CN113184546A

CN113184546A - Diamond tool production raw material wavy-pattern stacking system and stacking method thereof

Info

Publication number: CN113184546A
Application number: CN202110317364.2A
Authority: CN
Inventors: 刘超
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-03-25
Filing date: 2021-03-25
Publication date: 2021-07-30

Abstract

The invention relates to the field of diamonds, in particular to a wavy-pattern stacking system and a stacking method for diamond tool production raw materials. The technical problem of the invention is that: provides a diamond tool production raw material wave-shaped stacking system and a stacking method thereof. A diamond tool production raw material wavy type stacking system comprises a working frame plate, an operation control screen, a gluing system, a transferring and turning system and a stacking system; the working frame plate is connected with the operation control screen. The invention achieves the purpose that the diamond coating bodies are distributed on the surface of the matrix sheet in a wavy manner, and meanwhile, the diamond coating bodies are arranged on the two sides of the matrix sheet, so that the whole content of diamonds cannot be influenced, and the diamond coating bodies distributed in a wavy manner can be mutually staggered after being stacked, so that the horizontal interweaving force can be formed, the deviation is avoided, and the stable stacking effect is realized.

Description

Diamond tool production raw material wavy-pattern stacking system and stacking method thereof

Technical Field

The invention relates to the field of diamonds, in particular to a wavy-pattern stacking system and a stacking method for diamond tool production raw materials.

Background

In a common diamond tool, the distribution of diamonds in a matrix is disordered, segregation occurs in the mechanical mixing process, diamonds are gathered, the utilization rate of diamonds is reduced in the cutting process, and the cutting resistance is increased. The ordered diamond arrangement technology can make the diamonds distributed uniformly in the matrix, each diamond can play a role in processing, and the sharpness can be improved by more than thirty percent.

In the prior art, the production process for orderly arranging the fine-grained diamond tools generally places the matrix sheets into the diamond coating body after spraying glue, usually places the diamond coating body on one side after spraying glue on two sides of the matrix sheets, and then compositely stacks a plurality of the matrix sheets with the diamond coating body, but because the diamond coating body needs to be placed for a period of time after spraying glue, other impurities are adhered to the surface of the glue sprayed on one side of the matrix sheets without the diamond coating body in the standing and transferring processes in the process, so that the purity of the product is influenced, the glue on one side of the matrix sheets without the diamond coating body is gradually solidified, the adhesive force between the two groups of matrix sheets and the diamond coating body is greatly reduced when the matrix sheets are compositely stacked, and the stacked matrix sheets and the diamond coating body are offset with each other, cannot be stably stacked and can influence the subsequent hot-pressing sintering.

In combination with the above problems, there is a need for a diamond tool production material corrugated stacking system and a stacking method thereof to solve the above problems.

Disclosure of Invention

In order to overcome the defects that in the prior art, the diamond coating bodies are usually placed in matrix sheets after glue spraying is performed on the matrix sheets, the diamond coating bodies are usually placed on one sides of the matrix sheets after the glue spraying is performed on the two sides of the matrix sheets, then a plurality of the matrix sheets with the diamond coating bodies placed are compounded and stacked, but the diamond coating bodies are placed in a period of time after the glue spraying, so that other impurities are adhered to the surfaces of glue sprayed on the sides, where the diamond coating bodies are not placed, of the matrix sheets in the process of standing and transferring, further the purity of products is influenced, the glue on the sides, where the diamond coating bodies are not placed, of the matrix sheets is gradually solidified, the bonding force between the combinations of the two groups of matrix sheets and the diamond coating bodies is greatly reduced when the matrix sheets are compounded and stacked, and the stacked matrix sheets and diamond coating body combinations are offset with each other, the invention has the technical problems that the stable stacking can not be kept, and the subsequent hot-pressing sintering is influenced, and the invention has the following technical problems: provides a diamond tool production raw material wave-shaped stacking system and a stacking method thereof.

A diamond tool production raw material wavy type stacking system comprises a working frame plate, an operation control screen, a gluing system, a transferring and turning system and a stacking system; the working frame plate is connected with the operation control screen; the working frame plate is connected with the gluing system; the working frame plate is connected with the transfer turnover system; the working frame plate is connected with the stacking system; the transferring and overturning system is connected with the stacking system.

Further explaining, the gluing system comprises a first fixing plate, a first electric push rod, a first electric slide rail, a second electric slide rail, a first electric slide block, a second electric slide block, a first glue box, a first glue spraying opening, a first feeding opening, a first material separating plate and a material loading platform; four corners above the first fixing plate are connected with a group of first electric push rods through bolts; the four groups of first electric push rods are all connected with the working frame plate through bolts; the lower part of the first fixing plate is sequentially connected with a first electric slide rail and a second electric slide rail through bolts; the first electric slide rail is in sliding connection with the first electric slide block; the second electric slide rail is in sliding connection with the second electric slide block; the first electric sliding block and the second electric sliding block are fixedly connected with the first rubber box; the first glue box is connected with the first glue spraying port; the first glue box is connected with the first feeding port; the first fixing plate is fixedly connected with the first material separating plate; a material loading platform is arranged below the first material partition plate; the material loading platform is fixedly connected with the working frame plate.

Further explaining, the transferring and turning system comprises a stepping motor, a first driving wheel, a second driving wheel, a first hexagonal rod, a first driving sleeve, a first bevel gear, a second bevel gear, a first connecting plate, a second electric push rod, a third bevel gear, a first screw rod, a first connecting block, a third electric push rod, a first connecting plate, a connecting roller, a first flat gear, a wheel toothed plate, a fourth electric push rod, a second connecting plate, a fifth electric push rod, a second connecting block, a first polished rod, a third electric slide rail, a third electric slide block, a first clamping plate, a fourth electric slide block and a second clamping plate; an output shaft of the stepping motor is fixedly connected with the first driving wheel; the first driving wheel is in transmission connection with the second driving wheel; the first driving wheel is connected with the stacking system; the second driving wheel is fixedly connected with the first hexagonal prism rod; the first hexagonal rod is connected with the first transmission sleeve in a sliding manner; the first hexagonal rod is rotatably connected with the working frame plate through a support; the outer surface of the first transmission sleeve is fixedly connected with the first bevel gear and the second bevel gear in sequence; the first transmission sleeve is rotatably connected with the first connecting plate through a bearing; the first connecting plate is connected with the second electric push rod through a bolt; the second electric push rod is connected with the working frame plate through a bolt; when the first bevel gear is meshed with the third bevel gear and the second bevel gear is not meshed with the third bevel gear, the third bevel gear rotates forwards, and when the first bevel gear is not meshed with the third bevel gear and the second bevel gear is meshed with the third bevel gear, the third bevel gear rotates backwards; the third bevel gear is arranged on the middle side surface of the first bevel gear and the second bevel gear; the third bevel gear is fixedly connected with the first screw rod; the first screw rod is connected with the first connecting block in a screwing manner; the first screw rod is rotatably connected with the working frame plate through a bracket; the first connecting block is in bolt connection with the third electric push rod; the third electric push rod is in bolted connection with the first connecting plate; the first connecting plate is rotatably connected with the connecting roller; the connecting roller is fixedly connected with the first flat gear; a pinion plate is arranged on the side surface below the first flat gear; when the first flat gear is engaged with the gear tooth plate, the first flat gear moves and rotates simultaneously, and when the first flat gear is not engaged with the gear tooth plate, the first flat gear does not rotate; two groups of fourth electric push rods are arranged below the pinion plate; the two groups of fourth electric push rods are connected with the working frame plate through bolts; the connecting roller is connected with the third electric slide rail through bolts; the connecting roller is rotationally connected with the second connecting plate; the second connecting plate is in bolted connection with the fifth electric push rod; the fifth electric push rod is connected with the second connecting block through a bolt; the second connecting block is in sliding connection with the first polish rod; the first polish rod is fixedly connected with the working frame plate; the third electric slide rail is sequentially connected with the third electric slide block and the fourth electric slide block in a sliding manner; the third electric sliding block is fixedly connected with the first clamping plate; and the fourth electric sliding block is fixedly connected with the second clamping plate.

Further explaining, the stacking system comprises a third transmission wheel, a second hexagonal rod, a second transmission sleeve, a fourth bevel gear, a fifth bevel gear, a second connecting plate, a sixth electric push rod, a sixth bevel gear, a first transmission shaft, a fourth transmission wheel, a fifth transmission wheel, a second screw rod, a second fixed plate, a second polished rod, a fourth electric slide rail, a fifth electric slide block, a second glue box, a second glue spraying port, a second feeding port, a second material separating plate, a seventh bevel gear, a third screw rod, a hollow material limiting plate, a third polished rod, a material loading seat, a sixth electric slide block and a fifth electric slide rail; the third driving wheel is fixedly connected with the second hexagonal prism rod; the outer ring surface of the third driving wheel is in transmission connection with the first driving wheel through a belt; the second hexagonal rod is connected with the second transmission sleeve in a sliding manner; the second hexagonal rod is rotatably connected with the working frame plate through a support; two sides of the outer surface of the second transmission sleeve are fixedly connected with the fourth bevel gear and the fifth bevel gear; the second transmission sleeve is rotationally connected with the second connecting plate through a bearing; the second connecting plate is connected with a sixth electric push rod through a bolt; the sixth electric push rod is connected with the working frame plate through a bolt; when the fourth bevel gear is meshed with the sixth bevel gear and the fifth bevel gear is not meshed with the seventh bevel gear, the sixth bevel gear rotates and the seventh bevel gear does not rotate; the sixth bevel gear is arranged below the side surface of the fourth bevel gear; the fifth bevel gear is meshed with the seventh bevel gear; the sixth bevel gear is fixedly connected with the first transmission shaft; the first transmission shaft is fixedly connected with the fourth transmission wheel; the first transmission shaft is rotatably connected with the working frame plate; the outer ring surface of the fourth driving wheel is in transmission connection with the fifth driving wheel through a belt; the fifth driving wheel is fixedly connected with the second screw rod; the second screw rod is connected with the second fixing plate in a rotating mode; the second screw rod is rotatably connected with the working frame plate; the second fixed plate is in sliding connection with the second polished rod; the second fixing plate is connected with the fourth electric slide rail through a bolt; the second polish rod is fixedly connected with the working frame plate; the fourth electric slide rail is in sliding connection with the fifth electric slide block; the fifth electric sliding block is fixedly connected with the second glue box; the second glue box is fixedly connected with the second glue spraying opening; the second glue box is fixedly connected with the second feeding port; the second fixing plate is fixedly connected with the second material partition plate; the seventh bevel gear is fixedly connected with the third screw rod; the third screw rod is connected with the hollow material limiting plate in a rotating mode; the third screw rod is rotatably connected with the working frame plate; the hollow material limiting plate is in sliding connection with the third polished rod; the third polish rod is fixedly connected with the working frame plate; the loading seat is arranged on the side surface below the hollow material limiting plate; the material loading seat is fixedly connected with the sixth electric sliding block; the sixth electric sliding block is in sliding connection with the fifth electric sliding rail; and the fifth electric slide rail is connected with the working frame plate through bolts.

Further, a rectangular through groove is formed in the first fixing plate.

Further, a plurality of wave-shaped hollow parts are arranged in the first material separating plate and the second material separating plate.

Further, a group of third electric sliding rails, a third electric sliding block, a first clamping plate, a fourth electric sliding block and a second clamping plate are symmetrically arranged on two sides of the connecting roller.

Further, a through groove with the same size as the tire body thin sheet is arranged in the hollow material limiting plate.

A method for stacking diamond tool production raw materials in a wavy manner comprises the following working steps:

s1: coating, namely performing composite coating of metal powder on the surface of the fine-grained diamond to prepare a diamond coated body;

s2: gluing one surface of the matrix sheet by a gluing system, and enabling the grains of glue distribution to be wave-shaped;

s3: preparing a bottom plate, gluing the bottom plate matrix sheet by a stacking system, and placing a layer of diamond coating on the bottom plate matrix sheet;

s4: transferring and turning, namely turning the carcass sheet with one surface coated with the glue in the gluing system and simultaneously transferring the carcass sheet into a stacking system through a transferring and turning system;

s5: stacking, namely, turning over the carcass sheet with one coated surface, then enabling the carcass sheet to be opposite to the coated surface of the bottom plate carcass sheet, and stacking the carcass sheet on the bottom plate carcass sheet through a transfer turning-over system;

s6: and (4) collecting the combination of the matrix thin sheets and the diamond coating body after being stacked for many times.

Compared with the prior art, the invention has the following advantages:

the invention achieves the purposes that the diamond coating bodies are distributed on the surface of the matrix sheet in a wavy manner by spraying the rubber in a wavy manner, and meanwhile, the diamond coating bodies are arranged on the two sides of the matrix sheet, so that the integral content of the diamond cannot be influenced, and the diamond coating bodies distributed in a wavy manner can be staggered after being stacked, so that the interweaving force in the horizontal direction can be formed, the deviation is avoided, and the stable stacking effect is realized;

secondly, the invention is characterized in that a sufficient amount of carcass sheets are firstly placed in a gluing system, then the carcass sheets are glued by the gluing system, the lines of glue distribution are wave-shaped, a carcass sheet is placed in a stacking system, the stacking system is driven by a transfer turning-over system, the carcass sheet is glued by the stacking system, diamond coating bodies are placed, the carcass sheet is used as a bottom plate, then the carcass sheet with one glued surface in the gluing system is turned over by the transfer turning-over system and is transferred into the stacking system, the glued surface of the carcass sheet faces the bottom plate carcass sheet which is placed in the stacking system in advance and is aligned, then the non-glued surface of the second carcass sheet is glued by the stacking system, the diamond coating bodies are placed, and then the gluing system is repeated to glue one surface of the carcass sheet, and then transferring the turning system to turn over and move the matrix sheet into a stacking system, and coating glue on the other surface of the matrix sheet and placing the diamond coating bodies by the stacking system, so that the matrix sheet and the diamond coating bodies are distributed layer by layer at intervals.

Drawings

FIG. 1 is a first perspective view of the present invention;

FIG. 2 is a second perspective view of the present invention;

FIG. 3 is a third perspective view of the present invention;

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

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

FIG. 6 is a schematic perspective view of a first material-separating plate according to the present invention;

FIG. 7 is a schematic view of a first perspective structure of the transfer turn-over system of the present invention;

FIG. 8 is a schematic diagram of a second perspective view of the transfer turn-over system of the present invention;

FIG. 9 is a schematic view of a first perspective configuration of the stacking system of the present invention;

FIG. 10 is a second perspective view of the stacking system of the present invention;

FIG. 11 is a schematic view of a partial perspective view of a stacking system of the present invention;

fig. 12 is a schematic perspective view of a second material-separating plate according to the present invention.

In the above drawings: 1. working frame plate, 2, operation control screen, 3, gluing system, 4, transfer turnover system, 5, stacking system, 301, first fixing plate, 302, first electric push rod, 303, first electric slide rail, 304, second electric slide rail, 305, first electric slide block, 306, second electric slide block, 307, first glue box, 308, first glue spraying opening, 309, first feeding opening, 3010, first material separating plate, 3011, material loading platform, 401, stepping motor, 402, first driving wheel, 403, second driving wheel, 404, first hexagonal rod, 405, first driving sleeve, 406, first bevel gear, 407, second bevel gear, 408, first connecting plate, 409, second electric push rod, 4010, third bevel gear, 4011, first lead screw, 4012, first connecting block, 4013, third electric push rod, 4014, first connecting plate, 4015, connecting roller, 4016, first flat gear, 4017, 4018. a fourth electric push rod, 4019, a second connecting plate, 4020, a fifth electric push rod, 4021, a second connecting block, 4022, a first polished rod, 4023, a third electric sliding rail, 4024, a third electric sliding block, 4025, a first clamping plate, 4026, a fourth electric sliding block, 4027, a second clamping plate, 501, a third transmission wheel, 502, a second hexagonal rod, 503, a second transmission sleeve, 504, a fourth bevel gear, 505, a fifth bevel gear, 506, a second connecting plate, 507, a sixth electric push rod, 508, a sixth bevel gear, 509, a first transmission shaft, 5010, a fourth transmission wheel, 5011, a fifth transmission wheel, 5012, a second screw rod, 5013, a second fixing plate, 5014, a second polished rod, 5015, a fourth electric sliding rail, 5016, a fifth electric sliding block, 5017, a second glue box, 5018, a second glue spraying opening, 5019, a second feeding opening, 5020, a second material adding plate, a seventh material separating plate, 5021, a third bevel gear, 5022, a fifth electric sliding block, a second screw rod, 5012, a second feeding plate, 5027, a second screw rod, 5028, a second bevel gear, 5022, a second bevel gear, a second screw rod, 5022, a fifth bevel gear, 5022, a fourth screw rod, 5027, 5023. a hollow material limiting plate, 5024, a third polished rod, 5025, a material loading seat, 5026, a sixth electric slider, 5027 and a fifth electric sliding rail.

Detailed Description

Although the present invention may be described with respect to particular applications or industries, those skilled in the art will recognize the broader applicability of the invention. Those of ordinary skill in the art will recognize other factors such as: terms such as above, below, upward, downward, and the like are used to describe the accompanying drawings and are not meant to limit the scope of the invention, which is defined by the appended claims. Such as: any numerical designation of first or second, and the like, is merely exemplary and is not intended to limit the scope of the invention in any way.

Example 1

A diamond tool production raw material wavy type stacking system is shown in figures 1-12 and comprises a working frame plate 1, an operation control screen 2, a gluing system 3, a transfer turnover system 4 and a stacking system 5; the working frame plate 1 is connected with the operation control screen 2; the working frame plate 1 is connected with a gluing system 3; the working frame plate 1 is connected with a transfer turnover system 4; the working frame plate 1 is connected with a stacking system 5; the transfer turn-over system 4 is connected to a stacking system 5.

The working process is as follows: when the device is used, the device is horizontally fixed on a working plane to be used, a power supply is connected externally, an operator carries out integral allocation on the device through the operation control screen 2 to prepare a tyre body sheet and a diamond coating body to be processed, the device is firstly carried out operation debugging and starts to work after debugging is finished, firstly, enough tyre body sheet is placed in the gluing system 3, then the tyre body sheet is glued through the gluing system 3, the grain of glue distribution is in a wave shape, a tyre body sheet is placed in the stacking system 5, the stacking system 5 is driven through the transferring and turning system 4, the tyre body sheet is glued through the stacking system 5 and the diamond coating body is placed, the tyre body sheet is used as a bottom plate, then the tyre body sheet glued on one side in the gluing system 3 is turned over through the transferring and turning system 4 and is transferred into the stacking system 5 at the same time, the gluing surface of the matrix sheet faces to a bottom plate matrix sheet which is placed in advance by a stacking system 5 and is aligned, then the gluing surface of the second matrix sheet is glued and diamond coating bodies are placed on the non-gluing surface by the stacking system 5, then the gluing system 3 is repeated to glue one surface of the matrix sheet, then a transfer turning system 4 is used for turning and moving the matrix sheet to the stacking system 5, the stacking system 5 is used for coating glue on the other surface of the matrix sheet and placing the diamond coating bodies, so that the matrix sheet and the diamond coating bodies are distributed layer by layer, the device achieves the purpose that the diamond coating bodies are distributed in a wavy form on the surface of the matrix sheet by wavy pattern glue spraying, meanwhile, the diamond coating bodies are placed on both sides of the matrix sheet, therefore, the integral content of diamond cannot be influenced, and the diamond coating bodies distributed in a wavy form can be mutually staggered after being stacked, and then the interweaving force in the horizontal direction can be formed, the deviation is avoided, and the stable stacking effect is realized.

The gluing system 3 comprises a first fixing plate 301, a first electric push rod 302, a first electric slide rail 303, a second electric slide rail 304, a first electric slide block 305, a second electric slide block 306, a first glue box 307, a first glue spraying opening 308, a first feeding opening 309, a first material separating plate 3010 and a material loading platform 3011; four corners above the first fixing plate 301 are connected with a group of first electric push rods 302 through bolts; the four groups of first electric push rods 302 are all connected with the working frame plate 1 through bolts; the lower part of the first fixing plate 301 is sequentially connected with a first electric slide rail 303 and a second electric slide rail 304 through bolts; the first electric slide rail 303 is connected with the first electric slide block 305 in a sliding manner; the second electric slide rail 304 is connected with the second electric slide block 306 in a sliding manner; the first electric sliding block 305 and the second electric sliding block 306 are both fixedly connected with a first glue box 307; the first glue box 307 is connected with the first glue spraying port 308; the first glue box 307 is connected with a first feeding port 309; the first fixing plate 301 is fixedly connected with the first material separating plate 3010; a material loading platform 3011 is arranged below the first material separating plate 3010; the material loading platform 3011 is fixedly connected with the working frame plate 1.

Firstly, placing a sufficient amount of carcass sheets on a material loading platform 3011, adding a sufficient amount of glue into a first glue box 307 through a first feeding port 309, starting four groups of first electric push rods 302 at four corners above a first fixing plate 301, enabling the first fixing plate 301 and components connected with the first fixing plate 301 to synchronously move downwards, further enabling a first material separating plate 3010 to move downwards to be in contact with the upper surface of the uppermost carcass sheet, then starting a first electric slide rail 303 and a second electric slide rail 304, enabling the first electric slide rail 303 to control a first electric slide block 305 to move, enabling the second electric slide rail 304 to control a second electric slide block 306 to move, further enabling the first electric slide block 305 and the second electric slide block 306 to drive the first glue box 307, the first glue spraying port 308 and the first feeding port 309 to synchronously move, simultaneously controlling the first glue spraying port 308 to spray glue downwards, and arranging a plurality of wave-shaped hollow parts in the first material separating plate 3010, the glue can be coated on the upper surface of the carcass sheet only through the wavy hollow part in the first material partition plate 3010, so that a plurality of groups of wavy glue layers are formed on the upper surface of the carcass sheet, after the glue is coated, the next carcass sheet is continuously coated by moving the carcass sheet away through the transfer turn-over system 4, and the system realizes the wavy glue spraying on the carcass sheet.

The transfer turn-over system 4 comprises a stepping motor 401, a first driving wheel 402, a second driving wheel 403, a first hexagonal rod 404, a first driving sleeve 405, a first bevel gear 406, a second bevel gear 407, a first connecting plate 408, a second electric push rod 409, a third bevel gear 4010, a first screw 4011, a first connecting block 4012, a third electric push rod 4013, a first connecting plate 4014, a connecting roller 4015, a first flat gear 4016, a gear tooth plate 4017, a fourth electric push rod 4018, a second connecting plate 4019, a fifth electric push rod 4020, a second connecting block 4021, a first polished rod 4022, a third electric slide rail 4023, a third electric slide block 4024, a first clamping plate 4025, a fourth electric slide block 4026 and a second clamping plate 4027; an output shaft of the stepping motor 401 is fixedly connected with the first driving wheel 402; the first driving wheel 402 is in driving connection with a second driving wheel 403; the first driving wheel 402 is connected with the stacking system 5; the second driving wheel 403 is fixedly connected with the first hexagonal rod 404; the first hexagonal rod 404 is slidably connected with the first transmission sleeve 405; the first hexagonal rod 404 is rotatably connected with the working frame plate 1 through a bracket; the outer surface of the first transmission sleeve 405 is fixedly connected with a first bevel gear 406 and a second bevel gear 407 in sequence; the first driving sleeve 405 is rotatably connected with the first connecting plate 408 through a bearing; the first linkage plate 408 is bolted to a second electric push rod 409; the second electric push rod 409 is connected with the working frame plate 1 through a bolt; when the first bevel gear 406 is meshed with the third bevel gear 4010 and the second bevel gear 407 is not meshed with the third bevel gear 4010, the third bevel gear 4010 rotates forwards, and when the first bevel gear 406 is not meshed with the third bevel gear 4010 and the second bevel gear 407 is meshed with the third bevel gear 4010, the third bevel gear 4010 rotates backwards; the third bevel gear 4010 is arranged on the middle side surface of the first bevel gear 406 and the second bevel gear 407; the third bevel gear 4010 is fixedly connected with the first screw 4011; the first screw rod 4011 is rotatably connected with the first connecting block 4012; the first screw 4011 is rotatably connected with the working frame plate 1 through a bracket; the first connecting block 4012 is connected with a third electric push rod 4013 through a bolt; the third electric push rod 4013 is connected with the first connecting plate 4014 through a bolt; the first connecting plate 4014 is rotatably connected to a connecting roller 4015; the connecting roller 4015 is fixedly connected with a first flat gear 4016; a pinion plate 4017 is arranged on the side surface below the first flat gear 4016; when the first flat gear 4016 is engaged with the cog plate 4017, the first flat gear 4016 moves while rotating, and when the first flat gear 4016 is not engaged with the cog plate 4017, the first flat gear 4016 does not rotate; two groups of fourth electric push rods 4018 are arranged below the gear tooth plate 4017; the two groups of fourth electric push rods 4018 are connected with the working frame plate 1 through bolts; the connecting roller 4015 is connected with the third electric slide rail 4023 through a bolt; the connecting roller 4015 is rotatably connected to the second connecting plate 4019; the second connecting plate 4019 is in bolted connection with a fifth electric push rod 4020; the fifth electric push rod 4020 is connected with the second connecting block 4021 through a bolt; the second connecting block 4021 is in sliding connection with the first polish rod 4022; the first polish rod 4022 is fixedly connected with the working frame plate 1; the third electric slide rail 4023 is in sliding connection with the third electric slide block 4024 and the fourth electric slide block 4026 in sequence; the third electric sliding block 4024 is fixedly connected with the first clamping plate 4025; the fourth electric slider 4026 is fixedly connected to the second clamp plate 4027.

After a matrix sheet is coated by the glue coating system 3, the heights of a third electric slide rail 4023, a third electric slide block 4024, a first clamping plate 4025, a fourth electric slide block 4026 and a second clamping plate 4027 are adjusted through a third electric push rod 4013 and a fifth electric push rod 4020, so that the first clamping plate 4025 and the second clamping plate 4027 move to the positions on the two sides of the matrix sheet, then the third electric slide rail 4024 and the fourth electric slide block 4026 are controlled through the third electric slide rail 4023, the first clamping plate 4025 is driven to move through the third electric slide block 4024, the second clamping plate 4027 is driven to move through the fourth electric slide block 4026, so that the first clamping plate 4025 and the second clamping plate 4027 move close to each other, so that the matrix sheet is clamped, at the moment, a stepping motor 401 drives a first driving wheel 402 to rotate, the first driving wheel 402 drives a second driving wheel 403 through a belt, the first driving wheel 402 drives a stacking system 5, and a first sixth driving wheel 403 drives a prism rod 404 to rotate, the first driving sleeve 405 is driven to rotate by the first hexagonal rod 404, the first bevel gear 406 and the second bevel gear 407 are driven to rotate by the first driving sleeve 405, the first connecting plate 408 is pushed by the second electric push rod 409, the first driving sleeve 405, the first bevel gear 406 and the second bevel gear 407 are controlled to integrally move, the first driving sleeve 405 slides on the surface of the first hexagonal rod 404, the selective engagement between the first bevel gear 406 and the second bevel gear 407 and the third bevel gear 4010 can be controlled, when the first bevel gear 406 is engaged with the third bevel gear 4010 and the second bevel gear 407 is not engaged with the third bevel gear 4010, the third bevel gear 4010 rotates forwards, when the first bevel gear 406 is not engaged with the third bevel gear 4010 and the second bevel gear 407 is engaged with the third bevel gear 4010, the third bevel gear 4010 rotates backwards, and at this time, the third bevel gear 4010 is controlled to drive the first lead screw 4011 to rotate forwards, and further, the first connecting block 4012 screwed with the first connecting block is driven to move through the first lead screw 4011, the third electric push rod 4013, the first connecting plate 4014, the connecting roller 4015, the first flat gear 4016, the second connecting plate 4019, the fifth electric push rod 4020, the third electric slide rail 4023, the third electric slide block 4024, the first clamping plate 4025, the fourth electric slide block 4026 and the second clamping plate 4027 are driven to synchronously move through the first connecting block 4012, the second connecting block 4021 is matched with the first smooth rod 4022 in a sliding manner, so that the clamped carcass thin sheet is transferred, meanwhile, two groups of fourth electric push rods 4018 arranged below the wheel tooth plate 4017 are started, so that the wheel tooth plate 4017 moves upwards to a height position capable of being meshed with the first flat gear 4016, when the first flat gear 4016 moves to a position mutually meshed with the wheel tooth plate 4017, the first flat gear 4016 can rotate in the moving process, so as to drive the connecting roller 4015 and the connected components to synchronously rotate, and then realize turning over one hundred eighty degrees the matrix sheet, make the rubber coating face down, then align when moving to the position of stacking in the system of stacking 5 and put down, later each part resets, prepares to shift the upset to next matrix sheet, and this system has realized shifting the upset to the matrix sheet, makes the matrix sheet can stack layer upon layer fast.

The stacking system 5 comprises a third transmission wheel 501, a second hexagonal prism 502, a second transmission sleeve 503, a fourth bevel gear 504, a fifth bevel gear 505, a second connecting plate 506, a sixth electric push rod 507, a sixth bevel gear 508, a first transmission shaft 509, a fourth transmission wheel 5010, a fifth transmission wheel 5011, a second lead screw 5012, a second fixing plate 5013, a second polished rod 5014, a fourth electric slide rail 5015, a fifth electric slider 5016, a second glue tank 5017, a second glue spraying port 5018, a second feeding port 5019, a second partition plate 5020, a seventh bevel gear 5021, a third lead screw 5022, a hollow material limiting plate 5023, a third polished rod 5024, a material carrying seat 5025, a sixth electric slider 5026 and a fifth electric slide rail 5027; the third driving wheel 501 is fixedly connected with a second hexagonal rod 502; the outer ring surface of the third driving wheel 501 is in transmission connection with the first driving wheel 402 through a belt; the second hexagonal rod 502 is slidably connected with the second transmission sleeve 503; the second hexagonal rod 502 is rotatably connected with the working frame plate 1 through a bracket; two sides of the outer surface of the second transmission sleeve 503 are fixedly connected with a fourth bevel gear 504 and a fifth bevel gear 505; the second transmission sleeve 503 is rotatably connected with the second connection plate 506 through a bearing; the second engaging plate 506 is bolted to a sixth electric putter 507; the sixth electric push rod 507 is connected with the working frame plate 1 through a bolt; when the fourth bevel gear 504 is meshed with the sixth bevel gear 508 and the fifth bevel gear 505 is not meshed with the seventh bevel gear 5021, the sixth bevel gear 508 rotates and the seventh bevel gear 5021 does not rotate, and when the fourth bevel gear 504 is not meshed with the sixth bevel gear 508 and the fifth bevel gear 505 is meshed with the seventh bevel gear 5021, the sixth bevel gear 508 does not rotate and the seventh bevel gear 5021 rotates; the sixth bevel gear 508 is disposed below the side of the fourth bevel gear 504; the fifth bevel gear 505 is engaged with the seventh bevel gear 5021; the sixth bevel gear 508 is fixedly connected with a first transmission shaft 509; the first transmission shaft 509 is fixedly connected with the fourth transmission wheel 5010; the first transmission shaft 509 is rotatably connected with the working frame plate 1; the outer ring surface of the fourth transmission wheel 5010 is in transmission connection with the fifth transmission wheel 5011 through a belt; the fifth transmission wheel 5011 is fixedly connected with a second lead screw 5012; the second lead screw 5012 is screwed with the second fixing plate 5013; the second screw 5012 is rotatably connected with the working frame plate 1; the second fixing plate 5013 is in sliding connection with the second polish rod 5014; the second fixing plate 5013 is connected with a fourth electric slide rail 5015 through bolts; the second polish rod 5014 is fixedly connected with the working frame plate 1; the fourth electric sliding rail 5015 is in sliding connection with the fifth electric sliding block 5016; the fifth electric sliding block 5016 is fixedly connected with the second glue box 5017; the second glue box 5017 is fixedly connected with a second glue spraying opening 5018; the second glue box 5017 is fixedly connected with the second feeding port 5019; the second fixing plate 5013 is fixedly connected with the second material separating plate 5020; the seventh bevel gear 5021 is fixedly connected with the third lead screw 5022; the third screw rod 5022 is screwed with the hollow material limiting plate 5023; the third screw rod 5022 is rotatably connected with the working frame plate 1; the hollow material limiting plate 5023 is in sliding connection with the third polished rod 5024; the third polish rod 5024 is fixedly connected with the working frame plate 1; the material loading seat 5025 is arranged on the side surface below the hollow material limiting plate 5023; the material loading seat 5025 is fixedly connected with the sixth electric slider 5026; the sixth electric slider 5026 is slidably connected with the fifth electric sliding rail 5027; the fifth electric sliding rail 5027 is connected with the working frame plate 1 through a bolt.

Firstly, manually placing a bottom plate matrix sheet on a material carrying seat 5025, arranging two groups of combinations of a sixth electric slider 5026 and a fifth electric sliding rail 5027 below the material carrying seat 5025, controlling the sixth electric slider 5026 to move through the fifth electric sliding rail 5027, further enabling the material carrying seat 5025 and the bottom plate matrix sheet to move, firstly moving the bottom plate matrix sheet to the position below a second material separating plate 5020, driving a third driving wheel 501 to rotate through a first driving wheel 402, further driving a second six-edge rod 502 to rotate through the third driving wheel 501, further driving a fourth bevel gear 504 and a fifth bevel gear 505 to rotate through the second six-edge rod 502, driving a second connecting plate 502506 through a sixth electric push rod 507, further controlling a second transmission sleeve 503, the fourth bevel gear 504 and a fifth bevel gear 505 to move, the second transmission sleeve 503 to slide on the surface of the second six-edge rod 502, further controlling the fourth bevel gear 504 to be selectively meshed with the sixth bevel gear 508 and the fifth bevel gear 505 and the seventh bevel gear 1 to be selectively meshed with the fifth bevel gear 505 When the fourth bevel gear 504 is meshed with the sixth bevel gear 508 and the fifth bevel gear 505 is not meshed with the seventh bevel gear 5021, the sixth bevel gear 508 rotates and the seventh bevel gear 5021 does not rotate, when the fourth bevel gear 504 is not meshed with the sixth bevel gear 508 and the fifth bevel gear 505 is meshed with the seventh bevel gear 5021, the sixth bevel gear 508 does not rotate and the seventh bevel gear 5021 rotates, at this time, the fourth bevel gear 504 and the sixth bevel gear 508 are controlled to be meshed with each other, namely, the sixth bevel gear 508 rotates, the first transmission shaft 509 is driven to rotate by the sixth bevel gear 508, the fourth transmission wheel 5010 is driven to rotate by the first transmission shaft 509, the fifth transmission wheel 5011 is driven to rotate by the fourth transmission wheel 5010, the second lead screw 5012 is driven to rotate by the fifth transmission wheel 5011, and the second fixing plate 5013 which is screwed with the second lead screw 5012 is driven to move by the second lead screw 5012, at this time, the second fixing plate 5013 is controlled to move downwards, and at the same time, the second fixing plate 5013 slides on the surface of the second polish rod 5014, so that the second fixing plate 5013 drives the fourth electric sliding rail 5015, the fifth electric sliding block 5016, the second rubber box 5017, the second glue spraying port 5018, the second feeding port 5019 and the second material separating plate 5020 to synchronously move downwards, so that the second material separating plate 5020 moves downwards to be in contact with the upper surface of the slab matrix sheet on the material carrying seat 5025, a sufficient amount of glue is added into the second rubber box 5017 through the second feeding port 5019, then the glue in the second rubber box 5017 is sprayed onto the second material separating plate 5020 through the second glue spraying port 5018, a plurality of wave-shaped hollow parts are arranged in the second material separating plate 5020, the glue can only pass through the wave-shaped hollow parts in the second material separating plate 5020 and is coated on the upper surface of the slab matrix sheet, so that a plurality of wave-shaped water layers are formed on the upper surface of the slab matrix sheet, and after the glue is coated, the material loading seat 5025 and the bottom plate matrix sheet move to the lower part of the hollow material limiting plate 5023 through the cooperation of the sixth electric slider 5026 and the fifth electric sliding rail 5027, at the moment, the fifth bevel gear 505 and the seventh bevel gear 5021 are controlled to be meshed through the cooperation of the sixth electric push rod 507, even if the fifth bevel gear 505 drives the seventh bevel gear 5021 to rotate, the seventh bevel gear 5021 drives the third screw rod 5022 to rotate, the hollow material limiting plate 5023 which is screwed with the third screw rod 5022 is driven to move downwards to be at the same height with the upper surface of the bottom plate matrix sheet through the rotation of the third screw rod 5022, the middle of the hollow material limiting plate 5023 is provided with a hollow part with the same size as the bottom plate matrix sheet, the upper surface of the bottom plate matrix sheet can be surrounded, then the diamond coating body is manually placed on the upper surface of the bottom plate matrix sheet, and the diamond coating body is only bonded with the bottom plate matrix sheet through the glue position because the upper surface of the bottom plate matrix sheet is distributed in a plurality of groups of wave patterns, the rest parts have no adhesive connection, then the sixth electric slide block 5026 and the fifth electric slide rail 5027 are matched to control the material loading seat 5025 to drive the bottom plate carcass sheet to move to the position where the transfer turn-over system 4 is to be stacked, then the carcass sheet clamped by the transfer turn-over system 4 is placed on the bottom plate carcass sheet and aligned with each other, at the moment, the gluing part of the carcass sheet clamped by the transfer turn-over system 4 and the gluing part on the bottom plate carcass sheet are distributed at intervals and can be mutually embedded, so that after the carcass sheet clamped by the transfer turn-over system 4 moves downwards to be contacted with the bottom plate carcass sheet, the carcass sheet clamped by the transfer turn-over system 4 can be adhered with the non-adhered diamond coating body on the bottom plate carcass sheet through glue, and the carcass sheet clamped by the transfer turn-over system 4 and the bottom plate carcass sheet are respectively adhered with half of the diamond coating body, and the bonded diamond coating bodies are distributed in a plurality of groups of wavy patterns, so that the diamond coating bodies bonded with the matrix sheets clamped by the transfer turn-over system 4 are mutually embedded with the diamond coating bodies bonded with the matrix sheets of the bottom plate in a wavy pattern, further the diamond coating bodies form a horizontal interweaving force, the matrix sheets cannot deviate, the process is repeated, the subsequent matrix sheets and the diamond coating bodies are stacked layer by layer, and the system realizes the stacking of the matrix sheets and the diamond coating bodies.

A rectangular through groove is formed in the first fixing plate 301.

A space may be provided for the first charging port 309 to move.

A plurality of wave-shaped hollow parts are arranged in the first material separating plate 3010 and the second material separating plate 5020.

Can form a plurality of groups of wavy glue layers on the upper surface of the carcass sheet.

A set of third electric slide rails 4023, third electric sliders 4024, a first clamping plate 4025, a fourth electric slider 4026 and a second clamping plate 4027 are symmetrically arranged on two sides of the connecting roller 4015.

Can be used alternatively to clamp the carcass sheet.

A through groove with the same size as the carcass sheet is arranged in the hollow material limiting plate 5023.

The upper surface of the soleplate matrix sheet can be surrounded, so that the diamond coating body can be conveniently placed.

s2: gluing one surface of the matrix sheet by a gluing system 3, and enabling the grains of glue distribution to be wave-shaped;

s3: preparing a bottom plate, gluing the bottom plate matrix sheet through a stacking system 5, and placing a layer of diamond coating on the bottom plate matrix sheet;

s4: transferring and turning, namely turning the carcass sheet with one surface coated with the glue in the gluing system 3 by using a transferring and turning system 4 and simultaneously transferring the carcass sheet into a stacking system 5;

s5: stacking, wherein the carcass sheet with one coated surface is opposite to the coated surface of the bottom plate carcass sheet after being turned over, and the carcass sheet is stacked on the bottom plate carcass sheet through a transfer turning-over system 4;

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.

Claims

1. The utility model provides a system is stacked to diamond instrument raw materials for production waviness type, including work frame plate and operation control screen, characterized by: the device also comprises a gluing system, a transferring and turning system and a stacking system; the working frame plate is connected with the operation control screen; the working frame plate is connected with the gluing system; the working frame plate is connected with the transfer turnover system; the working frame plate is connected with the stacking system; the transferring and overturning system is connected with the stacking system.

2. A diamond tool production feedstock waviness type stacking system according to claim 1, wherein: the gluing system comprises a first fixing plate, a first electric push rod, a first electric slide rail, a second electric slide rail, a first electric slide block, a second electric slide block, a first glue box, a first glue spraying opening, a first feeding opening, a first material separating plate and a material loading platform; four corners above the first fixing plate are connected with a group of first electric push rods through bolts; the four groups of first electric push rods are all connected with the working frame plate through bolts; the lower part of the first fixing plate is sequentially connected with a first electric slide rail and a second electric slide rail through bolts; the first electric slide rail is in sliding connection with the first electric slide block; the second electric slide rail is in sliding connection with the second electric slide block; the first electric sliding block and the second electric sliding block are fixedly connected with the first rubber box; the first glue box is connected with the first glue spraying port; the first glue box is connected with the first feeding port; the first fixing plate is fixedly connected with the first material separating plate; a material loading platform is arranged below the first material partition plate; the material loading platform is fixedly connected with the working frame plate.

3. A diamond tool production feedstock waviness type stacking system according to claim 2, wherein: the transfer turnover system comprises a stepping motor, a first driving wheel, a second driving wheel, a first hexagonal rod, a first driving sleeve, a first bevel gear, a second bevel gear, a first connecting plate, a second electric push rod, a third bevel gear, a first screw rod, a first connecting block, a third electric push rod, a first connecting plate, a connecting roller, a first flat gear, a toothed plate, a fourth electric push rod, a second connecting plate, a fifth electric push rod, a second connecting block, a first polished rod, a third electric slide rail, a third electric slide block, a first clamping plate, a fourth electric slide block and a second clamping plate; an output shaft of the stepping motor is fixedly connected with the first driving wheel; the first driving wheel is in transmission connection with the second driving wheel; the first driving wheel is connected with the stacking system; the second driving wheel is fixedly connected with the first hexagonal prism rod; the first hexagonal rod is connected with the first transmission sleeve in a sliding manner; the first hexagonal rod is rotatably connected with the working frame plate through a support; the outer surface of the first transmission sleeve is fixedly connected with the first bevel gear and the second bevel gear in sequence; the first transmission sleeve is rotatably connected with the first connecting plate through a bearing; the first connecting plate is connected with the second electric push rod through a bolt; the second electric push rod is connected with the working frame plate through a bolt; when the first bevel gear is meshed with the third bevel gear and the second bevel gear is not meshed with the third bevel gear, the third bevel gear rotates forwards, and when the first bevel gear is not meshed with the third bevel gear and the second bevel gear is meshed with the third bevel gear, the third bevel gear rotates backwards; the third bevel gear is arranged on the middle side surface of the first bevel gear and the second bevel gear; the third bevel gear is fixedly connected with the first screw rod; the first screw rod is connected with the first connecting block in a screwing manner; the first screw rod is rotatably connected with the working frame plate through a bracket; the first connecting block is in bolt connection with the third electric push rod; the third electric push rod is in bolted connection with the first connecting plate; the first connecting plate is rotatably connected with the connecting roller; the connecting roller is fixedly connected with the first flat gear; a pinion plate is arranged on the side surface below the first flat gear; when the first flat gear is engaged with the gear tooth plate, the first flat gear moves and rotates simultaneously, and when the first flat gear is not engaged with the gear tooth plate, the first flat gear does not rotate; two groups of fourth electric push rods are arranged below the pinion plate; the two groups of fourth electric push rods are connected with the working frame plate through bolts; the connecting roller is connected with the third electric slide rail through bolts; the connecting roller is rotationally connected with the second connecting plate; the second connecting plate is in bolted connection with the fifth electric push rod; the fifth electric push rod is connected with the second connecting block through a bolt; the second connecting block is in sliding connection with the first polish rod; the first polish rod is fixedly connected with the working frame plate; the third electric slide rail is sequentially connected with the third electric slide block and the fourth electric slide block in a sliding manner; the third electric sliding block is fixedly connected with the first clamping plate; and the fourth electric sliding block is fixedly connected with the second clamping plate.

4. A diamond tool production feedstock waviness type stacking system according to claim 3, wherein: the stacking system comprises a third transmission wheel, a second hexagonal prism bar, a second transmission sleeve, a fourth bevel gear, a fifth bevel gear, a second connecting plate, a sixth electric push rod, a sixth bevel gear, a first transmission shaft, a fourth transmission wheel, a fifth transmission wheel, a second screw rod, a second fixed plate, a second polished rod, a fourth electric slide rail, a fifth electric slide block, a second glue box, a second glue spraying opening, a second feeding opening, a second material separating plate, a seventh bevel gear, a third screw rod, a hollow material limiting plate, a third polished rod, a material loading seat, a sixth electric slide block and a fifth electric slide rail; the third driving wheel is fixedly connected with the second hexagonal prism rod; the outer ring surface of the third driving wheel is in transmission connection with the first driving wheel through a belt; the second hexagonal rod is connected with the second transmission sleeve in a sliding manner; the second hexagonal rod is rotatably connected with the working frame plate through a support; two sides of the outer surface of the second transmission sleeve are fixedly connected with the fourth bevel gear and the fifth bevel gear; the second transmission sleeve is rotationally connected with the second connecting plate through a bearing; the second connecting plate is connected with a sixth electric push rod through a bolt; the sixth electric push rod is connected with the working frame plate through a bolt; when the fourth bevel gear is meshed with the sixth bevel gear and the fifth bevel gear is not meshed with the seventh bevel gear, the sixth bevel gear rotates and the seventh bevel gear does not rotate; the sixth bevel gear is arranged below the side surface of the fourth bevel gear; the fifth bevel gear is meshed with the seventh bevel gear; the sixth bevel gear is fixedly connected with the first transmission shaft; the first transmission shaft is fixedly connected with the fourth transmission wheel; the first transmission shaft is rotatably connected with the working frame plate; the outer ring surface of the fourth driving wheel is in transmission connection with the fifth driving wheel through a belt; the fifth driving wheel is fixedly connected with the second screw rod; the second screw rod is connected with the second fixing plate in a rotating mode; the second screw rod is rotatably connected with the working frame plate; the second fixed plate is in sliding connection with the second polished rod; the second fixing plate is connected with the fourth electric slide rail through a bolt; the second polish rod is fixedly connected with the working frame plate; the fourth electric slide rail is in sliding connection with the fifth electric slide block; the fifth electric sliding block is fixedly connected with the second glue box; the second glue box is fixedly connected with the second glue spraying opening; the second glue box is fixedly connected with the second feeding port; the second fixing plate is fixedly connected with the second material partition plate; the seventh bevel gear is fixedly connected with the third screw rod; the third screw rod is connected with the hollow material limiting plate in a rotating mode; the third screw rod is rotatably connected with the working frame plate; the hollow material limiting plate is in sliding connection with the third polished rod; the third polish rod is fixedly connected with the working frame plate; the loading seat is arranged on the side surface below the hollow material limiting plate; the material loading seat is fixedly connected with the sixth electric sliding block; the sixth electric sliding block is in sliding connection with the fifth electric sliding rail; and the fifth electric slide rail is connected with the working frame plate through bolts.

5. A diamond tool production feedstock waviness type stacking system according to claim 4, wherein: a rectangular through groove is formed in the first fixing plate.

6. A diamond tool production feedstock waviness type stacking system according to claim 5, wherein: a plurality of wave-shaped hollow parts are arranged in the first material separating plate and the second material separating plate.

7. A diamond tool production feedstock waviness type stacking system according to claim 6, wherein: a group of third electric slide rails, a third electric slide block, a first clamping plate, a fourth electric slide block and a second clamping plate are symmetrically arranged on two sides of the connecting roller.

8. A diamond tool production feedstock waviness type stacking system, according to claim 7, wherein: the hollow material limiting plate is internally provided with a through groove with the same size as the tyre body sheet.

9. A method for stacking diamond tool production raw materials in a wavy pattern mode is characterized by comprising the following steps: the method comprises the following working steps: