201), a first bearing plate (202), a second supporting side plate (203), a first wedge block (204), a first electric push rod (205), a glue discharging frame (206), a positioning linkage assembly, a connecting slat (215), a second spring (216), a limiting plate (217) and a baffle plate (218); two first support side plates (201) are fixedly connected to the left parts of the upper sides of the two first fixing plates (1) respectively; a first bearing plate (202) is fixedly connected between the four first supporting side plates (201); the middle part of the left side and the middle part of the right side of the first bearing plate (202) are fixedly connected with a second supporting side plate (203); the lower parts of the opposite sides of the two second supporting side plates (203) are fixedly connected with a first wedge block (204) respectively; the left part and the right part of the lower side of the first bearing plate (202) are fixedly connected with a first electric push rod (205) respectively; the telescopic parts of the two first electric push rods (205) are fixedly connected with a glue solution blanking frame (206); the left part and the right part of the glue solution blanking frame (206) are respectively connected with a positioning linkage assembly; the two positioning linkage components are bilaterally symmetrical; the two positioning linkage assemblies are respectively contacted with a first wedge block (204); two connecting laths (215) are connected between the two positioning linkage assemblies; the two connecting laths (215) are symmetrical back and forth; two second springs (216) are respectively connected to the lower sides of the two connecting laths (215); the lower sides of the front two second springs (216) and the lower sides of the rear two second springs (216) are respectively connected with a limiting plate (217); the two limiting plates (217) are symmetrical front and back; the upper sides of the two limiting plates (217) are fixedly connected with a baffle plate (218) respectively;

the left positioning linkage assembly comprises a fixed frame (207), a turnover plate (208), a first spring (209), a second wedge block (210), a first linkage plate (211), a second linkage plate (212), a first connecting column (213) and a first connecting plate (214); a fixed frame (207) is fixedly connected to the left part of the glue solution blanking frame (206); the left side of the fixed frame (207) is rotatably connected with a turnover plate (208) through a bearing seat; the overturning plate (208) is contacted with the first wedge block (204) at the left; a first spring (209) is connected between the lower right side of the turnover plate (208) and the fixed frame (207); the upper part of the right side of the overturning plate (208) is fixedly connected with a second wedge block (210); the lower part of the fixed frame (207) is rotatably connected with a first linkage plate (211); the lower part of the fixed frame (207) is rotatably connected with a second linkage plate (212); the first linkage plate (211) and the second linkage plate (212) are crossed, and the first linkage plate (211) is positioned in front of the second linkage plate (212); the left lower part of the first linkage plate (211) and the left lower part of the second linkage plate (212) are fixedly connected with a first connecting column (213) respectively; the left sides of the two first connecting columns (213) are fixedly connected with a first connecting plate (214) respectively; the right sides of the two first connecting plates (214) are fixedly connected with one connecting slat (215) respectively;

the cloth placing system comprises a third supporting side plate (301), a second bearing plate (302), a second electric push rod (303), a third bearing plate (304), a third electric push rod (305), a connecting frame (306), a first clamping column (307), a first L-shaped plate (308), a collecting seat (309), a second connecting column (310), a second connecting plate (311) and a second clamping column (312); the right parts of the upper sides of the two first fixing plates (1) are fixedly connected with a third supporting side plate (301) respectively; a second bearing plate (302) is fixedly connected to the upper side between the two third supporting side plates (301); the four corners of the lower side of the second bearing plate (302) are fixedly connected with a second electric push rod (303) respectively; the telescopic parts of the four second electric push rods (303) are fixedly connected with a third bearing plate (304); two third electric push rods (305) are fixedly connected to the left side and the right side of the third bearing plate (304) respectively; the telescopic parts of the left two third electric push rods (305) and the telescopic parts of the right two third electric push rods (305) are fixedly connected with a connecting frame (306) respectively; the opposite sides of the two connecting frames (306) are fixedly connected with a first clamping column (307) respectively; the left part and the right part of the upper side of the third bearing plate (304) are fixedly connected with two first L-shaped plates (308) respectively; the left two first L-shaped plates (308) and the right two first L-shaped plates (308) are fixedly connected with a collecting seat (309) respectively on the opposite sides; the lower parts of the two collecting seats (309) are fixedly connected with a second connecting column (310); the front part and the rear part of the two second connecting columns (310) are respectively connected with a second connecting plate (311) through torsion springs; the left two second connecting plates (311) are positioned outside the left collecting seat (309), and the right two second connecting plates (311) are positioned outside the right collecting seat (309); a second clamping column (312) is fixedly connected between the two second connecting plates (311) at the left and between the two second connecting plates (311) at the right.

2. The wrinkle-resistant and shift-resistant high-thermal-conductivity insulating plate molding apparatus as claimed in claim 1, wherein: the lowest point of the first clamping post (307) is located between the highest point and the middle of the second clamping post (312).

3. The wrinkle-resistant and shift-resistant high-thermal-conductivity insulating plate molding apparatus as claimed in claim 1, wherein: the left and right parts of the third bearing plate (304) are respectively connected with a left and right part of the left bearing plate, and the left and right part of the left bearing plate are respectively connected with a left and right part of the left bearing plate, the left bearing plate comprises a second L-shaped plate (401), a motor (402), a disc (403), a third L-shaped plate (404), a slide column (405), a third spring (406), a transmission plate (407), a first joint plate (408), a first wedge-shaped slat (409), a first shovel plate (410), a second joint plate (411), a connecting sliding block (412), a spring rod (413), a second wedge-shaped slat (414) and a second shovel plate (415); the middle part of the right side in the third bearing plate (304) is fixedly connected with a second L-shaped plate (401); a motor (402) is fixedly connected to the upper side of the second L-shaped plate (401); the output shaft of the motor (402) is fixedly connected with a disc (403); the middle part of the right side of the third bearing plate (304) is fixedly connected with a third L-shaped plate (404); the upper part of the third L-shaped plate (404) is connected with a sliding column (405) in a sliding way; a transmission plate (407) is fixedly connected to the left side of the sliding column (405); the transmission plate (407) is contacted with the disc (403); a third spring (406) is connected between the third L-shaped plate (404) and the transmission plate (407); the third spring (406) is sleeved on the sliding column (405); the right side of the sliding column (405) is fixedly connected with a first connecting plate (408); the lower right part of the first connecting plate (408) is fixedly connected with a first wedge-shaped slat (409); the upper part of the right side of the first connecting plate (408) is fixedly connected with a first shovel plate (410); the upper part of the right side of the second L-shaped plate (401) is fixedly connected with a second connecting plate (411); the right part of the lower side of the second connecting plate (411) is fixedly connected with two connecting sliding blocks (412); the lower sides of the two connecting sliding blocks (412) are respectively connected with a spring rod (413); two through sliding grooves are formed in the first shovel plate (410), and two connecting sliding blocks (412) are respectively arranged in one through sliding groove in a sliding manner; the lower sides of the two spring rods (413) are connected with a second wedge-shaped slat (414); the right side of the second wedge-shaped slat (414) is fixedly connected with a second shovel material plate (415).

4. A wrinkle-resistant and shift-resistant high thermal conductivity insulating sheet molding apparatus as defined in claim 3, wherein: the disk (403) rotates eccentrically.

5. The wrinkle-resistant and shift-resistant high thermal conductive insulating board molding apparatus as claimed in any one of claims 1 to 4, wherein: the molding method of the molding equipment comprises the following steps:

step one: laying a film, namely firstly laying a polyimide film in a transfer system manually;

step two: adding silicon collagen liquid, adding a bottom layer of silicon gel stock solution into a transfer system through a glue solution feeding system, and ensuring that polyimide films paved on the bottom layer cannot be impacted by the added silicon collagen liquid to generate wrinkles;

step three: placing the grid cloth, manually paving the glass fiber grid cloth in a transfer system, and adjusting the position of the glass fiber grid cloth through a cloth placing system;

step four: adding liquid for the second time, and adding the upper layer of silica gel stock solution into the transfer system through a glue solution feeding system;

step five: solidifying the glue solution, and solidifying the silica gel stock solution in the transfer system through external heating equipment to form an insulating plate;

step six: and separating, namely separating and taking away the insulating plate in the transfer system through a peripheral punching device.