CN112355735A

CN112355735A - Ceramic-based stone composite board forming processing method

Info

Publication number: CN112355735A
Application number: CN202011239127.0A
Authority: CN
Inventors: 张永好; 谢芳
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-11-09
Filing date: 2020-11-09
Publication date: 2021-02-12

Abstract

The invention relates to a ceramic-based stone composite board forming and processing method, which adopts the following ceramic-based stone composite board forming and processing equipment, wherein the ceramic-based stone composite board forming and processing equipment comprises a support, a fixing device and a polishing device; the lower end face of the support is arranged at the upper end of the processing table, the fixing device is arranged in the middle of the support, and the polishing device is arranged on the inner wall of the support. According to the ceramic-based stone composite plate polishing device, the positions of the setting plate and the polishing head of the polishing device can be adjusted according to the size of the ceramic-based stone composite plate, so that ceramic-based stone composite plates with different sizes and shapes can be polished, and the processing cost is saved; the ceramic-based stone composite board has the advantages that the end face, the hole and the outer wall of the ceramic-based stone composite board are sequentially polished by the polishing device, the continuity of work is guaranteed, the time of a conversion process is saved, and accordingly better working efficiency is achieved.

Description

Ceramic-based stone composite board forming processing method

Technical Field

The invention relates to the field of ceramic-based stone composite boards, in particular to a method for forming and processing a ceramic-based stone composite board.

Background

Composite panels are generally divided into: metal clad plate, timber composite sheet, various steel composite sheet, rock wool composite sheet and stone material composite sheet, the composite sheet has the board that different material layering of different functions constitutes, the stone material composite sheet is formed by two kinds and above different panel bonding for the adhesive, the plane materiel is natural stone material, the substrate is ceramic tile, stone material, glass or aluminium honeycomb, stone material composite sheet light in weight, intensity is high, the antipollution ability is strong and simple to operate, performance comparison advantage in having the practicality again, this sustainable development situation that has also decided its future market.

Because the ceramic base stone composite sheet shaping back surface is rough there is the burr, need polish the processing to it, because ceramic base stone composite sheet has anomalous shape and size, consequently still has following problem in the processing procedure of polishing:

(1) because some ceramic matrix stone composite plates have irregular shapes and sizes, the end surfaces, the inner walls and the outer walls of the ceramic matrix stone composite plates with different sizes and shapes are polished, and corresponding polishing equipment needs to be purchased by manufacturers, so that the processing cost is increased;

(2) when polishing the ceramic matrix stone composite board, the terminal surface, the inner wall or downthehole and outer wall of ceramic matrix stone composite board all need polish, if divide into a plurality of processes and polish a plurality of faces of ceramic matrix stone composite board, need spend time at the in-process of process conversion to machining efficiency has been influenced.

In order to solve the problems, the invention provides a method for forming and processing a ceramic matrix stone composite plate.

Disclosure of Invention

In order to achieve the purpose, the invention adopts the following technical scheme to realize the purpose: a ceramic-based stone composite board forming processing method adopts the following ceramic-based stone composite board forming processing equipment, wherein the ceramic-based stone composite board forming processing equipment comprises a support, a fixing device and a polishing device; the lower end face of the support is arranged at the upper end of the processing table, the fixing device is arranged in the middle of the support, and the polishing device is arranged on the inner wall of the support;

the support comprises an H-shaped base, a bottom plate, a connecting plate, a left side plate, a right side plate and a rear plate, wherein the lower end of the H-shaped base is installed at the upper end of the machining table, the upper end surface of the H-shaped base is connected with the lower end surface of the upper end of the bottom plate, the upper end surface of the bottom plate is connected with the upper end surface of the connecting plate, the left side plate is installed at the position, close to the left end, of the upper end surface of the connecting plate, the right side plate is installed at the position, close to the;

the fixing device comprises an electric push rod, a sliding plate, a bidirectional screw rod, a mounting box, a forward and reverse rotation motor, a sliding block and a clamping block, wherein a circular groove is formed in the middle of the upper end face of the connecting plate, the circular groove is formed in the middle of the upper end face of the connecting plate and is connected to the middle of the H-shaped base, the telescopic end of the electric push rod is connected with the middle of the lower end face of the sliding plate, a sliding groove is formed in the upper end face of the sliding plate, a rotating groove is formed in the middle of the front end of the sliding plate, the outer wall of the front side of the bidirectional screw rod is connected with the rotating groove in a matching mode, the mounting box is mounted at the front end of the sliding plate, the forward and reverse rotation motor is mounted in the mounting box, the front end of the bidirectional screw rod is connected with the output shaft of the forward, the sliding blocks are connected with the outer wall of the bidirectional screw rod through thread fit, clamping blocks are mounted on the upper end faces of the sliding blocks, and the clamping blocks are symmetrically arranged in the front and back direction; when the ceramic-based stone composite plate polishing machine works, the threaded rod is rotated by an operator, the adjusting block is driven to move in the rectangular groove by the rotation of the threaded rod, the adjusting rod is sequentially rotated by the operator, the polishing head is driven to move by the adjusting rod, and the positions of the setting plate and the polishing head are adjusted according to the size of the ceramic-based stone composite plate, so that ceramic-based stone composite plates with different sizes and shapes can be polished, and the processing cost is saved; the ceramic-based stone composite board is placed on the sliding board through a worker, the positive and negative rotating motor is started, the output shaft of the positive and negative rotating motor drives the bidirectional screw to rotate in the positive direction, the clamping block is driven by the bidirectional screw to move towards the middle to clamp the front end and the rear end of the ceramic-based stone composite board tightly, and therefore the ceramic-based stone composite board is clamped and fixed.

The polishing device comprises a pushing cylinder, a threaded rod, a long plate, a regulating block, a setting plate, a hole polishing mechanism and an outer wall polishing mechanism, wherein a through hole is formed in the lower side of the front end face of the rear plate, the inner wall of the through hole is connected with the outer wall of the fixed end of the pushing cylinder, the fixed telescopic end of the pushing cylinder is connected with the middle part of the rear end face of the long plate, a rectangular groove is formed in the front end face of the long plate, the regulating blocks are symmetrically arranged in the rectangular groove in a bilateral mode through a sliding fit mode, threaded holes are formed in the middle parts of the left end and the right end of the rectangular groove, the threaded rod is connected with the threaded holes through a threaded fit mode, a sliding hole is formed in one; the front ends of the adjusting blocks are connected with setting plates which are arranged in a bilateral symmetry mode, an outer wall polishing mechanism is arranged above the left side of each setting plate, and a hole polishing mechanism is arranged above the right side of each setting plate; when the ceramic-based stone composite plate fixing device works, after the ceramic-based stone composite plate is clamped and fixed by the fixing device, the pushing air cylinder is started, the telescopic end of the pushing air cylinder drives the long plate to move back and forth, the left end surface and the right end surface of the ceramic-based stone composite plate are polished, after polishing is finished, the pushing air cylinder drives the long plate to return to the original position, the electric push rod is started, the telescopic end of the electric push rod drives the ceramic-based stone composite plate to move upwards to the specified position through the sliding plate, the hole polishing mechanism is started, the hole polishing mechanism rotates after moving to the polishing position, holes of the ceramic-based stone composite plate are polished, after polishing in the holes is finished, the hole polishing mechanism fixes the ceramic-based stone composite plate from the holes, the output shaft of the forward and reverse rotation motor drives the bidirectional screw rod to rotate reversely, the ceramic-based, the outer wall grinding mechanism starts, and the outer wall grinding mechanism moves to the position of polishing and then moves left and right, and polishes the outer wall of the ceramic-based stone composite board.

The method for forming and processing the ceramic-based stone composite plate by using the ceramic-based stone composite plate forming and processing equipment comprises the following steps:

s1, equipment checking: before the ceramic-based stone composite plate molding and processing equipment is started to polish the ceramic-based stone composite plate, the operation of the equipment is checked;

s2, end face grinding: after workers adjust the position of the setting plate and the outer wall polishing mechanism according to the size of the ceramic-based stone composite plate, the molded ceramic-based stone composite plate is placed between the clamping blocks, clamped by the clamping blocks, and then driven by the pushing cylinder to move the setting plate back and forth, so that the two end faces of the ceramic-based stone composite plate are polished;

s3, polishing in the hole: after the end face polishing is finished, the electric push rod drives the ceramic-based stone composite plate to move upwards for a specified distance through the clamping block, the hole polishing mechanism is started, and the hole polishing mechanism is used for polishing the positions of the holes of the ceramic-based stone composite plate;

s4, polishing the outer wall: after hole polishing is finished, the hole polishing mechanism fixes the position of the ceramic-based stone composite plate from the inside of the hole, and the outer wall polishing mechanism moves to a specified position to polish the outer wall of the ceramic-based stone composite plate through rotation;

s5, completing the following: and after polishing, taking down the ceramic-based stone composite board by a worker.

Preferably, the clamping end upside and the downside of pressing from both sides tight piece be the semicircular structure of indent, press from both sides the tight end middle part of tight piece and be the semicircular structure of evagination, semicircle diameter size of a dimension cooperatees with ceramic base stone composite sheet outer wall to tight steadiness has been guaranteed to press from both sides.

Preferably, the opposite surfaces of the setting plates are provided with placing grooves, polishing air bags are arranged in the placing grooves, the outer walls of the polishing air bags are connected with polishing sheets, and the non-planar end surfaces can be polished through soft materials of the polishing air bags.

Preferably, the hole polishing mechanism comprises a mounting rack, an electric telescopic rod, a square block, an electric motor, a driving gear, a driven gear, a polishing rod, a rubber strip, an expansion air bag, a gas pipe and a connecting shaft, the mounting rack is arranged at the position, corresponding to the outer wall polishing mechanism, of the right end surface of the right side plate, the electric telescopic rod is arranged on the inner wall of the right end surface of the mounting rack, the expansion end of the electric telescopic rod is connected with the middle part of the right end surface of the square block, placing holes are formed in the left end surface of the square block at equal intervals, a T-shaped groove is formed in the square block, the T-shaped groove is communicated with the placing holes, the electric motor is arranged on the inner wall of the right end of the T-shaped groove, the driving gear is fixedly sleeved on the outer, the driving gear all is connected with the pole of polishing with driven gear left end face middle part, the outer wall groove has evenly been seted up along its circumference direction to the pole of polishing left side outer wall, the round hole has been seted up at pole left side middle part of polishing, be provided with the inflation gasbag in the round hole, the outer wall inslot is provided with the rubber strip through the sliding fit mode, the lower extreme of rubber strip all is connected with the inflation gasbag outer wall, the gas transmission hole has been seted up on the inside right side of pole of polishing, the gas transmission hole is linked together with the round hole, the left end of gas transmission. When the ceramic-based stone composite plate polishing device works, the electric telescopic rod is started, the telescopic end of the electric telescopic rod drives the square block to move towards the left side, when the polishing rod moves to the position in the hole of the ceramic-based stone composite plate, the electric motor is started, the output end of the electric motor drives the driving gear to rotate, and the driven gear is meshed with the driving gear to drive the polishing rod to rotate, so that the hole of the ceramic-based stone composite plate is polished; after polishing the completion, the air pump starts, and the air pump passes through the gas-supply pipe and to inflation gasbag carrier gas, makes inflation gasbag inflation get up to drive the rubber strip and remove outside the outer wall groove, support the hole inner wall of ceramic base stone composite sheet tight, thereby fix the ceramic base stone composite sheet at the pole left end of polishing.

Preferably, outer wall grinding machanism including the cylinder of polishing, the link, the disc, the rectangular block, the cylinder ring, adjust pole and the head of polishing, the link is all installed to the left end face upside of left side board, the link is opening right \ 21274, the shape structure, the cylinder of polishing is installed to link left end inner wall, the flexible end of the cylinder of polishing is connected with cylinder piece left end middle part, the right-hand member face of disc is close to the outer wall position and evenly is provided with the rectangular block along its circumference direction, the rectangular block right-hand member all is connected with the left end face of cylinder ring, the cylinder ring outer wall has evenly seted up multiunit regulation hole along its circumference direction, be equipped with the screw thread in the regulation hole, it is connected with the regulation hole through screw-thread fit to. During specific work, the polishing cylinder is started, the telescopic end of the polishing cylinder drives the cylindrical ring to move left and right through the disc, and the outer wall of the ceramic-based stone composite board is polished through the polishing head inside the cylindrical ring.

Preferably, the number of the grinding rods is the same as the number of the holes in the ceramic-based stone composite plate, the positions of the grinding rods correspond to the holes in the ceramic-based stone composite plate one by one, and the shapes and the sizes of the grinding rods are matched with those of the holes.

The invention has the beneficial effects that:

1. according to the ceramic-based stone composite plate polishing device, the positions of the setting plate and the polishing head of the polishing device can be adjusted according to the size of the ceramic-based stone composite plate, so that ceramic-based stone composite plates with different sizes and shapes can be polished, and the processing cost is saved; the ceramic-based stone composite board has the advantages that the end face, the hole and the outer wall of the ceramic-based stone composite board are sequentially polished by the polishing device, the continuity of work is guaranteed, the time of a conversion process is saved, and accordingly better working efficiency is achieved.

2. According to the grinding device, the threaded rod is rotated by an operator, the adjusting block is driven to move in the rectangular groove by the rotation of the threaded rod, the adjusting rod is sequentially rotated by the operator, the grinding head is driven to move by the adjusting rod, and the positions of the setting plate and the grinding head are adjusted according to the size of the ceramic-based stone composite plate, so that ceramic-based stone composite plates with different sizes and shapes can be ground, and the processing cost is saved.

3. The invention designs that the telescopic end of a pushing cylinder drives a long plate to move back and forth, the left end surface and the right end surface of a ceramic-based stone composite plate are polished, after polishing is finished, the pushing cylinder drives the long plate to return to the original position, the telescopic end of an electric push rod drives the ceramic-based stone composite plate to move upwards to a specified position through a sliding plate, a hole polishing mechanism moves to the polishing position and then rotates to polish the hole of the ceramic-based stone composite plate, after polishing in the hole is finished, the hole polishing mechanism fixes the ceramic-based stone composite plate from the hole, an output shaft of a forward and reverse rotating motor drives a bidirectional screw rod to rotate reversely, the clamping block is driven by the bidirectional screw rod through a sliding block to move towards two sides to loosen the ceramic-based stone composite plate, the telescopic end of the electric push rod drives the sliding, the ceramic-based stone composite board has the advantages that the outer wall of the ceramic-based stone composite board is polished, the continuity of work is guaranteed, the time of a conversion process is saved, and therefore better working efficiency is achieved.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a flow chart of the present invention;

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

FIG. 3 is a front cross-sectional view of the present invention;

FIG. 4 is a sectional view taken along line A-A of FIG. 3 in accordance with the present invention;

fig. 5 is a sectional view taken along line B-B of fig. 3 in accordance with the present invention.

FIG. 6 is a cross-sectional view taken along line C-C of FIG. 3 of the present invention.

Fig. 7 is an enlarged view of a portion of the invention at D in fig. 3.

Fig. 8 is a partial enlarged view of the invention at E in fig. 3.

FIG. 9 is a cross-sectional view of the electric motor, drive gear, driven gear and connecting shaft of the present invention in cooperation;

fig. 10 is a schematic perspective view of a processing object of the present invention.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

As shown in fig. 1 to 10, the ceramic matrix stone composite board forming method adopts the following ceramic matrix stone composite board forming equipment, and the ceramic matrix stone composite board forming equipment comprises a support 1, a fixing device 2 and a polishing device 3; the lower end surface of the support 1 is arranged at the upper end of the processing table, the fixing device 2 is arranged in the middle of the support 1, and the polishing device 3 is arranged on the inner wall of the support 1;

the support 1 comprises an H-shaped base 11, a bottom plate 12, a connecting plate 13, a left side plate 14, a right side plate 15 and a rear plate 16, wherein the lower end of the H-shaped base 11 is installed at the upper end of a machining table, the upper end surface of the H-shaped base 11 is connected with the upper end surface of the bottom plate 12, the upper end surface of the bottom plate 12 is connected with the upper end surface of the connecting plate 13, the left side plate 14 is installed at the position, close to the left end, of the upper end surface of the connecting plate 13, the right side plate 15 is installed at the position, close to the right end, of the upper end surface;

the fixing device 2 comprises an electric push rod 21, a sliding plate 22, a bidirectional screw 23, an installation box 24, a forward and reverse rotation motor 25, a sliding block 26 and a clamping block 27, wherein a circular groove is formed in the middle of the upper end face of the connecting plate 13, the circular groove is formed from the upper end face of the connecting plate 13 to the middle of the H-shaped base 11, the telescopic end of the electric push rod 21 is connected with the middle of the lower end face of the sliding plate 22, a sliding groove is formed in the upper end face of the sliding plate 22, a rotating groove is formed in the middle of the front end of the sliding plate 22, the outer wall of the front side of the bidirectional screw 23 is connected with the rotating groove in a matching mode, the installation box 24 is installed at the front end of the sliding plate 22, the forward and reverse rotation motor 25 is installed in the installation box 24, the front end of the bidirectional screw 23 is connected with the output shaft of the forward and reverse, the front end surface of the rear side sliding block 26 is provided with a right threaded hole at a position corresponding to the bidirectional screw 23, the sliding blocks 26 are connected with the outer wall of the bidirectional screw 23 through thread fit, the upper end surfaces of the sliding blocks 26 are provided with clamping blocks 27, and the clamping blocks 27 are symmetrically arranged front and back; the tight end upside of clamp of tight piece 27 and downside be the semicircular structure of indent, the tight end middle part of clamp of tight piece 27 is the semicircular structure of evagination, semicircle diameter size of a dimension cooperatees with ceramic base stone composite sheet outer wall to tight steadiness has been guaranteed to press from both sides.

During specific work, the threaded rod 32 is rotated by an operator, the adjusting block 34 is driven to move in the rectangular groove by the rotation of the threaded rod 32, the adjusting rod 356 is sequentially rotated by the operator, the polishing head 357 is driven to move by the adjusting rod 356, and the positions of the setting plate 35 and the polishing head 357 are adjusted according to the size of the ceramic-based stone composite plate, so that ceramic-based stone composite plates with different sizes and shapes can be polished, and the processing cost is saved; the ceramic matrix stone composite board is placed on the sliding plate 22 through a worker, the forward and reverse rotating motor 25 is started, the output shaft of the forward and reverse rotating motor 25 drives the bidirectional screw 23 to rotate in the forward direction, the clamping block 27 is driven to move towards the middle through the bidirectional screw 23, the front end and the rear end of the ceramic matrix stone composite board are clamped tightly, and therefore the ceramic matrix stone composite board is clamped and fixed.

The polishing device 3 comprises a pushing cylinder 31, a threaded rod 32, a long plate 33, an adjusting block 34, a setting plate 35, a hole polishing mechanism 37 and an outer wall polishing mechanism 36, wherein a through hole is formed in the lower side of the front end face of the rear plate 16, the inner wall of the through hole is connected with the outer wall of the fixed end of the pushing cylinder 31, the fixed telescopic end of the pushing cylinder 31 is connected with the middle part of the rear end face of the long plate 33, a rectangular groove is formed in the front end face of the long plate 33, the adjusting blocks 34 are symmetrically arranged in the rectangular groove in a bilateral mode of sliding fit, threaded holes are formed in the middle parts of the left end and the right end of the rectangular groove, the threaded rod 32 is connected with the threaded holes in a threaded fit mode, a sliding hole is formed in one end, close; the front ends of the adjusting blocks 34 are connected with a setting plate 35, the setting plate 35 is arranged in a bilateral symmetry mode, an outer wall polishing mechanism 36 is arranged above the left side of the setting plate 35, and a hole polishing mechanism 37 is arranged above the right side of the setting plate 35; the opposite face that sets up board 35 all seted up the standing groove, all establish in the standing groove and be provided with the gasbag 351 of polishing, gasbag 351 outer wall connection that polishes has polishing piece 352, can polish non-planar terminal surface through the soft material of gasbag 351 of polishing. When the ceramic-based stone composite board fixing device works specifically, after the ceramic-based stone composite board is clamped and fixed by the fixing device 2, the pushing cylinder 31 is started, the telescopic end of the pushing cylinder 31 drives the long plate 33 to move back and forth, the left end surface and the right end surface of the ceramic-based stone composite board are polished, after polishing is completed, the pushing cylinder 31 drives the long plate 33 to return to the original position, the electric push rod 21 is started, the telescopic end of the electric push rod 21 drives the ceramic-based stone composite board to move upwards to the specified position through the sliding plate 22, the hole polishing mechanism 37 is started, the hole polishing mechanism 37 rotates after moving to the polishing position, holes of the ceramic-based stone composite board are polished, after polishing in the holes is completed, the hole polishing mechanism 37 fixes the ceramic-based stone composite board from the holes, the output shaft of the forward and reverse rotation motor 25 drives the bidirectional screw rod 23 to rotate reversely, the flexible end of electric putter 21 drives sliding plate 22 and gets back to the primary importance, and outer wall grinding machanism 36 starts, and outer wall grinding machanism 36 removes after removing to the position of polishing and removes, polishes the outer wall of ceramic matrix stone composite sheet.

The hole polishing mechanism 37 comprises a mounting rack 371, an electric telescopic rod 372, a square block 373, an electric motor 374, a driving gear 375, a driven gear 376, a polishing rod 377, a rubber strip 378, an expansion air bag 379, an air pipe 3710 and a connecting shaft 3711, the mounting rack 371 is mounted at the position, corresponding to the outer wall polishing mechanism 36, of the right end face of the right side plate 15, the electric telescopic rod 372 is mounted on the inner wall of the right end face of the mounting rack 371, the telescopic end of the electric telescopic rod 372 is connected with the middle part of the right end face of the square block 373, placing holes are equidistantly formed in the left end face of the square block 373, a T-shaped groove is formed in the square block 373 and communicated with the placing holes, the electric motor 374 is mounted on the inner wall of the right end of the T-shaped groove, the driving gear 375 is fixedly sleeved on the outer wall of an, connecting axle 3711 right-hand member is connected with T-arrangement groove right-hand member inner wall, driving gear 375 all is connected with grinding rod 377 with driven gear 376 left end face middle part, grinding rod 377 has left side outer wall and has evenly seted up the outer wall groove along its circumference direction, the round hole has been seted up at grinding rod 377 left side middle part, be provided with inflation gasbag 379 in the round hole, the outer wall inslot is provided with rubber strip 378 through the sliding fit mode, the lower extreme of rubber strip 378 all is connected with inflation gasbag 379 outer wall, the gas transmission hole has been seted up on the inside right side of grinding rod 377, the gas transmission hole is linked together with the round hole, the left end of gas transmission hole. During specific work, the electric telescopic rod 372 is started, the telescopic end of the electric telescopic rod 372 drives the square block 373 to move towards the left side, when the polishing rod 377 moves to the position in the hole of the ceramic-based stone composite plate, the electric motor 374 is started, the output end of the electric motor 374 drives the driving gear 375 to rotate, the driven gear 376 is meshed with the driving gear 375 to drive the polishing rod 377 to rotate, and therefore the hole of the ceramic-based stone composite plate is polished; after polishing, the air pump starts, and the air pump passes through gas-supply pipe 3710 to inflation gasbag 379 delivery gas, makes inflation gasbag 379 expand to drive rubber strip 378 and remove outside the outer wall groove, support the hole inner wall of ceramic base stone composite sheet tightly, thereby fix the ceramic base stone composite sheet at the pole 377 left end of polishing.

The outer wall grinding mechanism 36 comprises a grinding cylinder 361, a connecting frame 362, a disc 363, a rectangular block 364, a cylindrical ring 365, an adjusting rod 366 and a grinding head 367, the connecting frame 362 is installed on the upper side of the left end face of the left side plate 14, the connecting frame 362 is of a right opening-facing 21274, the structure is that the inner wall of the left end of the connecting frame 362 is provided with the grinding cylinder 361, the telescopic end of the grinding cylinder 361 is connected with the middle of the left end of the cylindrical block, the rectangular block 364 is evenly arranged on the position, close to the outer wall, of the right end face of the disc 363 in the circumferential direction, the right end of the rectangular block 364 is connected with the left end face of the cylindrical ring 365, a plurality of groups of adjusting holes are evenly formed in the outer wall of the cylindrical ring 365 in the circumferential. During specific work, the polishing cylinder 361 is started, the telescopic end of the polishing cylinder 361 drives the cylindrical ring 365 to move left and right through the disc 363, and the outer wall of the ceramic-based stone composite plate is polished through the polishing head 367 inside the cylindrical ring 365.

The quantity of the polishing rods 377 is the same as the quantity of the holes in the ceramic-based stone composite plate, the positions of the polishing rods 377 correspond to the holes in the ceramic-based stone composite plate one to one, and the shapes and the sizes of the polishing rods 377 are matched with those of the holes.

s2, end face grinding: after workers adjust the position of the setting plate 35 and the outer wall polishing mechanism 36 according to the size of the ceramic-based stone composite plate, the formed ceramic-based stone composite plate is placed between the clamping blocks 27 and clamped by the clamping blocks 27, and then the setting plate 35 is driven to move back and forth by the clamping blocks 27, so that the two end faces of the ceramic-based stone composite plate are polished;

s3, polishing in the hole: after the end face polishing is finished, the electric push rod 21 drives the ceramic-based stone composite plate to move upwards for a specified distance through the clamping block 27, the hole polishing mechanism 37 is started, and the hole polishing mechanism 37 is used for polishing the positions of the holes of the ceramic-based stone composite plate;

s4, polishing the outer wall: after hole polishing is finished, the hole polishing mechanism 37 fixes the position of the ceramic-based stone composite plate from the inside of the hole, and the outer wall polishing mechanism 36 moves to a specified position to polish the outer wall of the ceramic-based stone composite plate through rotation;

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are given by way of illustration of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the invention as hereinafter claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. A ceramic-based stone composite board forming and processing method adopts the following ceramic-based stone composite board forming and processing equipment, wherein the ceramic-based stone composite board forming and processing equipment comprises a support (1), a fixing device (2) and a polishing device (3); the method is characterized in that: the lower end surface of the support (1) is arranged at the upper end of the processing table, the fixing device (2) is arranged in the middle of the support (1), and the polishing device (3) is arranged on the inner wall of the support (1);

the support (1) comprises an H-shaped base (11), a bottom plate (12), a connecting plate (13), a left side plate (14), a right side plate (15) and a rear plate (16), wherein the lower end of the H-shaped base (11) is installed at the upper end of a machining table, the upper end surface of the H-shaped base (11) is connected with the lower end surface of the upper end of the bottom plate (12), the upper end surface of the bottom plate (12) is connected with the upper end surface of the connecting plate (13), the left side plate (14) is installed at the position, close to the left end, of the upper end surface of the connecting plate (13), the right side plate (15) is installed at the position, close to the right end, of the upper end;

the fixing device (2) comprises an electric push rod (21), a sliding plate (22), a bidirectional screw rod (23), a mounting box (24), a forward and reverse rotation motor (25), a sliding block (26) and a clamping block (27), wherein a circular groove is formed in the middle of the upper end face of the connecting plate (13), the circular groove is formed in the middle of the upper end face of the connecting plate (13) and extends to the middle of the H-shaped base (11), the telescopic end of the electric push rod (21) is connected with the middle of the lower end face of the sliding plate (22), a sliding groove is formed in the upper end face of the sliding plate (22), a rotating groove is formed in the middle of the front end of the sliding plate (22), the outer wall of the front side of the bidirectional screw rod (23) is connected with the rotating groove in a matching mode, the mounting box (24) is mounted at the front end of the sliding plate (22), the forward and reverse rotation motor (25, the sliding blocks (26) are symmetrically arranged in the sliding groove in a front-back mode in a sliding fit mode, a left threaded hole is formed in the position, corresponding to the bidirectional screw rod (23), of the front end face of the front side sliding block (26), a right threaded hole is formed in the position, corresponding to the bidirectional screw rod (23), of the front end face of the rear side sliding block (26), the sliding blocks (26) are connected with the outer wall of the bidirectional screw rod (23) through thread fit, clamping blocks (27) are arranged on the upper end face of each sliding block (26), and the clamping blocks (27) are symmetrically arranged in;

the polishing device (3) comprises a pushing cylinder (31), a threaded rod (32), a long plate (33), an adjusting block (34), a setting plate (35), an outer wall polishing mechanism (36) and a hole polishing mechanism (37), the lower side of the front end face of the rear plate (16) is provided with a through hole, the inner wall of the through hole is connected with the outer wall of the fixed end of the pushing cylinder (31), the fixed telescopic end of the pushing cylinder (31) is connected with the middle part of the rear end face of the long plate (33), the front end face of the long plate (33) is provided with a rectangular groove, adjusting blocks (34) are symmetrically arranged in the rectangular groove in a left-right mode in a sliding fit mode, threaded holes are formed in the middle parts of the left end and the right end of the rectangular groove, the threaded rod (32) is connected with the threaded holes in a threaded fit mode, one end, close to the threaded holes, of each adjusting block (34) is provided with a sliding; the front ends of the adjusting blocks (34) are connected with setting plates (35), the setting plates (35) are arranged in a bilateral symmetry mode, outer wall polishing mechanisms (36) are arranged above the left sides of the setting plates (35), and hole polishing mechanisms (37) are arranged above the right sides of the setting plates (35);

s2, end face grinding: after workers adjust the position of the setting plate (35) and the outer wall polishing mechanism (36) according to the size of the ceramic-based stone composite plate, the formed ceramic-based stone composite plate is placed between the clamping blocks (27), clamped by the clamping blocks (27), and driven by the pushing cylinder (31) to move the setting plate (35) back and forth, so that two end faces of the ceramic-based stone composite plate are polished;

s3, polishing in the hole: after the end face is polished, the electric push rod (21) drives the ceramic-based stone composite plate to move upwards for a specified distance through the clamping block (27), the hole polishing mechanism (37) is started, and the hole polishing mechanism (37) is used for polishing the positions of the holes of the ceramic-based stone composite plate;

s4, polishing the outer wall: after hole polishing is finished, the hole polishing mechanism (37) fixes the position of the ceramic-based stone composite plate from the inside of the hole, and the outer wall polishing mechanism (36) moves to a specified position to polish the outer wall of the ceramic-based stone composite plate through rotation;

2. The method for forming ceramic matrix stone composite plates according to claim 1, wherein: the clamping end upside and the downside of clamping block (27) be the semicircular structure of indent, the clamping end middle part of clamping block (27) is the semicircular structure of evagination, semicircle diameter size of a dimension matches with ceramic base stone composite sheet outer wall.

3. The method for forming ceramic matrix stone composite plates according to claim 1, wherein: the opposite surfaces of the setting plates (35) are provided with placing grooves, polishing air bags (351) are arranged in the placing grooves, and the outer walls of the polishing air bags (351) are connected with polishing plates (352).

4. The method for forming ceramic matrix stone composite plates according to claim 1, wherein: the outer wall grinding mechanism (36) comprises a grinding cylinder (361), a connecting frame (362), a disc (363), a rectangular block (364), a cylindrical ring (365), an adjusting rod (366) and a grinding head (367), wherein the connecting frame (362) is arranged on the upper side of the left end face of the left side plate (14), the connecting frame (362) is of a right-opening v 21274, the grinding cylinder (361) is arranged on the inner wall of the left end of the connecting frame (362), the telescopic end of the grinding cylinder (361) is connected with the middle part of the left end of the cylindrical block, rectangular blocks (364) are uniformly arranged on the right end face of the disc (363) close to the outer wall along the circumferential direction, the right end of each rectangular block (364) is connected with the left end face of the cylindrical ring (365), a plurality of groups of adjusting holes are uniformly formed in the outer wall of the cylindrical ring (365) along the circumferential direction, threads are arranged in the adjusting holes, the tail ends of the threaded rods (32) are provided with polishing heads (367).

5. The method for forming ceramic matrix stone composite plates according to claim 1, wherein: the hole polishing mechanism (37) comprises a mounting rack (371), an electric telescopic rod (372), a square block (373), an electric motor (374), a driving gear (375), a driven gear (376), a polishing rod (377), a rubber strip (378), an expansion air bag (379), an air conveying pipe (3710) and a connecting shaft (3711), wherein the mounting rack (371) is installed at the position, corresponding to the outer wall polishing mechanism (36), of the right end surface of the right side plate (15), the electric telescopic rod (372) is installed on the inner wall of the right end surface of the mounting rack (371), the expansion end of the electric telescopic rod (372) is connected with the middle part of the right end surface of the square block (373), placing holes are formed in the left end surface of the square block (373) at equal intervals, a T-shaped groove is formed in the square block (373), the T-shaped groove is communicated with the placing holes, the electric motor (374) is, the outer wall of the driving gear (375) is connected with a plurality of driven gears (376) through size meshing, the movable sleeve of the driven gears (376) is arranged on the outer wall of the connecting shaft (3711), the right end of the connecting shaft (3711) is connected with the inner wall of the right end of the T-shaped groove, the middle parts of the left end faces of the driving gear (375) and the driven gears (376) are connected with a polishing rod (377), the outer wall groove is uniformly formed in the left outer wall of the polishing rod (377) along the circumferential direction of the outer wall groove, a round hole is formed in the middle of the left side of the polishing rod (377), an expansion air bag (379) is arranged in the round hole, a rubber strip (378) is arranged in the outer wall groove in a sliding fit mode, the lower end of the rubber strip (378) is connected with the outer wall of the expansion air bag (379), an air conveying.

6. The method for forming ceramic matrix stone composite plates according to claim 5, wherein: the number of the grinding rods (377) is the same as the number of the holes in the ceramic-based stone composite plate, the positions of the grinding rods (377) correspond to the holes in the ceramic-based stone composite plate one by one, and the shapes and the sizes of the grinding rods (377) are matched with the shapes and the sizes of the holes.