CN111622475B - Ceramic tile cutting and laying all-in-one machine for decoration engineering and working method thereof - Google Patents

Abstract

The invention discloses a ceramic tile cutting and laying integrated machine for decoration engineering and a working method thereof, the ceramic tile cutting and laying integrated machine pushes an upper push plate upwards through a jacking cylinder piston rod, the upper push plate moves upwards to be near a tile inlet, a ceramic tile is placed on the upper push plate, the jacking cylinder piston rod contracts, the ceramic tile is stacked on the upper push plate, the upper push plate descends to a groove at the bottom of a storage box, a limiting plate is pushed by a limiting cylinder piston rod, the limiting plate fixes the ceramic tile, the pushing cylinder piston rod pushes a push plate, the push plate pushes the ceramic tile at the bottom out of a tile outlet and pushes the ceramic tile into a processing box through a connecting port, the ceramic tile is pushed on a water, through the structure arrangement, the ceramic tile cutting and laying all-in-one machine can stack and store ceramic tiles, so that the ceramic tiles can be laid automatically, simultaneously, through the design of the limiting plate, the situation that the tiles are not fixed and the tiles are broken when being stored in the storage box in the moving process of the integrated machine is prevented.

Description

Ceramic tile cutting and laying all-in-one machine for decoration engineering and working method thereof

Technical Field

The invention relates to the technical field of decoration engineering, in particular to a ceramic tile cutting and laying all-in-one machine for decoration engineering and a working method thereof.

Background

The decoration engineering refers to a construction process in building construction, and the concrete contents include plastering of inner and outer wall surfaces and a ceiling, decorating surfaces and veneering surfaces of the inner and outer walls, decorating surfaces of floor surfaces, mounting of decorations on vertical surfaces of buildings, painting and pasting of wooden products such as doors and windows and the like and metal products and the like. When the decoration engineering construction is carried out, the arc iron plate is used when the decoration wall is manufactured, and the surface of the arc iron plate needs to be polished before decoration.

Among the prior art ceramic tile cutting equipment when cutting the ceramic tile, need the workman to put the ceramic tile on cutting equipment and cut, need workman oneself to lay at the ceramic tile cutting, whole cutting, laying process all need workman's hands to participate in, not only cause the injury to the workman easily when the ceramic tile cutting simultaneously whole laying process need the workman lay by oneself, workman's intensity of labour is big. Current ceramic tile cutting equipment can't save the ceramic tile and transport, is used for ceramic tile surface cooling to carry out water spray treatment during the cutting simultaneously, and the water after nevertheless handling is difficult to be collected, and current laying equipment lays the effect simultaneously not good.

Disclosure of Invention

The invention aims to provide a ceramic tile cutting and laying all-in-one machine for decoration engineering and a working method thereof, and solves the following technical problems: (1) the ceramic tile cutting and laying all-in-one machine can stack and store ceramic tiles at the bottom from a tile outlet and push the ceramic tiles into a processing box through a connecting port, the ceramic tiles are pushed on a water filtering belt, and the ceramic tiles can be stacked and stored through the structure arrangement, so that the automatic laying of the ceramic tiles is facilitated, and meanwhile, the situation that the ceramic tiles are collided and cracked due to the fact that the ceramic tiles are not fixed in the storage box in the moving process of the all-in-one machine is prevented through the design of the limiting plate; (2) by starting a fifth motor, the two driving rollers are matched with the water filtering belt to convey the ceramic tile, after the ceramic tile is conveyed to a cutting position, the water filtering belt stops rotating, the two lifting cylinder piston rods push the lower pressing plate downwards, the lower pressing plate is pressed on the upper surface of the ceramic tile, the micro-motion cylinder piston rods clamp the side edge of the ceramic tile through the clamping plate, the first oil cylinder drives the cutting blade to descend through the lifting shell, the output shaft of the first motor drives the first connecting block to move horizontally through the lead screw, the first connecting block drives the first oil cylinder to move through the oil cylinder seat, the second motor cuts the upper surface of the ceramic tile into a cutting groove through the cutting blade, a spray gun sprays water in the water storage tank through a hose in the cutting process to cool the cutting groove on the ceramic tile, meanwhile, tile ash is adsorbed by water during cutting, then the clamping plate and the lower pressing plate are cancelled to fix the ceramic tile, the, the all-in-one machine can effectively fix ceramic tiles with different widths, simultaneously, the ceramic tiles are not directly cut off during cutting, the condition that a cutting piece is in contact with a water filter belt is avoided, meanwhile, through the design of two spray guns, the ceramic tiles during cutting are cooled and dust generated during cutting is treated, the ceramic tiles are prevented from cracking during high-temperature cutting, meanwhile, the condition that the dust is randomly blown is avoided, and meanwhile, waste water is conveyed out through a conveying cavity through a spiral auger, so that the waste water is convenient to collect; (3) water sprayed out through a spray gun enters a conveying cavity through a waste water hopper, a fourth motor is started, an output shaft of the fourth motor drives a spiral auger to rotate, the spiral auger conveys waste water out of a water outlet, a filter water belt conveys tiles onto a shaft plate, a piston rod of a fourth oil cylinder contracts to drive the shaft plate to rotate, a second oil cylinder presses the tiles downwards through a bending plate, the tiles are broken off from a cutting position, meanwhile, a piston rod of a third oil cylinder pushes a rotating plate downwards, the rotating plate adsorbs the tiles on the shaft plate through a negative pressure sucking disc, then, a third motor is started, an output shaft of the third motor drives a moving plate to move through matching of a lead screw and a second connecting block, then, the third oil cylinder moves to the upper side of a laying opening, a piston rod of the third oil cylinder pushes the rotating plate downwards, further, the tiles descend from the bottom of the laying opening, the tiles are laid on the ground, and, make things convenient for the ceramic tile rupture, can carry out automation with the ceramic tile through the negative pressure sucking disc and lay effectually.

The purpose of the invention can be realized by the following technical scheme:

a ceramic tile cutting and laying integrated machine for decoration engineering comprises a processing box, wherein a storage box is arranged on the processing box, a water storage tank is arranged on the processing box, a tile inlet is formed in the top of the storage box, two limiting cylinders are arranged on the inner wall of the storage box, limiting plates are fixedly connected to the end parts of piston rods of the two limiting cylinders, a pushing cylinder is arranged on the outer wall of the storage box, a pushing plate is arranged at the end part of a piston rod of the pushing cylinder, a jacking cylinder is arranged at the bottom of the outer wall of the storage box, a groove is formed in the bottom of the inner wall of the storage box, an upper push plate is arranged in the groove on the storage box, the end part of the piston rod of the jacking cylinder is connected with the lower surface of the upper push plate, the processing box is communicated with the storage box, the end part of a piston rod of the micro-motion cylinder is provided with a clamping plate, the inner wall of the top of the processing box is provided with an installation shell, the installation shell is provided with an oil cylinder seat in a sliding manner, the oil cylinder seat is provided with a first oil cylinder, the end part of a piston rod of the first oil cylinder is connected with a lifting shell, the lifting shell is provided with a cutting blade, the lifting shell is provided with two spray guns, the cutting blade is arranged above the water filtering belt, the inner wall of the top of the processing box is provided with a movable plate in a sliding manner, the lower surface of the movable plate is provided with a second oil cylinder and a third oil cylinder, the end part of a piston rod of the second oil cylinder is provided with a bending plate, the end part of a piston rod of the third oil cylinder is connected with a rotating plate in a rotating manner, the lower surface of, the end part of a piston rod of the fourth oil cylinder is rotatably connected with the lower surface of the shaft plate, the bottom of the processing box is provided with a laying opening, a waste water bucket is arranged below the water filtering belt, and the bottom of the waste water bucket is communicated with the top of the conveying cavity.

Furthermore, four support columns are installed at the bottom of the storage box, and the four support columns are respectively installed at the four corner positions of the bottom of the storage box.

Further, two spacing cylinders fixed mounting are in depositing case homonymy inner wall, and two spacing cylinders are vertical setting, the limiting plate is vertical to be set up in depositing the incasement.

Further, the catch plate sets up in the limiting plate below, deposit case one side and seted up out the brick mouth, it sets up in the coplanar with the catch plate to go out the brick mouth, the connector has been seted up on the processing case, the connector is linked together with a brick mouth.

Further, the lift cylinder is installed in processing incasement wall top, and two lift cylinders set up respectively in the installation shell both sides, first motor is installed to installation shell one side, rotate on the installation shell and install the lead screw, first motor output shaft lead screw rotates on the lead screw and overlaps and be equipped with first connecting block, first hydro-cylinder piston rod is connected at the lift shell top, the second motor is installed to lift shell one side, second motor output shaft connects the cutting piece.

Furthermore, two spray guns are symmetrically arranged on two sides of the lifting shell, a hose is arranged at a water inlet of each spray gun, one end, away from each spray gun, of the hose penetrates through the top wall of the processing box to be communicated with the bottom of the water storage tank, two sliding rails are arranged in the mounting shell, two sliding blocks are arranged on the oil cylinder base and are respectively arranged on the upper side and the lower side of the oil cylinder base, and the oil cylinder base is connected with the two sliding rails through the two sliding blocks in a sliding mode.

Furthermore, the water filtering belt is in transmission connection through two driving rollers, the water filtering belt is arranged below the two lower pressing plates, a second connecting block is embedded on the movable plate, the outer peripheral surface of the screw rod is sleeved with the second connecting block, the screw rod is connected with an output shaft of a third motor, the third motor is fixed on the inner wall of the top of the processing box, two sliding rails are arranged on two sides of the screw rod respectively, two sliding blocks are embedded on the upper surface of the movable plate, and the movable plate is in sliding connection with the two sliding rails through the two sliding blocks.

Furthermore, four negative pressure suction cups are respectively arranged at four corners of the lower surface of the rotating plate, universal wheels are respectively arranged at the four corners of the bottom of the processing box, a fifth motor is arranged on the side wall of the processing box, and an output shaft of the fifth motor is connected with one of the driving rollers.

Further, a fourth motor is installed on one side of the conveying cavity, a spiral flood dragon is connected to the end portion of an output shaft of the fourth motor, the spiral flood dragon is arranged in the conveying cavity, and a water outlet is formed in the conveying cavity.

Further, the working method of the ceramic tile cutting and laying all-in-one machine for the decoration engineering comprises the following steps:

the method comprises the following steps: the ceramic tile cutting machine comprises a jacking cylinder piston rod, an upper push plate, a limiting plate, a ceramic tile, a pushing cylinder piston rod, a lower pressing plate, a first oil cylinder and a second oil cylinder, wherein the jacking cylinder piston rod pushes the upper push plate upwards, the upper push plate moves upwards to be close to a tile inlet, the ceramic tile is placed on the upper push plate, the jacking cylinder piston rod contracts, the ceramic tile is stacked on the upper push plate, the upper push plate descends to be in a groove at the bottom of a storage box, the limiting plate is pushed by the limiting cylinder piston rod, the limiting plate fixes the ceramic tile, the pushing cylinder piston rod pushes the pushing plate, the pushing plate pushes the bottom ceramic tile out of the tile outlet and pushes the ceramic tile into a processing box through a connector, the ceramic tile is pushed on a water filtering belt, a fifth motor is started, two driving rollers are matched with the water filtering belt to convey the, the ceramic tile cutting machine comprises a first motor, a second motor, a clamping plate, a lower pressing plate, a water filtering belt, a first oil cylinder, a second oil cylinder, a first oil cylinder seat, a second oil cylinder seat, a first motor, a second motor, a cutting blade, a spray gun, a water storage tank, a water outlet pipe, a water inlet pipe, a water outlet pipe, a water inlet pipe, a water outlet pipe, a water;

step two: spray gun spun water passes through the waste water bucket and gets into and carry the intracavity, open the fourth motor, fourth motor output shaft drives the spiral flood dragon and rotates, the spiral flood dragon carries out waste water from the delivery port, the filter water area carries the ceramic tile to the axletree board on, the contraction of fourth hydro-cylinder piston rod drives the axletree board rotatory, the second hydro-cylinder moves the ceramic tile through the board of bending downwards, the ceramic tile is broken from the cutting position, third hydro-cylinder piston rod promotes the rotor plate downwards simultaneously, the rotor plate adsorbs the ceramic tile on the axletree board through the negative pressure sucking disc, then open the third motor, third motor output shaft drives the movable plate through the cooperation of lead screw with the second connecting block and removes, and then the third hydro-cylinder removes to laying mouthful top, third hydro-cylinder piston rod promotes the rotor plate downwards, and then descend the ceramic tile from laying mouthful bottom.

The invention has the beneficial effects that:

(1) the invention relates to a ceramic tile cutting and laying all-in-one machine for decoration engineering and a working method thereof, the upper push plate is pushed upwards by the piston rod of the jacking air cylinder, the upper push plate moves upwards to be close to the tile inlet, the ceramic tile is placed on the upper push plate, the piston rod of the jacking air cylinder contracts to stack the ceramic tile on the upper push plate, the upper push plate descends into the groove at the bottom of the storage box, the piston rod of the limiting air cylinder pushes the limiting plate, the limiting plate fixes the ceramic tile, the piston rod of the pushing air cylinder pushes the push plate, the push plate pushes the ceramic tile at the bottom out of the tile outlet and pushes the ceramic tile into the processing box through the connector, and the ceramic tile is pushed on the, through the structure arrangement, the ceramic tile cutting and laying all-in-one machine can stack and store ceramic tiles, so that the ceramic tiles can be laid automatically, meanwhile, through the design of the limiting plate, the situation that the ceramic tiles are not fixed in the storage box during the movement of the all-in-one machine and are collided and cracked due to the fact that the ceramic tiles are stored in the storage box is prevented;

(2) by starting a fifth motor, the two driving rollers are matched with the water filtering belt to convey the ceramic tile, after the ceramic tile is conveyed to a cutting position, the water filtering belt stops rotating, the two lifting cylinder piston rods push the lower pressing plate downwards, the lower pressing plate is pressed on the upper surface of the ceramic tile, the micro-motion cylinder piston rods clamp the side edge of the ceramic tile through the clamping plate, the first oil cylinder drives the cutting blade to descend through the lifting shell, the output shaft of the first motor drives the first connecting block to move horizontally through the lead screw, the first connecting block drives the first oil cylinder to move through the oil cylinder seat, the second motor cuts the upper surface of the ceramic tile into a cutting groove through the cutting blade, a spray gun sprays water in the water storage tank through a hose in the cutting process to cool the cutting groove on the ceramic tile, meanwhile, tile ash is adsorbed by water during cutting, then the clamping plate and the lower pressing plate are cancelled to fix the ceramic tile, the, the all-in-one machine can effectively fix ceramic tiles with different widths, simultaneously, the ceramic tiles are not directly cut off during cutting, the condition that a cutting piece is in contact with a water filter belt is avoided, meanwhile, through the design of two spray guns, the ceramic tiles during cutting are cooled and dust generated during cutting is treated, the ceramic tiles are prevented from cracking during high-temperature cutting, meanwhile, the condition that the dust is randomly blown is avoided, and meanwhile, waste water is conveyed out through a conveying cavity through a spiral auger, so that the waste water is convenient to collect;

(3) water sprayed out of a spray gun enters a conveying cavity through a waste water hopper, a fourth motor is started, an output shaft of the fourth motor drives a spiral auger to rotate, the spiral auger conveys waste water out of a water outlet, a filter water belt conveys tiles onto a shaft plate, a piston rod of a fourth oil cylinder contracts to drive the shaft plate to rotate, a second oil cylinder presses the tiles downwards through a bending plate, the tiles are broken off from a cutting position, meanwhile, a piston rod of the third oil cylinder pushes a rotating plate downwards, the rotating plate adsorbs the tiles on the shaft plate through a negative pressure sucking disc, then, a third motor is started, an output shaft of the third motor drives a moving plate to move through the matching of a lead screw and a second connecting block, further, the third oil cylinder moves to the upper part of a laying port, a piston rod of the third oil cylinder pushes the rotating plate downwards, further, the tiles descend from the bottom of the laying port, the tiles are laid on the ground, make things convenient for the ceramic tile rupture, can carry out automation with the ceramic tile through the negative pressure sucking disc and lay effectually.

Drawings

The invention will be further described with reference to the accompanying drawings.

FIG. 1 is a schematic structural diagram of a ceramic tile cutting and laying all-in-one machine for decoration engineering of the invention;

FIG. 2 is a view showing the internal structure of the storage case of the present invention;

FIG. 3 is an internal structural view of the processing box of the present invention;

FIG. 4 is a side view of the lower platen of the present invention;

FIG. 5 is a side view of the mounting housing of the present invention;

FIG. 6 is a side view of the moving plate of the present invention;

fig. 7 is an internal structural view of the delivery chamber of the present invention.

In the figure: 1. a processing box; 2. a storage box; 3. a water storage tank; 4. a support pillar; 5. entering a brick inlet; 6. a limiting cylinder; 7. a limiting plate; 8. a push cylinder; 9. a push plate; 10. jacking a cylinder; 11. a push plate is arranged; 12. a brick outlet; 13. a connecting port; 14. a lifting cylinder; 15. a lower pressing plate; 16. a micro-motion cylinder; 17. a clamping plate; 18. mounting a shell; 19. a first motor; 20. a first connection block; 21. a cylinder block; 22. a first cylinder; 23. a lifting shell; 24. a second motor; 25. a spray gun; 26. a hose; 27. a drive roller; 28. a water filtering belt; 29. moving the plate; 30. a second connecting block; 31. a third motor; 32. a second cylinder; 321. bending the plate; 33. a third oil cylinder; 331. a rotating plate; 332. a negative pressure sucker; 34. a shaft plate; 35. an upright plate; 36. a fourth cylinder; 37. paving a port; 38. a wastewater bucket; 39. a fourth motor; 40. a delivery lumen; 41. a spiral flood dragon; 42. a water outlet; 43. and a fifth motor.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the invention relates to a ceramic tile cutting and laying integrated machine for decoration engineering, which comprises a processing box 1, wherein a storage box 2 is arranged on the processing box 1, a water storage tank 3 is arranged on the processing box 1, a tile inlet 5 is arranged at the top of the storage box 2, two limiting cylinders 6 are arranged on the inner wall of the storage box 2, the end parts of piston rods of the two limiting cylinders 6 are fixedly connected with a limiting plate 7, a pushing cylinder 8 is arranged on the outer wall of the storage box 2, a pushing plate 9 is arranged at the end part of the piston rod of the pushing cylinder 8, a jacking cylinder 10 is arranged at the bottom of the outer wall of the storage box 2, a groove is arranged at the bottom of the inner wall of the storage box 2, an upper pushing plate 11 is arranged in the groove on the storage box 2, the end part of the piston rod of the jacking cylinder 10 is connected with, two micro-motion cylinders 16 are symmetrically arranged on two sides of the lower pressing plate 15, a clamping plate 17 is arranged at the end part of a piston rod of each micro-motion cylinder 16, an installation shell 18 is arranged on the inner wall of the top of the processing box 1, an oil cylinder seat 21 is arranged on the installation shell 18 in a sliding manner, a first oil cylinder 22 is arranged on the oil cylinder seat 21, the end part of the piston rod of the first oil cylinder 22 is connected with a lifting shell 23, a cutting piece is arranged on the lifting shell 23, two spray guns 25 are arranged on the lifting shell 23, the cutting piece is arranged above the water filtering belt 28, a moving plate 29 is arranged on the inner wall of the top of the processing box 1 in a sliding manner, a second oil cylinder 32 and a third oil cylinder 33 are arranged on the lower surface of the moving plate 29, a bending plate 321 is arranged at the end part of the piston rod of the second oil cylinder 32, a rotating plate 331 is rotatably, a fourth oil cylinder 36 is rotatably mounted on one side of the vertical plate 35 through a hinge, the end part of a piston rod of the fourth oil cylinder 36 is rotatably connected with the lower surface of the shaft plate 34, a laying port 37 is formed in the bottom of the processing box 1, a waste water bucket 38 is arranged below the water filtering belt 28, and the bottom of the waste water bucket 38 is communicated with the top of the conveying cavity 40.

Specifically, deposit 2 bottoms of case and install four support columns 4, four support columns 4 are installed respectively in depositing 2 bottoms of case corner positions everywhere. Two spacing cylinders 6 fixed mounting are in depositing 2 homonymy inner walls of case, and two spacing cylinders 6 are vertical setting, and limiting plate 7 is vertical to be set up in depositing 2 incasement. The pushing plate 9 is arranged below the limiting plate 7, one side of the storage box 2 is provided with a brick outlet 12, the brick outlet 12 and the pushing plate 9 are arranged on the same plane, the processing box 1 is provided with a connector 13, and the connector 13 is communicated with the brick outlet 12. Lifting cylinder 14 is installed at 1 inner wall top of processing case, and two lifting cylinder 14 set up respectively in installation shell 18 both sides, and first motor 19 is installed to installation shell 18 one side, rotates on the installation shell 18 and installs the lead screw, and first motor 19 output shaft is connected the lead screw, rotates on the lead screw to overlap and is equipped with first connecting block 20, and lift shell 23 top is connected to first hydro-cylinder 22 piston rod, and second motor 24 is installed to lift shell 23 one side, and second motor 24 output shaft is connected the cutting piece. Two spray guns 25 are symmetrically arranged on two sides of the lifting shell 23, a hose 26 is arranged at a water inlet of each spray gun 25, one end, far away from each spray gun 25, of each hose 26 penetrates through the bottom of the top wall communicated water storage tank 3 of the machining box 1, two sliding rails are arranged in the mounting shell 18, two sliding blocks are arranged on the oil cylinder base 21 and are respectively arranged on the upper side and the lower side of the oil cylinder base 21, and the oil cylinder base 21 is connected with the two sliding rails through the two sliding blocks in. The water filtering belt 28 is in transmission connection through the two driving rollers 27, the water filtering belt 28 is arranged below the two lower pressing plates 15, a second connecting block 30 is embedded in the moving plate 29, the outer peripheral surface of the screw rod is sleeved with the second connecting block 30, the screw rod is connected with an output shaft of a third motor 31, the third motor 31 is fixed to the inner wall of the top of the processing box 1, two sliding rails are arranged on two sides of the screw rod respectively, two sliding blocks are embedded in the upper surface of the moving plate 29, and the moving plate 29 is in sliding connection with the two. The four negative pressure suction cups 332 are respectively installed at the four corners of the lower surface of the rotating plate 331, universal wheels are installed at the four corners of the bottom of the processing box 1, the fifth motor 43 is installed on the side wall of the processing box 1, and the output shaft of the fifth motor 43 is connected with one of the driving rollers 27. Carry chamber 40 one side to install fourth motor 39, fourth motor 39 output shaft end connection has spiral flood dragon 41, and spiral flood dragon 41 sets up in carrying chamber 40, has seted up delivery port 42 on the transport chamber 40.

Referring to fig. 1-7, the working process of the tile cutting and laying all-in-one machine for decoration engineering of the present embodiment is as follows:

the method comprises the following steps: a piston rod of a jacking cylinder 10 pushes an upper push plate 11 upwards, the upper push plate 11 moves upwards to be close to a tile inlet 5, a ceramic tile is placed on the upper push plate 11, the piston rod of the jacking cylinder 10 contracts to stack the ceramic tile on the upper push plate 11, the upper push plate 11 descends to a groove at the bottom of a storage box 2, a piston rod of a limiting cylinder 6 pushes a limiting plate 7, the limiting plate 7 fixes the ceramic tile, a piston rod of a pushing cylinder 8 pushes a push plate 9, the push plate 9 pushes the bottom ceramic tile out of a tile outlet 12 and into a processing box 1 through a connecting port 13, the ceramic tile is pushed onto a water filtering belt 28, a fifth motor 43 is started, two driving rollers 27 are matched with the water filtering belt 28 to convey the ceramic tile, after the ceramic tile is conveyed to a cutting position, the water filtering belt 28 stops rotating, piston rods of two lifting cylinders 14 push a lower press plate 15 downwards, the lower press plate 15 is pressed on the upper surface of the ceramic, the first oil cylinder 22 drives the cutting blade to descend through the lifting shell 23, the output shaft of the first motor 19 drives the first connecting block 20 to horizontally move through the lead screw, the first connecting block 20 drives the first oil cylinder 22 to move through the oil cylinder seat 21, the second motor 24 cuts a cutting groove on the upper surface of the ceramic tile through the cutting blade, the spray gun 25 sprays water in the water storage tank 3 through the hose 26 in the cutting process to cool the cutting groove on the ceramic tile, meanwhile, ceramic tile ash is adsorbed by the water in the cutting process, then the clamping plate 17 and the lower pressing plate 15 cancel the fixation of the ceramic tile, and the water filtering belt 28 conveys the ceramic tile;

step two: water sprayed by the spray gun 25 enters the conveying cavity 40 through the waste water hopper 38, the fourth motor 39 is started, an output shaft of the fourth motor 39 drives the spiral flood dragon 41 to rotate, the spiral flood dragon 41 conveys waste water out of the water outlet 42, the water filtering belt 28 conveys tiles onto the shaft plate 34, a piston rod of the fourth oil cylinder 36 contracts to drive the shaft plate 34 to rotate, the second oil cylinder 32 downwards presses the tiles through the bending plate 321, the tiles are broken off from a cutting position, a piston rod of the third oil cylinder 33 downwards pushes the rotating plate 331, the rotating plate 331 adsorbs the tiles on the shaft plate 34 through the negative pressure suction cup 332, then the third motor 31 is started, an output shaft of the third motor 31 drives the moving plate 29 to move through the matching of the screw rod and the second connecting block 30, the third oil cylinder 33 moves to be above the paving opening 37, a piston rod of the third oil cylinder 33 downwards pushes the rotating plate 331, and then the tiles descend from the bottom of the, the tiles are laid on the ground.

The foregoing is merely exemplary and illustrative of the present invention and various modifications, additions and substitutions may be made by those skilled in the art to the specific embodiments described without departing from the scope of the invention as defined in the following claims.

Claims (2)

1. The utility model provides a cut and lay all-in-one of ceramic tile for decoration engineering, which is characterized in that, includes processing case (1), be provided with on processing case (1) and deposit case (2), be provided with storage water tank (3) on processing case (1), deposit case (2) top and seted up into brick mouth (5), deposit case (2) inner wall and install two spacing cylinders (6), two spacing cylinders (6) piston rod end fixed connection limiting plate (7), deposit case (2) outer wall and install promotion cylinder (8), promotion cylinder (8) piston rod end installs slurcam (9), deposit case (2) outer wall bottom and install jacking cylinder (10), deposit case (2) inner wall bottom and set up flutedly, be provided with push pedal (11) in the recess of depositing case (2), push pedal (11) lower surface is connected to jacking cylinder (10) piston rod end, the processing box (1) is communicated with the storage box (2), two lifting cylinders (14) are installed in an inner cavity of the processing box (1), a piston rod of each lifting cylinder (14) is connected with a lower pressing plate (15), two micro-cylinders (16) are symmetrically arranged on two sides of each lower pressing plate (15), a clamping plate (17) is installed at the end part of a piston rod of each micro-cylinder (16), an installation shell (18) is installed on the inner wall of the top of the processing box (1), an oil cylinder seat (21) is arranged on the installation shell (18) in a sliding mode, a first oil cylinder (22) is installed on the oil cylinder seat (21), a lifting shell (23) is connected at the end part of the piston rod of each first oil cylinder (22), cutting pieces are installed on the lifting shell (23), two spray guns (25) are installed on the lifting shell (23), the cutting pieces are arranged above the water filtering belt (28), and a moving plate (, the lower surface of the moving plate (29) is provided with a second oil cylinder (32) and a third oil cylinder (33), a bending plate (321) is arranged at the end part of the piston rod of the second oil cylinder (32), a rotating plate (331) is rotatably connected at the end part of the piston rod of the third oil cylinder (33), four negative pressure suckers (332) are arranged on the lower surface of the rotating plate (331), an upright plate (35) is arranged on one side of the water filtering belt (28), a shaft plate (34) is rotatably arranged on the upright plate (35), a fourth oil cylinder (36) is rotatably arranged on one side of the upright plate (35) through a hinge, the end part of a piston rod of the fourth oil cylinder (36) is rotationally connected with the lower surface of the shaft plate (34), a laying port (37) is formed in the bottom of the processing box (1), a waste water bucket (38) is arranged below the water filtering belt (28), and the bottom of the waste water bucket (38) is communicated with the top of the conveying cavity (40);

the bottom of the storage box (2) is provided with four support columns (4), and the four support columns (4) are respectively arranged at the four corner positions of the bottom of the storage box (2);

the two limiting cylinders (6) are fixedly arranged on the inner walls of the same side of the storage box (2), the two limiting cylinders (6) are longitudinally arranged, and the limiting plate (7) is vertically arranged in the storage box (2);

the pushing plate (9) is arranged below the limiting plate (7), one side of the storage box (2) is provided with a brick outlet (12), the brick outlet (12) and the pushing plate (9) are arranged on the same plane, the processing box (1) is provided with a connecting port (13), and the connecting port (13) is communicated with the brick outlet (12);

the lifting air cylinders (14) are arranged at the top of the inner wall of the processing box (1), the two lifting air cylinders (14) are respectively arranged at two sides of an installation shell (18), a first motor (19) is arranged at one side of the installation shell (18), a screw rod is rotatably arranged on the installation shell (18), an output shaft of the first motor (19) is connected with the screw rod, a first connecting block (20) is rotatably sleeved on the screw rod, a piston rod of a first oil cylinder (22) is connected with the top of a lifting shell (23), a second motor (24) is arranged at one side of the lifting shell (23), and an output shaft of the second motor (24) is connected with a cutting blade;

the two spray guns (25) are symmetrically arranged on two sides of the lifting shell (23), a hose (26) is arranged at a water inlet of each spray gun (25), one end, far away from each spray gun (25), of each hose (26) penetrates through the top wall of the processing box (1) and is communicated with the bottom of the water storage box (3), two sliding rails are arranged in the mounting shell (18), two sliding blocks are arranged on the oil cylinder base (21), the two sliding blocks are respectively arranged on the upper side and the lower side of the oil cylinder base (21), and the oil cylinder base (21) is connected with the two sliding rails in a sliding mode through the two sliding;

the water filtering belt (28) is in transmission connection through two driving rollers (27), the water filtering belt (28) is arranged below two lower pressing plates (15), a second connecting block (30) is embedded on the moving plate (29), the outer peripheral surface of the screw rod is sleeved with the second connecting block (30), the screw rod is connected with an output shaft of a third motor (31), the third motor (31) is fixed on the inner wall of the top of the processing box (1), two sliding rails are arranged on two sides of the screw rod respectively, two sliding blocks are embedded on the upper surface of the moving plate (29), and the moving plate (29) is in sliding connection with the two sliding rails through the two sliding blocks;

the four negative pressure suckers (332) are respectively arranged at four corners of the lower surface of the rotating plate (331), universal wheels are respectively arranged at the four corners of the bottom of the processing box (1), a fifth motor (43) is arranged on the side wall of the processing box (1), and an output shaft of the fifth motor (43) is connected with one driving roller (27);

carry chamber (40) one side to install fourth motor (39), fourth motor (39) output shaft end connection has spiral flood dragon (41), spiral flood dragon (41) set up in carrying chamber (40), delivery port (42) have been seted up on carrying chamber (40).

2. A working method of a ceramic tile cutting and laying all-in-one machine for decoration engineering is characterized by comprising the following steps:

the method comprises the following steps: a piston rod of a jacking cylinder (10) upwards pushes an upper push plate (11), the upper push plate (11) upwards moves to a position near a tile inlet (5), a tile is placed on the upper push plate (11), a piston rod of the jacking cylinder (10) contracts, the tile is stacked on the upper push plate (11), the upper push plate (11) descends to a groove at the bottom of a storage box (2), a limiting plate (7) is pushed by a piston rod of a limiting cylinder (6), the limiting plate (7) fixes the tile, a push plate (9) is pushed by a piston rod of a push cylinder (8), the bottom tile is pushed out from a tile outlet (12) by the push plate (9) and pushed into a processing box (1) through a connecting port (13), the tile is pushed onto a water filtering belt (28), a fifth motor (43) is started, two driving rollers (27) are matched with the water filtering belt (28) to convey the tile, and the water filtering belt (28) stops rotating after the tile is conveyed to, piston rods of two lifting cylinders (14) push a lower pressing plate (15) downwards, the lower pressing plate (15) is pressed on the upper surface of a ceramic tile, piston rods of a micro-motion cylinder (16) clamp the side edge of the ceramic tile through a clamping plate (17), a first oil cylinder (22) drives a cutting piece to descend through a lifting shell (23), an output shaft of a first motor (19) drives a first connecting block (20) to move horizontally through a lead screw, the first connecting block (20) drives the first oil cylinder (22) to move through an oil cylinder seat (21), a second motor (24) cuts a cutting groove on the upper surface of the ceramic tile through the cutting piece, a spray gun (25) sprays water in a water storage tank (3) through a hose (26) in the cutting process, cooling the cutting groove on the ceramic tile, adsorbing ceramic tile ash by water during cutting, then removing the fixation of the ceramic tile by the clamping plate (17) and the lower pressing plate (15), and conveying the ceramic tile by the water filtering belt (28);

step two: water sprayed by the spray gun (25) enters the conveying cavity (40) through the waste water hopper (38), the fourth motor (39) is started, an output shaft of the fourth motor (39) drives the spiral flood dragon (41) to rotate, the spiral flood dragon (41) conveys waste water out of the water outlet (42), the ceramic tile is conveyed onto the shaft plate (34) through the water filtering belt (28), a piston rod of the fourth oil cylinder (36) contracts to drive the shaft plate (34) to rotate, the second oil cylinder (32) downwards presses the ceramic tile through the bending plate (321), the ceramic tile is broken from a cutting position, meanwhile, a piston rod of the third oil cylinder (33) downwards pushes the rotating plate (331), the rotating plate (331) absorbs the ceramic tile on the shaft plate (34) through the negative pressure suction cup (332), then the third motor (31) is started, an output shaft of the third motor (31) drives the moving plate (29) to move through the matching of the screw rod and the second connecting block (30), and then the third laying oil cylinder (33) moves to the position above the laying port, the piston rod of the third oil cylinder (33) pushes the rotating plate (331) downwards, so that the ceramic tiles are descended from the bottom of the paving opening (37) and paved on the ground.

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