CN113119640A - Ceramic tile engraver for construction - Google Patents

Abstract

The invention relates to the technical field of buildings, in particular to a tile carving machine for building construction, which comprises a base platform, a feeding component, an operating platform and a carving component, wherein the feeding component of the tile carving machine can be rotationally adjusted by using a third motor for driving, so that the flexibility of the operation of the carving machine is improved, meanwhile, the area range of materials which can be conveyed by the feeding component of the carving machine is greatly improved, and the transferring speed is improved, so that the use efficiency of the carving machine is improved.

Description

Ceramic tile engraver for construction

Technical Field

The invention relates to the technical field of buildings, in particular to a tile carving machine for building construction.

Background

The ceramic tile is made of an acid-base-resistant porcelain or stone material formed by grinding, mixing, pressing, glazing and sintering refractory metal oxides and semimetal oxides, is increasingly used in the field of buildings, and is often processed by a ceramic tile engraving machine for attractiveness before building construction is carried out by using the ceramic tile, and pattern patterns are engraved on the ceramic tile by using the engraving machine.

However, there is very big defect in current ceramic tile engraver in the use, the speed of current ceramic tile engraver material loading is slow, the efficiency of using has been reduced, current ceramic tile engraver is less to ceramic tile moving scope, the flexibility of operation has been reduced, current ceramic tile engraver is not steady enough of removing in carving, thereby the glyptic precision has been reduced, current ceramic tile engraver is in the use, the piece of production can drift down on the ground, cause the pollution, the feature of environmental protection of using has been reduced.

Disclosure of Invention

Aiming at the problems in the prior art, the invention provides a tile carving machine for building construction.

The technical scheme adopted by the invention for solving the technical problems is as follows: a tile carving machine for building construction comprises a base platform, a feeding assembly, an operating platform and a carving assembly, wherein the feeding assembly is installed at one end of the top of the base platform, the operating platform is fixedly welded in the middle of the top of the base platform, a front-and-back moving assembly is horizontally fixed at one end, far away from the feeding assembly, of the top of the base platform, the front-and-back moving assembly is vertically installed with an up-and-down moving assembly, a left-and-right moving assembly is in sliding fit with the up-and-down moving assembly, and the carving assembly;

the feeding assembly comprises a supporting plate, a first sliding bottom plate and a first hydraulic cylinder, the supporting plate is vertically arranged, the supporting plate is rotatably matched with the top of a base station, the first sliding bottom plate is welded on one side of the supporting plate horizontally, the first sliding bottom plate is positioned at one end, far away from the base station, of the supporting plate, a first sliding rail is welded on one side, far away from the supporting plate, of the first sliding bottom plate horizontally, the cross section of the first sliding rail is of an I-shaped structure, a first moving plate is slidably matched on the first sliding rail, the first hydraulic cylinder is welded on one side, far away from the first sliding rail, of the first moving plate, the first hydraulic cylinder is vertically arranged, a first hydraulic rod is arranged at the bottom end of the first hydraulic cylinder, a connecting plate is welded at the bottom end of the first hydraulic rod, the first hydraulic cylinder is driven to move the first hydraulic rod, and the first hydraulic rod drives, the height of the feeding assembly is adjusted, the feeding assembly is moved to the position where materials such as tiles are leveled by adjusting the height of the feeding assembly, the pneumatic clamp holder is installed on one side of the connecting plate, the two clamping blocks are installed on one side of the pneumatic clamp holder, the clamping heads are arranged at one ends of the two clamping blocks, the two clamping blocks are driven by the pneumatic clamp holder to drive the two clamping heads to clamp the materials such as the tiles, the materials such as the tiles are lifted by driving of the first hydraulic cylinder, the materials such as the tiles are transported by adjusting the direction of the first sliding bottom plate and adjusting the position of the first moving plate, the feeding assembly of the tile engraving machine can be rotationally adjusted by driving of the third motor, the area range of the materials which can be transported by the feeding assembly of the engraving machine is increased, the transporting speed is increased, the position of the feeding assembly of the engraving machine is adjusted by driving of the first motor, the feeding component of the engraving machine can fetch and deliver ceramic tile materials at any position in a coverage area, so that the use flexibility of the engraving machine is further improved, the use efficiency of the engraving machine is further improved, and one end of the feeding component can move out from the upper part of an operation table by steering adjustment of the feeding component, so that sufficient space is reserved for the engraving component;

the top of the operating platform is provided with a groove, a plurality of base plates are welded in the groove, and the groove is formed in the top of the operating platform, so that scraps generated in the carving process are collected, and refuge scraps fall everywhere on the ground, and the pollution to the surrounding environment is reduced;

the back-and-forth moving assembly comprises a second sliding bottom plate, a second hydraulic cylinder and a second hydraulic rod, the second sliding bottom plate is of an L-shaped structure, the second sliding bottom plate is horizontally welded to the top of the base station, one end of the second sliding bottom plate is horizontally provided with the second hydraulic cylinder, one end, close to the second sliding bottom plate, of the second hydraulic cylinder is provided with the second hydraulic rod, one end, far away from the second hydraulic cylinder, of the second hydraulic rod is connected with a second moving plate, the second hydraulic rod is driven by the second hydraulic cylinder to move, the second hydraulic rod drives the second moving plate to move the second moving plate, the second moving plate is made to move back and forth, and the back-and-forth position of the carving assembly is adjusted by moving the second moving;

the up-down moving assembly comprises a third sliding bottom plate, three sliding rails and a fourth motor, the third sliding bottom plate is vertically welded at the top of a second moving plate, two third sliding rails are welded at one side of the third sliding bottom plate, the cross sections of the two third sliding rails are in an I-shaped structure, a left-right moving assembly is arranged on the two third sliding rails in a sliding fit manner and comprises a fourth sliding bottom plate, four sliding rails and a third moving plate, the third moving plate is welded at one side of the fourth sliding bottom plate, the fourth sliding bottom plate is in a sliding fit manner on the two third sliding rails through the third moving plate, two fourth sliding rails are horizontally welded at one side of the fourth sliding rails far away from the third moving plate, an engraving assembly is arranged on the two fourth sliding rails in a sliding fit manner, the second screw rod is driven by the fourth motor to rotate, and a second nut is moved on the second screw rod by rotating the second screw rod, the second nut drives the third moving plate to move the third moving plate up and down, and the up-and-down position of the engraving assembly is adjusted by moving the third moving plate up and down;

the carving component comprises a fourth moving plate, a sixth motor and a drill bit, the fourth moving plate is in sliding fit with a fourth sliding rail, the sixth motor is vertically installed on one side of the fourth moving plate, and the drill bit is installed at the bottom end of the sixth motor.

Preferably, the base station is hollow structure, one side of base station is equipped with the opening, the base station opening part articulates there is the cabinet door, the handle that is "U" type structure is installed to one side of cabinet door, the top welding of base station has a plurality of to support the chassis, a plurality of supports the bottom of chassis and all bonds there is the plastic pad, through setting up the base station into hollow structure, make the base station internal energy accomodate various instruments, maintenance and the renewal part for this engraver facilitate, through setting up the cabinet door, bring the facility for inner space's use, and then further improve the convenience of using, through bonding the plastic pad bottom supporting the chassis, increase the frictional force between support chassis and the ground, thereby stability when improving this machine operation.

Preferably, the inside one end that is close to the pay-off subassembly of base station is vertical installs the third motor, and the cross-section of backup pad is "L" type structure, and the top of third motor is connected through the bottom of pivot with the backup pad, drives through the third motor, makes the backup pad rotate on the base station, adjusts first sliding bottom plate's direction through rotating the backup pad.

Preferably, a first motor is installed at one end of the first sliding bottom plate, a first lead screw is arranged on one side of the first sliding bottom plate in a rotating fit mode, one end, close to the first sliding bottom plate, of the first motor is connected with the first lead screw through a rotating shaft, the first lead screw is driven through the first motor to rotate, the first nut is driven to move on the first lead screw through rotating the first lead screw, the first nut drives the first moving plate, the position of the first moving plate is adjusted, the direction of the first sliding bottom plate is adjusted, the position of the first moving plate is adjusted, and the feeding assembly is moved to the positions above materials such as tiles.

Preferably, first move the board and keep away from one side welding of first pneumatic cylinder and have first slider and first nut, first slider is kept away from first one side of moving the board and has been seted up first spout, the big or small looks adaptation of first spout cross-section size and first slide rail cross-section, first slider sliding fit is on first slide rail, first nut screw-thread fit is on first lead screw, through using first slider sliding fit on first slide rail, make more steady accuracy that the pay-off subassembly position removed, improve the precision of this engraver pay-off operation, and then improve the glyptic precision of this ceramic tile engraver, complicated alignment accommodation process has been avoided, the glyptic effect has been improved greatly, good economic value and market prospect have.

Preferably, the second motors are arranged on one sides of the two clamping blocks, the two second motors are connected with rotating handles through rotating shafts, one ends of the two rotating handles, which are far away from the second motors, are connected with the two chucks through the rotating shafts, the second motors are arranged on the clamping blocks, the chucks are driven by the rotating handles to rotate, the chucks are enabled to rotate through rotating the chucks, the ceramic tile is turned over through turning the ceramic tile, the inclination angle of the ceramic tile can be flexibly adjusted in the conveying process through turning the ceramic tile, convenience is provided for safe transfer of the ceramic tile, the use safety of the carving machine is improved, meanwhile, the carving operation of the back side of the ceramic tile is facilitated through turning the ceramic tile, the carving flexibility is further improved, the cross sections of the two chucks are both in a V-shaped structure, the cross sections of the chucks are arranged in a V-shaped structure, so that the ceramic tile is clamped between the two chucks more tightly, the stability of the feeding component to the tile carrying is improved.

Preferably, the top horizontal welding machine of second sliding bottom plate has two second slide rails, the cross-section of two second slide rails all is "worker" style of calligraphy structure, the bottom welding that the second moved the board has two second sliders, the second spout has all been seted up to the bottom of two second sliders, the size of second spout cross-section and the big or small looks adaptation of second slide rail cross-section, two second slider sliding fit are on two second slide rails, the second moves the board through two second slider sliding fit on two second slide rails, through using second slider sliding fit on the second slide rail, make the more smooth and easy of sculpture subassembly back-and-forth movement of this engraver.

Preferably, a fourth motor is installed at the top of the third sliding bottom plate, a second lead screw is rotatably matched with one side, close to a third sliding rail, of the third sliding bottom plate, the bottom of the fourth motor is connected with the top of the second lead screw through a rotating shaft, two third sliding blocks and a second nut are welded on one side, far away from the fourth sliding bottom plate, of the third moving plate, a third sliding groove is formed in one side of each of the two third sliding blocks, the cross sections of the two third sliding grooves are matched with the cross sections of the two third sliding rails in size, the two third sliding blocks are respectively and slidably matched on the two third sliding rails, the second nut is in threaded fit on the second lead screw, and the engraving assembly of the engraving machine is adjusted up and down more stably by using the third sliding blocks in sliding fit on the third sliding rails.

Preferably, a fifth motor is installed to the one end of fourth sliding bottom plate, one side normal running fit that fourth sliding bottom plate is close to the fourth slide rail has the third lead screw, the one end of fifth motor is connected with the third lead screw through the pivot, one side welding of fourth shifting plate has two fourth sliders and a third nut, the fourth spout has all been seted up to one side of two fourth sliders, the size of fourth spout cross-section and the big or small looks adaptation of fourth slide rail cross-section, fourth slider normal running fit is on the fourth slide rail, third nut screw-thread fit is on the third lead screw, through fourth slider normal running fit on the fourth slide rail, make the sculpture subassembly of this engraver remove more level and smooth and easy.

Preferably, the use method of the tile carving machine specifically comprises the following steps:

the method comprises the following steps: the third motor drives the support plate to rotate on the base platform, the direction of the first sliding bottom plate is adjusted by rotating the support plate, the first motor drives the first lead screw to rotate, the first lead screw is rotated to move the first nut on the first lead screw, the first nut drives the first moving plate to adjust the position of the first moving plate, the feeding assembly is moved above materials such as tiles and the like by adjusting the direction of the first sliding bottom plate and the position of the first moving plate, the first hydraulic rod is driven by the first hydraulic cylinder to move, the first hydraulic rod drives the connecting plate to adjust the height of the feeding assembly, the feeding assembly is moved to the position where the materials such as tiles and the like are level by adjusting the height of the feeding assembly, the pneumatic clamp is driven to enable the two clamping blocks to drive the two clamping heads to clamp the materials such as tiles and the like, and the two clamping blocks are driven by the first hydraulic cylinder, materials such as ceramic tiles and the like are lifted, and the materials such as the ceramic tiles and the like are transferred by adjusting the direction of the first sliding bottom plate and the position of the first moving plate;

step two: the tile material is moved to the upper part of the operating platform through the feeding assembly, and the two clamping blocks are loosened through the driving of the pneumatic clamp holder, so that the tile material is flatly placed on the base plate at the top of the operating platform;

step three: the second hydraulic cylinder drives the second hydraulic rod to move, the second hydraulic rod drives the second moving plate to move the second moving plate back and forth, and the second moving plate is moved back and forth, the front and back positions of the engraving assembly are adjusted, the fourth motor drives the second screw rod to rotate, the second nut moves on the second screw rod by rotating the second screw rod, the second nut drives the third moving plate to move the third moving plate up and down, and by moving the third moving plate up and down, the upper and lower positions of the engraving assembly are adjusted, the third screw rod is driven to rotate by a fifth motor, the third screw rod is rotated to enable the third nut to move on the third screw rod, the third nut drives the fourth moving plate to enable the fourth moving plate to move left and right, and the fourth moving plate is moved left and right, adjust about the position of carving the subassembly, drive the drill bit through the sixth motor, carve the surface of ceramic tile.

The invention has the beneficial effects that:

(1) the tile carving machine for building construction can improve the flexibility of the operation of the carving machine by driving the feeding component of the carving machine through the third motor, greatly improve the range of the area where the feeding component of the carving machine can convey materials, and improve the transferring speed, thereby improving the use efficiency of the carving machine, can improve the flexibility of the use of the carving machine and the use efficiency of the carving machine by driving the feeding component of the carving machine through the first motor and adjusting the position of the feeding component of the carving machine, so that the feeding component of the carving machine can take and convey the tile materials at any position in the covered area, and can move out one end of the feeding component from the upper part of the operating platform by steering and adjusting the feeding component, thereby freeing sufficient space for the carving component, the engraver abundant performance of being convenient for carves the function, improve the degree of freedom of engraver sculpture operation to improve the sculpture effect of this engraver, through using first slider sliding fit on first slide rail, make more steady accuracy that the pay-off subassembly position removed, improve the accurate nature of this engraver pay-off operation, and then improve the glyptic precision of this ceramic tile engraver, avoided complicated alignment accommodation process, improved glyptic effect greatly, good economic value and market prospect have.

(2) The invention relates to a tile carving machine for building construction, which is characterized in that the cross section of each chuck is arranged to be in a V-shaped structure, so that a tile is clamped between the two chucks more tightly, the stability of a feeding assembly for carrying the tile is improved, and the reliability of the carving machine is improved, the chuck is driven to rotate by a second motor arranged on each chuck block through a rotating handle, the tile is turned by rotating the chuck, the tile can be flexibly adjusted in the conveying process through turning the tile, the safe transfer of the tile is facilitated, the use safety of the carving machine is improved, meanwhile, the back side of the tile is conveniently carved by turning the tile, the flexibility of carving is further improved, and the debris generated in the carving process is collected by arranging the groove at the top of an operation table, the refuge debris can float everywhere on the ground, so that the pollution to the surrounding environment is reduced, and the environmental protection performance in use is improved.

(3) According to the tile carving machine for building construction, the carving flexibility of the carving machine is improved by adjusting the positions of the carving components back and forth, up and down and left and right, so that the richness of the carving patterns of the carving machine is improved, the carving components of the carving machine move back and forth more smoothly by using the second sliding block in a sliding fit mode on the second sliding rail, the carving components of the carving machine are adjusted up and down more stably by using the third sliding block in a sliding fit mode on the third sliding rail, the carving components of the carving machine move left and right more smoothly by using the fourth sliding block in a sliding fit mode on the fourth sliding rail, the adjustment of the carving components is more smooth and stable, the shaking of the machine in the carving process is reduced, and therefore the carving success rate is improved, and the quality of carved products is improved.

Drawings

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

Fig. 1 is a schematic view of the overall structure of the present invention.

Fig. 2 is a schematic view of the base structure of the present invention.

Fig. 3 is a schematic structural view of a feeding assembly of the present invention.

FIG. 4 is a schematic diagram of a first moving plate structure according to the present invention.

FIG. 5 is a schematic view of the structure of the operation table of the present invention.

FIG. 6 is a schematic view of the forward-backward movement assembly of the present invention.

FIG. 7 is a schematic view of the up-down moving assembly of the present invention.

FIG. 8 is a schematic view of the left-right moving assembly of the present invention.

FIG. 9 is a schematic diagram of a third moving plate structure according to the present invention.

Fig. 10 is a schematic view of the engraving member of the present invention.

In the figure: 1. a base station; 101. a support chassis; 102. a cabinet door; 103. a handle; 2. a feeding assembly; 201. a support plate; 202. a first sliding bottom plate; 203. a first slide rail; 204. a first moving plate; 205. a first motor; 206. a first lead screw; 207. a first slider; 208. a first nut; 209. a first hydraulic cylinder; 210. a first hydraulic lever; 211. a connecting plate; 212. a pneumatic gripper; 213. a clamping block; 214. a chuck; 215. a second motor; 216. a third motor; 3. an operation table; 301. a groove; 302. a base plate; 4. a forward and backward movement assembly; 401. a second sliding bottom plate; 402. a second hydraulic cylinder; 403. a second hydraulic rod; 404. a second moving plate; 405. a second slide rail; 406. a second slider; 5. an up-and-down moving assembly; 501. a third sliding bottom plate; 502. a third slide rail; 503. a second lead screw; 504. a fourth motor; 6. a left-right moving component; 601. a fourth sliding bottom plate; 602. a fourth slide rail; 603. a third screw rod; 604. a fifth motor; 605. a third moving plate; 606. a third slider; 607. a second nut; 7. an engraving assembly; 701. a fourth moving plate; 702. a sixth motor; 703. a drill bit; 704. a fourth slider; 705. and a third nut.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

As shown in fig. 1-10, the tile carving machine for building construction of the present invention comprises a base platform 1, a feeding component 2, an operation platform 3 and a carving component 7, wherein the feeding component 2 is installed at one end of the top of the base platform 1, the operation platform 3 is fixedly welded in the middle of the top of the base platform 1, a front-back moving component 4 is horizontally fixed at one end of the top of the base platform 1 far away from the feeding component 2, an up-down moving component 5 is vertically installed on the front-back moving component 4, a left-right moving component 6 is slidably fitted on the up-down moving component 5, and the carving component 7 is slidably fitted on the left-;

wherein, the feeding component 2 comprises a supporting plate 201, a first sliding bottom plate 202 and a first hydraulic cylinder 209, the supporting plate 201 is vertically arranged, the supporting plate 201 is rotatably matched on the top of the base station 1, the first sliding bottom plate 202 is welded on one side of the supporting plate 201, the first sliding bottom plate 202 is positioned at one end of the supporting plate 201 far away from the base station 1, a first sliding rail 203 is horizontally welded on one side of the first sliding bottom plate 202 far away from the supporting plate 201, the cross section of the first sliding rail 203 is in an I-shaped structure, a first moving plate 204 is slidably matched on the first sliding rail 203, a first hydraulic cylinder 209 is welded on one side of the first moving plate 204 far away from the first sliding rail 203, the first hydraulic cylinder 209 is vertically arranged, a first hydraulic rod 210 is arranged at the bottom end of the first hydraulic cylinder 209, a connecting plate 211 is welded at the bottom end of the first hydraulic rod 210, the first hydraulic rod 210 is driven by the first hydraulic cylinder 209 to move, the height of the feeding component 2 is adjusted, the feeding component 2 is moved to the position where materials such as ceramic tiles and the like are leveled by adjusting the height of the feeding component 2, a pneumatic clamp 212 is installed at one side of a connecting plate 211, two clamping blocks 213 are installed at one side of the pneumatic clamp 212, one ends of the two clamping blocks 213 are provided with chucks 214, the pneumatic clamp 212 drives the two clamping blocks 213 to drive the two chucks 214 to clamp the materials such as ceramic tiles and the like, the materials such as ceramic tiles and the like are lifted up by driving through a first hydraulic cylinder 209, the materials such as ceramic tiles and the like are transported by adjusting the direction of a first sliding bottom plate 202 and adjusting the position of a first moving plate 204, the feeding component 2 of the ceramic tile engraving machine can be rotationally adjusted by driving through a third motor 216, the operation flexibility of the engraving machine is improved, and meanwhile, the area range of the materials which can be conveyed by the feeding component 2 of the engraving machine, the transfer speed is increased, so that the use efficiency of the carving machine is improved, the first motor 205 is used for driving, the position of the feeding component 2 of the carving machine is adjusted, the feeding component 2 of the carving machine can fetch and deliver ceramic tile materials at any position in a coverage area, the use flexibility of the carving machine is further improved, the use efficiency of the carving machine is further improved, one end of the feeding component 2 can be moved out from the upper side of the operating table 3 by turning to adjust the feeding component 2, so that sufficient space is reserved for the carving component 7, the carving function of the carving machine is fully played, the degree of freedom of carving operation of the carving machine is improved, and the carving effect of the carving machine is improved;

the top of the operating platform 3 is provided with a groove 301, a plurality of backing plates 302 are welded in the groove 301, the groove 301 is formed in the top of the operating platform 3, chips generated in the carving process are collected, the chips are refuged to fall everywhere on the ground, pollution to the surrounding environment is reduced, and accordingly the environment friendliness in use is improved;

the front-back moving component 4 comprises a second sliding bottom plate 401, a second hydraulic cylinder 402 and a second hydraulic cylinder 403, the second sliding bottom plate 401 is of an L-shaped structure, the second sliding bottom plate 401 is horizontally welded to the top of the base station 1, one end of the second sliding bottom plate 401 is horizontally provided with the second hydraulic cylinder 402, one end, close to the second sliding bottom plate 401, of the second hydraulic cylinder 402 is provided with the second hydraulic cylinder 403, one end, far away from the second hydraulic cylinder 402, of the second hydraulic cylinder 403 is connected with a second moving plate 404, the second hydraulic cylinder 402 drives the second hydraulic cylinder 403 to move, the second hydraulic cylinder 403 drives the second moving plate 404 to move the second moving plate 404, the second moving plate 404 moves back and forth, and the front-back position of the carving component 7 is adjusted by moving the second moving plate 404 back;

the up-down moving assembly 5 comprises a third sliding bottom plate 501, a third sliding rail 502 and a fourth motor 504, the third sliding bottom plate 501 is vertically welded on the top of the second moving plate 404, one side of the third sliding bottom plate 501 is welded with two third sliding rails 502, the cross sections of the two third sliding rails 502 are in an I-shaped structure, the two third sliding rails 502 are slidably matched with the left-right moving assembly 6, the left-right moving assembly 6 comprises a fourth sliding bottom plate 601, a fourth sliding rail 602 and a third moving plate 605, the third moving plate 605 is welded on one side of the fourth sliding bottom plate 601, the fourth sliding bottom plate 601 is slidably matched on the two third sliding rails 502 through the third moving plate 605, one side of the fourth sliding rail 602, which is far away from the third moving plate 605, is horizontally welded with two fourth sliding rails 602, the two fourth sliding rails 602 are slidably matched with the engraving assembly 7, the second screw 503 is driven by the fourth motor 504 to rotate the second screw 503, the second nut 607 moves on the second lead screw 503, the second nut 607 drives the third moving plate 605 to move the third moving plate 605 up and down, and the up and down position of the engraving assembly 7 is adjusted by moving the third moving plate 605 up and down;

the engraving assembly 7 comprises a fourth moving plate 701, a sixth motor 702 and a drill 703, the fourth moving plate 701 is slidably fitted on the fourth sliding rail 602, the sixth motor 702 is vertically installed on one side of the fourth moving plate 701, and the drill 703 is installed at the bottom end of the sixth motor 702.

Base station 1 is hollow structure, and one side of base station 1 is equipped with the opening, and 1 opening part of base station articulates there is cabinet door 102, and the handle 103 that is "U" type structure is installed to one side of cabinet door 102, and the top welding of base station 1 has a plurality of to support chassis 101, and the bottom that a plurality of supported chassis 101 all bonds has the plastic pad.

The inside one end that is close to pay-off subassembly 2 of base station 1 is vertical installs third motor 216, and the cross-section of backup pad 201 is "L" type structure, and the top of third motor 216 is connected through the bottom of pivot with backup pad 201, drives through third motor 216, makes backup pad 201 rotate on base station 1, adjusts the direction of first sliding bottom plate 202 through rotating backup pad 201.

A first motor 205 is installed at one end of the first sliding bottom plate 202, a first lead screw 206 is rotatably matched at one side of the first sliding bottom plate 202, one end of the first motor 205, which is close to the first sliding bottom plate 202, is connected with the first lead screw 206 through a rotating shaft, the first lead screw 206 is rotated through the driving of the first motor 205, a first nut 208 is moved on the first lead screw 206 through rotating the first lead screw 206, the first nut 208 drives a first moving plate 204, the position of the first moving plate 204 is adjusted, and the feeding assembly 2 is moved above materials such as tiles and the like by adjusting the direction of the first sliding bottom plate 202 and the position of the first moving plate 204.

First move the board 204 and keep away from the welding of one side of first pneumatic cylinder 209 has first slider 207 and first nut 208, first slider 207 keeps away from first one side of moving board 204 and has seted up first spout, the big or small looks adaptation in first spout cross-section size and first slide rail 203 cross-section, first slider 207 sliding fit is on first slide rail 203, first nut 208 screw-thread fit is on first lead screw 206, through using first slider 207 sliding fit on first slide rail 203, make the more steady accuracy that the 2 positions of pay-off subassembly removed, improve the precision of this engraver pay-off operation, and then improve the glyptic precision of this tile engraver, the complicated alignment accommodation process has been avoided, the glyptic effect has been improved greatly, and has good economic value and market prospect.

The second motors 215 are respectively arranged on one side of the two clamping blocks 213, the two second motors 215 are respectively connected with a rotating handle through a rotating shaft, one ends of the two rotating handles, far away from the second motors 215, are connected with the two clamping heads 214 through the rotating shaft, the second motors 215 are arranged on the clamping blocks 213, the second motors 215 drive the clamping heads 214 through the rotating handles, the clamping heads 214 can rotate, the ceramic tile can be turned over through rotating the clamping heads 214, the inclination angle of the ceramic tile can be flexibly adjusted in the conveying process through turning the ceramic tile, convenience is provided for safe transfer of the ceramic tile, the use safety of the carving machine is improved, meanwhile, the carving operation on the back of the ceramic tile is facilitated through turning the ceramic tile, the carving flexibility is further improved, the cross sections of the two clamping heads 214 are both in a V-shaped structure, the cross section of the clamping heads 214 is arranged in a V-shaped structure, and the ceramic tile is clamped between the two clamping heads 214 more tightly, the stability of the feeding component 2 for carrying the ceramic tiles is improved, and therefore the use reliability of the carving machine is improved.

The top horizontal welding machine of second sliding bottom plate 401 has two second slide rails 405, the cross-section of two second slide rails 405 all is "worker" style of calligraphy structure, the bottom welding that the second moved board 404 has two second sliders 406, the second spout has all been seted up to the bottom of two second sliders 406, the size of second spout cross-section and the size looks adaptation of second slide rail 405 cross-section, two second sliders 406 sliding fit are on two second slide rails 405, the second moves board 404 through two second sliders 406 sliding fit on two second slide rails 405, through using second slider 406 sliding fit on second slide rail 405, make the more smooth and easy of sculpture subassembly 7 back-and-forth movement of this engraver.

The top of the third sliding bottom plate 501 is provided with a fourth motor 504, one side of the third sliding bottom plate 501 close to the third sliding rail 502 is rotatably matched with a second screw rod 503, the bottom of the fourth motor 504 is connected with the top of the second screw rod 503 through a rotating shaft, one side of the third sliding bottom plate 605 far away from the fourth sliding bottom plate 601 is welded with two third sliding blocks 606 and a second nut 607, one side of each of the two third sliding blocks 606 is provided with a third sliding groove, the cross sections of the two third sliding grooves are matched with the cross sections of the two third sliding rails 502 in size, the two third sliding blocks 606 are respectively in sliding fit on the two third sliding rails 502, the second nut 607 is in threaded fit on the second screw rod, and the carving assembly 7 of the carving machine is more stable in up-down adjustment by using the third sliding blocks 606 to be in sliding fit on the third sliding rails 502.

A fifth motor 604 is installed at one end of a fourth sliding bottom plate 601, a third screw 603 is rotatably matched at one side of the fourth sliding bottom plate 601 close to a fourth sliding rail 602, one end of the fifth motor 604 is connected with the third screw 603 through a rotating shaft, two fourth sliding blocks 704 and a third nut 705 are welded at one side of the fourth sliding plate 701, a fourth sliding groove is formed in one side of each of the two fourth sliding blocks 704, the cross section of the fourth sliding groove is matched with the cross section of the fourth sliding rail 602 in size, the fourth sliding block 704 is slidably matched on the fourth sliding rail 602, the third nut 705 is in threaded fit on the third screw 603, and the fourth sliding block 704 is slidably matched on the fourth sliding rail 602, so that the left and right movement of the engraving assembly 7 of the engraving machine is smoother.

The use method of the tile carving machine specifically comprises the following steps:

the method comprises the following steps: the support plate 201 is driven by a third motor 216 to rotate on the base platform 1, the direction of the first sliding bottom plate 202 is adjusted by rotating the support plate 201, the first screw rod 206 is driven by a first motor 205 to rotate, the first nut 208 is driven to move on the first screw rod 206 by rotating the first screw rod 206, the first nut 208 drives the first moving plate 204 to adjust the position of the first moving plate 204, the feeding component 2 is moved above materials such as ceramic tiles and the like by adjusting the direction of the first sliding bottom plate 202 and the position of the first moving plate 204, the first hydraulic rod 210 is driven by a first hydraulic cylinder 209 to move, the first hydraulic rod 210 drives the connecting plate 211 to adjust the height of the feeding component 2, the feeding component 2 is moved to the position where the materials such as the ceramic tiles and the like are level by adjusting the height of the feeding component 2, and the two clamp blocks 213 drive two clamp heads 214 to clamp the materials such as the ceramic tiles and the like by driving the pneumatic clamp holder 212, materials such as tiles are lifted up by driving of the first hydraulic cylinder 209, and the materials such as the tiles are transferred by adjusting the direction of the first sliding bottom plate 202 and the position of the first moving plate 204;

step two: the tile material is moved to the upper part of the operating platform 3 through the feeding component 2, and is driven by the pneumatic clamper 212 to loosen the two clamping blocks 213, so that the tile material is flatly placed on the backing plate 302 at the top of the operating platform 3;

step three: the second hydraulic cylinder 402 drives the second hydraulic rod 403 to move, the second hydraulic rod 403 drives the second moving plate 404, the second moving plate 404 moves back and forth, the front and back position of the engraving member 7 is adjusted by moving the second moving plate 404 back and forth, the second screw 503 is rotated by driving the fourth motor 504, the second nut 607 is moved on the second screw 503 by rotating the second screw 503, the third moving plate 605 is moved up and down by driving the second nut 607, the up and down position of the engraving member 7 is adjusted by moving the third moving plate 605 up and down, the third screw 603 is rotated by driving the fifth motor 604, the third nut is moved on the third screw 603 by rotating the third screw 603, the fourth moving plate 701 is driven by the third nut 705, the fourth moving plate 701 is moved left and right, the position of the engraving member 7 is adjusted left and right by moving the fourth moving plate 701, the drill 703 is driven by the sixth motor 702 to carve the surface of the tile.

When in use, firstly, the support plate 201 is driven by the third motor 216 to rotate on the base platform 1, the direction of the first sliding bottom plate 202 is adjusted by rotating the support plate 201, the first screw rod 206 is driven by the first motor 205 to rotate, the first nut 208 is driven by rotating the first screw rod 206 to move on the first screw rod 206, the first nut 208 drives the first moving plate 204, the position of the first moving plate 204 is adjusted, the feeding component 2 is moved above materials such as ceramic tiles and the like by adjusting the direction of the first sliding bottom plate 202 and the position of the first moving plate 204, the first hydraulic rod 210 is driven by the first hydraulic cylinder 209 to move, the first hydraulic rod 210 drives the connecting plate 211 to adjust the height of the feeding component 2, the feeding component 2 is moved to the position where the materials such as the ceramic tiles and the like are level by adjusting the height of the feeding component 2, and is driven by the pneumatic clamper 212, the two clamping blocks 213 drive the two clamping heads 214 to clamp materials such as ceramic tiles and the like, the materials such as the ceramic tiles and the like are lifted by the drive of the first hydraulic cylinder 209, the flexibility of the operation of the carving machine is improved by adjusting the direction of the first sliding bottom plate 202 and adjusting the position of the first moving plate 204 to transfer the materials such as the ceramic tiles and the like, the feeding component 2 of the carving machine can be rotationally adjusted by driving the third motor 216, meanwhile, the area range of the feeding component 2 of the carving machine capable of conveying the materials is greatly improved, the transferring speed is improved, the use efficiency of the carving machine is improved, the position of the feeding component 2 of the carving machine is adjusted by driving the first motor 205, the feeding component 2 of the carving machine can take and deliver the ceramic tiles at any position in the coverage area, the use flexibility of the carving machine is further improved, and the use efficiency of the carving machine is further improved, by adjusting the feeding component 2 in a turning way, one end of the feeding component 2 can be moved out from the upper part of the operating platform 3, so that sufficient space is reserved for the carving component 7, the carving function of the carving machine can be fully exerted, the freedom degree of carving operation of the carving machine is improved, the carving effect of the carving machine is improved, the position of the feeding component 2 can be moved more stably and accurately by using the first sliding block 207 in a sliding fit manner on the first sliding rail 203, the feeding operation accuracy of the carving machine is improved, the carving accuracy of the tile carving machine is further improved, the complex alignment adjusting process is avoided, the carving effect is greatly improved, the tile carving effect is good in economic value and market prospect, then, the tile material is moved to the upper part of the operating platform 3 through the feeding component 2, the two clamping blocks 213 are loosened by driving of the pneumatic clamp holder 212, the tile material is flatly placed on the backing plate 302 at the top of the operating platform 3, the cross section of the clamping heads 214 is arranged to be of a V-shaped structure, so that the ceramic tile is clamped between the two clamping heads 214 more tightly, the stability of the feeding component 2 for carrying the ceramic tile is improved, the reliability of the carving machine in use is improved, the second motor 215 is arranged on the clamping block 213, the second motor 215 drives the clamping heads 214 through a rotating handle, the clamping heads 214 can rotate, the ceramic tile is turned over through rotating the clamping heads 214, the inclination angle of the ceramic tile can be flexibly adjusted in the conveying process through turning over the ceramic tile, convenience is brought to safe transfer of the ceramic tile, the use safety of the carving machine is improved, meanwhile, the carving operation on the back side of the ceramic tile is facilitated through turning over the ceramic tile, the carving flexibility is further improved, the grooves 301 are formed in the top of the operating platform 3, chips generated in the carving process are collected, and refuge chips float everywhere on the ground, the pollution to the surrounding environment is reduced, the environmental protection performance is improved, finally, the second hydraulic cylinder 402 drives the second hydraulic rod 403 to move, the second hydraulic rod 403 drives the second moving plate 404 to move the second moving plate 404 back and forth, the front and back positions of the engraving assembly 7 are adjusted by moving the second moving plate 404 back and forth, the fourth motor 504 drives the second screw rod 503 to rotate, the second nut 607 moves on the second screw rod 503 by rotating the second screw rod 503, the second nut 607 drives the third moving plate 605 to move the third moving plate 605 up and down, the up and down positions of the engraving assembly 7 are adjusted by moving the third moving plate 605 up and down, the fifth motor 604 drives the third screw rod 603 to rotate, the third nut 705 moves on the third screw rod 603 by rotating the third screw rod 603, the third nut 705 drives the fourth moving plate 701 to move the fourth moving plate 701 left and right, the position of the engraving component 7 is adjusted left and right by moving the fourth moving plate 701 left and right, the engraving flexibility of the engraving machine is improved by adjusting the position of the engraving component 7 front and back, up and down and left and right, thereby improving the richness of the carving patterns of the carving machine, the back and forth movement of the carving component 7 of the carving machine is smoother and smoother by using the second sliding block 406 to be matched on the second sliding rail 405 in a sliding way, by using the third sliding block 606 to be slidably fitted on the third sliding rail 502, the up-and-down adjustment of the engraving assembly 7 of the engraving machine is more stable, the fourth sliding block 704 is in sliding fit with the fourth sliding rail 602, so that the left and right movement of the engraving component 7 of the engraving machine is smoother, through making the regulation of sculpture subassembly 7 more level and smooth stable, reduce the shake of sculpture in-process machine to improve glyptic success rate and improve the quality of sculpture product.

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, and the embodiments and descriptions given above are only illustrative of the principles of the present invention, and various changes and modifications may be made without departing from the spirit and scope of the invention, which fall within the scope of the claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (10)

1. The utility model provides a ceramic tile engraver for construction, includes base station (1), pay-off subassembly (2), operation panel (3) and sculpture subassembly (7), its characterized in that: the automatic carving machine is characterized in that a feeding assembly (2) is installed at one end of the top of the base platform (1), the operating table (3) is fixedly welded in the middle of the top of the base platform (1), a front-and-back moving assembly (4) is horizontally fixed at one end, far away from the feeding assembly (2), of the top of the base platform (1), an up-and-down moving assembly (5) is vertically installed on the front-and-back moving assembly (4), a left-and-right moving assembly (6) is in sliding fit with the up-and-down moving assembly (5), and a carving assembly (7);

wherein, pay-off subassembly (2) includes backup pad (201), first sliding bottom plate (202) and first pneumatic cylinder (209), backup pad (201) is vertical setting, backup pad (201) normal running fit is at the top of base station (1), one side welding level of backup pad (201) has first sliding bottom plate (202), first sliding bottom plate (202) are located backup pad (201) and keep away from the one end of base station (1), one side horizontal welding that first sliding bottom plate (202) kept away from backup pad (201) has first slide rail (203), the cross-section of first slide rail (203) is "worker" style of calligraphy structure, sliding fit has first shifting plate (204) on first slide rail (203), one side welding that first sliding rail (203) were kept away from to first shifting plate (204) has first pneumatic cylinder (209), first pneumatic cylinder (209) are vertical setting, a first hydraulic rod (210) is arranged at the bottom end of the first hydraulic cylinder (209), a connecting plate (211) is welded at the bottom end of the first hydraulic rod (210), a pneumatic clamp holder (212) is installed on one side of the connecting plate (211), two clamping blocks (213) are installed on one side of the pneumatic clamp holder (212), and a clamping head (214) is arranged at one end of each clamping block (213);

a groove (301) is formed in the top of the operating table (3), and a plurality of backing plates (302) are welded in the groove (301);

the front-back moving assembly (4) comprises a second sliding bottom plate (401), a second hydraulic cylinder (402) and a second hydraulic rod (403), the second sliding bottom plate (401) is of an L-shaped structure, the second sliding bottom plate (401) is horizontally welded to the top of the base station (1), the second hydraulic cylinder (402) is horizontally installed at one end of the second sliding bottom plate (401), the second hydraulic rod (403) is arranged at one end, close to the second sliding bottom plate (401), of the second hydraulic cylinder (402), and the second moving plate (404) is connected to one end, away from the second hydraulic cylinder (402), of the second hydraulic rod (403);

the up-down moving assembly (5) comprises a third sliding bottom plate (501), a third sliding rail (502) and a fourth motor (504), the third sliding bottom plate (501) is vertically welded at the top of the second moving plate (404), two third sliding rails (502) are welded at one side of the third sliding bottom plate (501), the cross sections of the two third sliding rails (502) are in an I-shaped structure, a left-right moving assembly (6) is matched on the two third sliding rails (502) in a sliding manner, the left-right moving assembly (6) comprises a fourth sliding bottom plate (601), a fourth sliding rail (602) and a third moving plate (605), the third moving plate (605) is welded at one side of the fourth sliding bottom plate (601), the fourth sliding bottom plate (601) is matched on the two third sliding rails (502) in a sliding manner through the third moving plate (605), and one side of the fourth sliding rail (602) far away from the third moving plate (605) is horizontally welded with the two fourth sliding rails (602), the two fourth sliding rails (602) are matched with an engraving assembly (7) in a sliding manner;

the engraving assembly (7) comprises a fourth moving plate (701), a sixth motor (702) and a drill bit (703), the fourth moving plate (701) is in sliding fit with a fourth sliding rail (602), the sixth motor (702) is vertically installed on one side of the fourth moving plate (701), and the drill bit (703) is installed at the bottom end of the sixth motor (702).

2. The tile carving machine for building construction according to claim 1, wherein: base station (1) is hollow structure, and one side of base station (1) is equipped with the opening, and base station (1) opening part articulates there is cabinet door (102), and handle (103) that are "U" type structure are installed to one side of cabinet door (102), and the top welding of base station (1) has a plurality of to support chassis (101), and the bottom that a plurality of supported chassis (101) all bonds has the plastic pad.

3. The tile carving machine for building construction according to claim 1, wherein: a third motor (216) is vertically installed at one end, close to the feeding component (2), in the base platform (1), the cross section of the supporting plate (201) is of an L-shaped structure, and the top of the third motor (216) is connected with the bottom of the supporting plate (201) through a rotating shaft.

4. The tile carving machine for building construction according to claim 1, wherein: a first motor (205) is installed at one end of the first sliding bottom plate (202), a first screw rod (206) is rotatably matched at one side of the first sliding bottom plate (202), and one end, close to the first sliding bottom plate (202), of the first motor (205) is connected with the first screw rod (206) through a rotating shaft.

5. The tile carving machine for building construction according to claim 4, wherein: one side of the first moving plate (204) far away from the first hydraulic cylinder (209) is welded with a first sliding block (207) and a first nut (208), one side of the first sliding block (207) far away from the first moving plate (204) is provided with a first sliding chute, the cross section of the first sliding chute is matched with the cross section of the first sliding rail (203), the first sliding block (207) is in sliding fit on the first sliding rail (203), and the first nut (208) is in threaded fit on the first screw rod (206).

6. The tile carving machine for building construction according to claim 1, wherein: second motor (215) are all installed to one side of two clamp splice (213), and two second motor (215) all are connected with through the pivot and change the handle, and two are changeed the one end of keeping away from second motor (215) and are connected with two chucks (214) through the pivot, and the cross-section of two chucks (214) all is "V" style of calligraphy structure.

7. The tile carving machine for building construction according to claim 1, wherein: the top horizontal welding machine of second sliding bottom plate (401) has two second slide rails (405), the cross-section of two second slide rails (405) all is "worker" style of calligraphy structure, the second moves the bottom welding of board (404) has two second slider (406), the second spout has all been seted up to the bottom of two second slider (406), the size of second spout cross-section and the size looks adaptation of second slide rail (405) cross-section, two second slider (406) sliding fit are on two second slide rails (405), the second moves board (404) through two second slider (406) sliding fit on two second slide rails (405).

8. The tile carving machine for building construction according to claim 1, wherein: the top of third sliding bottom plate (501) is equipped with fourth motor (504), one side normal running fit that third sliding bottom plate (501) is close to third slide rail (502) has second lead screw (503), the bottom of fourth motor (504) is connected with the top of second lead screw (503) through the pivot, the third moves one side welding that fourth sliding bottom plate (601) was kept away from in board (605) has two third sliders (606) and a second nut (607), the third spout has all been seted up to one side of two third sliders (606), the size of two third spout cross-sections and the size looks adaptation of two third slide rail (502) cross-sections, sliding fit is on two third slide rail (502) respectively in two third sliders (606), second nut (607) screw-thread fit is on second lead screw (503).

9. The tile carving machine for building construction according to claim 1, wherein: a fifth motor (604) is installed at one end of a fourth sliding bottom plate (601), a third screw rod (603) is rotatably matched at one side, close to a fourth sliding rail (602), of the fourth sliding bottom plate (601), one end of the fifth motor (604) is connected with the third screw rod (603) through a rotating shaft, two fourth sliding blocks (704) and a third nut (705) are welded at one side of a fourth moving plate (701), a fourth sliding groove is formed in one side of each of the two fourth sliding blocks (704), the size of the cross section of the fourth sliding groove is matched with the size of the cross section of the fourth sliding rail (602), the fourth sliding block (704) is slidably matched on the fourth sliding rail (602), and the third nut (705) is in threaded fit on the third screw rod (603).

10. A tile carving machine for construction according to claim 1, wherein: the use method of the tile carving machine specifically comprises the following steps:

the method comprises the following steps: driven by a third motor (216), the support plate (201) is enabled to rotate on the base platform (1), the direction of the first sliding bottom plate (202) is adjusted by rotating the support plate (201), the first motor (205) is enabled to drive the first screw rod (206) to rotate, the first nut (208) is enabled to move on the first screw rod (206) by rotating the first screw rod (206), the first nut (208) drives the first moving plate (204), the position of the first moving plate (204) is adjusted, the feeding assembly (2) is moved above materials such as ceramic tiles and the like by adjusting the direction of the first sliding bottom plate (202) and the position of the first moving plate (204), the first hydraulic rod (210) is enabled to move by driving the first hydraulic cylinder (209), the first hydraulic rod (210) drives the connecting plate (211), the height of the feeding assembly (2) is adjusted, and the height of the feeding assembly (2) is adjusted by adjusting the height of the feeding assembly, the feeding assembly (2) is moved to the position where materials such as tiles are flush, the pneumatic clamp holder (212) drives the feeding assembly to enable the two clamping blocks (213) to drive the two clamping heads (214) to clamp the materials such as the tiles, the materials such as the tiles are lifted up through the driving of the first hydraulic cylinder (209), and the materials such as the tiles are transferred by adjusting the direction of the first sliding bottom plate (202) and the position of the first moving plate (204);

step two: the tile material is moved above the operating platform (3) through the feeding assembly (2), and the two clamping blocks (213) are loosened through the driving of the pneumatic clamp holder (212), so that the tile material is flatly placed on the base plate (302) at the top of the operating platform (3);

step three: the second hydraulic cylinder (402) drives the second hydraulic rod (403) to move, the second hydraulic rod (403) drives the second moving plate (404) to move the second moving plate (404) back and forth, the front and back positions of the engraving assembly (7) are adjusted by moving the second moving plate (404) back and forth, the second motor (504) drives the second lead screw (503) to rotate, the second nut (607) moves on the second lead screw (503) by rotating the second lead screw (503), the second nut (607) drives the third moving plate (605) to move the third moving plate (605) up and down, the upper and lower positions of the engraving assembly (7) are adjusted by moving the third moving plate (605) up and down, the third lead screw (603) rotates by driving the fifth motor (604), and the third nut (705) moves on the third lead screw (603) by rotating the third lead screw (603), the third nut (705) drives the fourth moving plate (701), the fourth moving plate (701) moves left and right, the position of the carving component (7) is adjusted left and right by moving the fourth moving plate (701) left and right, and the drill bit (703) is driven by the sixth motor (702) to carve the surface of the ceramic tile.

Images