CN220975825U - Ceramic tile lamination transfer machine - Google Patents

Abstract

The utility model relates to the technical field of ceramic tile processing, in particular to a ceramic tile stacking and transferring machine, which is characterized in that after ceramic tile production, ceramic tiles of a first conveying mechanism are conveyed through the first conveying mechanism, a worker controls the stacking mechanism through a controller to transfer the ceramic tiles of the first conveying mechanism to a supporting plate, so that stacking of the ceramic tiles is completed, the worker shortens through an electric hydraulic cylinder A through the controller, and the supporting plate drives the stacked ceramic tiles to be placed on a second conveying mechanism, so that stacking and rotating of the ceramic tiles are simultaneously realized; including bottom plate, conveying mechanism and No. two conveying mechanism all install on the bottom plate top, still include controller, A electronic pneumatic cylinder, backup pad and stacking mechanism, controller, A electronic pneumatic cylinder and stacking mechanism all install on the bottom plate top, and A electronic pneumatic cylinder top removes the end and is provided with the backup pad, and conveying mechanism, no. two conveying mechanism, stacking mechanism, A electronic pneumatic cylinder all are connected with the controller electricity.

Description

Ceramic tile lamination transfer machine

Technical Field

The utility model relates to the technical field of ceramic tile processing, in particular to a ceramic tile stacking and transferring machine.

Background

The ceramic is a series of products manufactured by selecting, crushing and the like by taking clay as a main raw material and adding other natural mineral raw materials, manual carrying, packaging and other operations are needed in the production process of the ceramic, and in the ceramic tile production process, two conveying roller ways in different directions need to be reversed, and the ceramic tiles can be preliminarily stacked for the next procedure and packaged for the next step.

In the prior art, the Chinese patent document with the bulletin number of CN101342670B discloses a tile steering device for tile production, the device can accurately control the rotation angle of tiles, but the device has high requirements on a motor and electric control, and can not realize the function of simultaneously completing the steering transportation and stacking of the tiles, and the Chinese patent with the bulletin number of CN204021896U discloses a novel tile automatic offline device, which realizes the problem that the tiles need to be steered for multiple times in the transportation process, but the device also can not realize the function of simultaneously completing the steering transportation and stacking of the tiles.

Disclosure of utility model

In order to solve the technical problems, the utility model provides a tile stacking and transferring machine capable of simultaneously realizing stacking and transferring.

The utility model relates to a ceramic tile stacking and transferring machine, which comprises a bottom plate, a first conveying mechanism, a second conveying mechanism, a controller, an A electric hydraulic cylinder, a supporting plate and a stacking mechanism, wherein the first conveying mechanism and the second conveying mechanism are all arranged at the top end of the bottom plate; after ceramic tile production, the ceramic tile is conveyed through the first conveying mechanism, a worker controls the stacking mechanism through the controller to enable the ceramic tile of the first conveying mechanism to be transferred to the supporting plate, so that stacking of the ceramic tile is completed, and then the worker shortens through the controller through operating the electric hydraulic cylinder A, so that the supporting plate drives the stacked ceramic tile to be placed on the second conveying mechanism, and meanwhile stacking and rotating operation of the ceramic tile are achieved.

Preferably, the stacking mechanism comprises an electric turntable, a stand column, a connecting plate, a support plate, a B electric hydraulic cylinder, a lifting plate and an electric sucking disc, wherein the electric turntable is arranged at the top end of the bottom plate, the stand column is arranged at the top end of the electric turntable, the connecting plate is arranged at the left end of the stand column, the support plate is arranged at the left end of the connecting plate, the B electric hydraulic cylinder is arranged at the top end of the support plate, the bottom moving end of the B electric hydraulic cylinder extends to the lower part of the support plate and is connected with the top end of the lifting plate, the electric sucking disc is arranged at the bottom end of the lifting plate, and the electric turntable, the B electric hydraulic cylinder and the electric sucking disc are all electrically connected with the controller; when the first conveying mechanism carries out directional conveying on the produced ceramic tiles, a worker stretches through the controller to enable the lifting plate to drive the electric sucker to move downwards, the electric sucker is started, the electric sucker adsorbs the ceramic tiles on the first conveying mechanism, then the electric hydraulic cylinder is operated to shorten, the electric turntable rotates by one hundred eighty degrees, the electric sucker drives the adsorbed ceramic tiles to be transferred to the position right above the supporting plate, then the electric hydraulic cylinder is operated to stretch, and therefore the lifting plate drives the adsorbed ceramic tiles to be placed above the supporting plate through the electric sucker to be repeatedly operated, and stacking of the ceramic tiles is completed.

Preferably, the first conveying mechanism comprises a conveying frame, a first guide roller, a first conveying belt, a first motor and supporting legs, the supporting legs are respectively arranged at four corners of the bottom end of the conveying frame, the bottom ends of the four groups of supporting legs are all connected with the top end of a bottom plate, a plurality of groups of first guide rollers are rotatably arranged on the conveying frame, a plurality of groups of first guide rollers are driven by the first conveying belt, the first motor is arranged at the left end of the conveying frame, the output end of the first motor is connected with the left end of the first guide rollers, and the first motor is electrically connected with the controller; when the produced tiles are conveyed, a worker starts the first motor through the controller, so that a plurality of groups of first guide rollers mutually cooperate to drive the first conveyor belt to rotate, and the tiles placed on the first conveyor belt are conveyed in a directional mode.

Preferably, the second conveying mechanism comprises a vertical plate, a second guide roller, a second conveyor belt and a second motor, wherein the two groups of vertical plates are all arranged at the top end of the bottom plate, a plurality of groups of second guide rollers are rotatably arranged between the two groups of vertical plates, two groups of annular grooves are formed in each group of second guide rollers, a group of second conveyor belts are respectively sleeved in the annular grooves which are parallel to each other in the plurality of groups of second guide rollers, the second motor is arranged at the outer end of the group of vertical plates, the output end of the second motor is connected with the right end of the group of second guide rollers, an electric hydraulic cylinder A and a supporting plate are arranged between the two groups of second conveyor belts, and the second motor is electrically connected with the controller; the electric sucking disc places the ceramic tile on the backup pad top, and the ceramic tile stacks up the back, and staff operation A electric hydraulic cylinder shortens to make the backup pad drive the ceramic tile that stacks and reduce, when the height of backup pad is less than the height of two sets of B electric hydraulic cylinders, the ceramic tile that stacks is placed on two sets of conveyer belts, starts No. two motors, thereby makes multiunit No. two deflector rolls mutually support and thereby makes two sets of conveyer belts transport the operation to the ceramic tile that stacks up.

Preferably, the anti-slip device further comprises an anti-slip pad, and the top end of the supporting plate is provided with the anti-slip pad; the backup pad top is provided with the slipmat, and the ceramic tile is placed on the slipmat, increases contact friction, prevents that the ceramic tile from appearing sliding.

Preferably, the telescopic support further comprises telescopic rods, telescopic rods are respectively arranged at four corners of the bottom end of the supporting plate, and the bottom ends of the four groups of telescopic rods are connected with the top end of the bottom plate; four groups of telescopic links mutually cooperate to guide the supporting plate in the vertical direction, so that the supporting plate can stably lift.

Preferably, the device further comprises a reinforcing plate, wherein the reinforcing plate is arranged at one end of the upright post, and the top end of the reinforcing plate is connected with the bottom end of the connecting plate; the upright post and the connecting plate are connected through the reinforcing plate, so that the connection firmness is improved.

Compared with the prior art, the utility model has the beneficial effects that: after ceramic tile production, the ceramic tile is conveyed through the first conveying mechanism, a worker controls the stacking mechanism through the controller to enable the ceramic tile of the first conveying mechanism to be transferred to the supporting plate, so that stacking of the ceramic tile is completed, and then the worker shortens through the controller through operating the electric hydraulic cylinder A, so that the supporting plate drives the stacked ceramic tile to be placed on the second conveying mechanism, and meanwhile stacking and rotating operation of the ceramic tile are achieved.

Drawings

FIG. 1 is a schematic view of a first axial structure of the present utility model;

FIG. 2 is a schematic view of a second axial structure of the present utility model;

FIG. 3 is an enlarged schematic view of the stacking mechanism;

FIG. 4 is an enlarged schematic view of the structure of the support plate and the telescopic rod;

The reference numerals in the drawings: 1. a bottom plate; 2. a controller; 3. an electric hydraulic cylinder; 4. a support plate; 5. an electric turntable; 6. a column; 7. a connecting plate; 8. a support plate; 9. b, an electric hydraulic cylinder; 10. a lifting plate; 11. an electric suction cup; 12. a transfer frame; 13. a first guide roller; 14. a first conveyor belt; 15. a motor I; 16. a support leg; 17. a vertical plate; 18. a second guide roller; 19. a second transmission belt; 20. a motor II; 21. an anti-slip pad; 22. a telescopic rod; 23. reinforcing plate.

Detailed Description

In order that the utility model may be readily understood, a more complete description of the utility model will be rendered by reference to the appended drawings. This utility model may be embodied in many different forms and is not limited to the embodiments described herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

Example 1

As shown in fig. 1 and 2, the tile stacking and transferring machine comprises a bottom plate 1, a first conveying mechanism and a second conveying mechanism, wherein the first conveying mechanism and the second conveying mechanism are all arranged at the top end of the bottom plate 1, the tile stacking and transferring machine further comprises a controller 2, an electric hydraulic cylinder 3, a supporting plate 4 and a stacking mechanism, the controller 2, the electric hydraulic cylinder 3 and the stacking mechanism are all arranged at the top end of the bottom plate 1, the supporting plate 4 is arranged at the top moving end of the electric hydraulic cylinder 3, and the first conveying mechanism, the second conveying mechanism, the stacking mechanism and the electric hydraulic cylinder 3 are all electrically connected with the controller 2;

As shown in fig. 1, 2 and 3, the stacking mechanism comprises an electric turntable 5, a stand column 6, a connecting plate 7, a support plate 8, a B electric hydraulic cylinder 9, a lifting plate 10 and an electric sucking disc 11, wherein the electric turntable 5 is arranged at the top end of the bottom plate 1, the stand column 6 is arranged at the top end of the electric turntable 5, the connecting plate 7 is arranged at the left end of the stand column 6, the support plate 8 is arranged at the left end of the connecting plate 7, the B electric hydraulic cylinder 9 is arranged at the top end of the support plate 8, the bottom moving end of the B electric hydraulic cylinder 9 extends to the lower part of the support plate 8 and is connected with the top end of the lifting plate 10, the electric sucking disc 11 is arranged at the bottom end of the lifting plate 10, and the electric turntable 5, the B electric hydraulic cylinder 9 and the electric sucking disc 11 are electrically connected with the controller 2;

as shown in fig. 1, the shoe further comprises a non-slip mat 21, and the top end of the supporting plate 4 is provided with the non-slip mat 21;

As shown in fig. 4, the telescopic support further comprises telescopic rods 22, wherein the telescopic rods 22 are respectively arranged at four corners of the bottom end of the supporting plate 4, and the bottom ends of the four groups of telescopic rods 22 are connected with the top end of the bottom plate 1;

As shown in fig. 3, the structure further comprises a reinforcing plate 23, wherein the reinforcing plate 23 is arranged at one end of the upright post 6, and the top end of the reinforcing plate 23 is connected with the bottom end of the connecting plate 7.

In this embodiment, after the tile is produced, the tile is conveyed through the first conveying mechanism, when the first conveying mechanism carries out directional conveying on the produced tile, the worker operates the B electric hydraulic cylinder 9 to extend through the controller 2, thereby enabling the lifting plate 10 to drive the electric sucker 11 to move downwards, starting the electric sucker 11, thereby enabling the electric sucker 11 to adsorb the tile on the first conveying mechanism, then operating the B electric hydraulic cylinder 9 to shorten, enabling the electric turntable 5 to rotate by one hundred eighty degrees, thereby enabling the electric sucker 11 to drive the adsorbed tile to be transferred to the position right above the supporting plate 4, then operating the B electric hydraulic cylinder 9 to extend, thereby enabling the lifting plate 10 to drive the adsorbed tile to be placed above the anti-slip pad 21 through the electric sucker 11, repeating operation, thereby completing the stacking of the tile, then enabling the supporting plate 4 to drive the stacked tile to be placed on the second conveying mechanism through the controller 2 to shorten through operating the a electric hydraulic cylinder 3, thereby simultaneously realizing the operation of stacking and rotating the tile.

Example 2

As shown in fig. 1 and 2, the tile stacking and transferring machine comprises a bottom plate 1, a first conveying mechanism and a second conveying mechanism, wherein the first conveying mechanism and the second conveying mechanism are all arranged at the top end of the bottom plate 1, the tile stacking and transferring machine further comprises a controller 2, an electric hydraulic cylinder 3, a supporting plate 4 and a stacking mechanism, the controller 2, the electric hydraulic cylinder 3 and the stacking mechanism are all arranged at the top end of the bottom plate 1, the supporting plate 4 is arranged at the top moving end of the electric hydraulic cylinder 3, and the first conveying mechanism, the second conveying mechanism, the stacking mechanism and the electric hydraulic cylinder 3 are all electrically connected with the controller 2;

As shown in fig. 1, 2 and 3, the stacking mechanism comprises an electric turntable 5, a stand column 6, a connecting plate 7, a support plate 8, a B electric hydraulic cylinder 9, a lifting plate 10 and an electric sucking disc 11, wherein the electric turntable 5 is arranged at the top end of the bottom plate 1, the stand column 6 is arranged at the top end of the electric turntable 5, the connecting plate 7 is arranged at the left end of the stand column 6, the support plate 8 is arranged at the left end of the connecting plate 7, the B electric hydraulic cylinder 9 is arranged at the top end of the support plate 8, the bottom moving end of the B electric hydraulic cylinder 9 extends to the lower part of the support plate 8 and is connected with the top end of the lifting plate 10, the electric sucking disc 11 is arranged at the bottom end of the lifting plate 10, and the electric turntable 5, the B electric hydraulic cylinder 9 and the electric sucking disc 11 are electrically connected with the controller 2;

As shown in fig. 1, the first conveying mechanism comprises a conveying frame 12, a first guide roller 13, a first conveying belt 14, a first motor 15 and supporting legs 16, the supporting legs 16 are respectively arranged at four corners of the bottom end of the conveying frame 12, the bottom ends of the four groups of supporting legs 16 are all connected with the top end of the bottom plate 1, a plurality of groups of first guide rollers 13 are rotatably arranged on the conveying frame 12, a plurality of groups of first guide rollers 13 are driven by the first conveying belt 14, the first motor 15 is arranged at the left end of the conveying frame 12, the output end of the first motor 15 is connected with the left end of the group of first guide rollers 13, and the first motor 15 is electrically connected with the controller 2;

As shown in fig. 2, the second conveying mechanism comprises a vertical plate 17, a second guide roller 18, a second conveyor belt 19 and a second motor 20, wherein the two vertical plates 17 are all arranged at the top end of the bottom plate 1, a plurality of groups of second guide rollers 18 are rotatably arranged between the two vertical plates 17, each group of second guide rollers 18 is provided with two groups of annular grooves, a group of second conveyor belts 19 are respectively sleeved in the annular grooves which are parallel to each other in the plurality of groups of second guide rollers 18, the second motor 20 is arranged at the outer end of the one group of vertical plates 17, the output end of the second motor 20 is connected with the right end of the group of second guide rollers 18, the electric hydraulic cylinder 3 and the supporting plate 4 are arranged between the two groups of second conveyor belts 19, and the second motor 20 is electrically connected with the controller 2;

as shown in fig. 1, the shoe further comprises a non-slip mat 21, and the top end of the supporting plate 4 is provided with the non-slip mat 21;

As shown in fig. 4, the telescopic support further comprises telescopic rods 22, wherein the telescopic rods 22 are respectively arranged at four corners of the bottom end of the supporting plate 4, and the bottom ends of the four groups of telescopic rods 22 are connected with the top end of the bottom plate 1;

As shown in fig. 3, the structure further comprises a reinforcing plate 23, wherein the reinforcing plate 23 is arranged at one end of the upright post 6, and the top end of the reinforcing plate 23 is connected with the bottom end of the connecting plate 7.

In this embodiment, when the produced tiles are transported, the first motor 15 is started by the staff through the controller 2, thereby the first guide rollers 13 of the plurality of groups are mutually matched to drive the first conveyor belt 14 to rotate, thereby the tiles placed on the first conveyor belt 14 are directionally transported, the staff stretches through the electric hydraulic cylinders 9 of the operation B of the controller 2, thereby the lifting plate 10 drives the electric suction cups 11 to move downwards, the electric suction cups 11 are started, the electric suction cups 11 are made to adsorb the tiles on the first transport mechanism, then the electric hydraulic cylinders 9 of the operation B are shortened, the electric rotary table 5 rotates by one hundred eighty degrees, thereby the electric suction cups 11 drive the adsorbed tiles to be transferred to the right above the supporting plate 4, then the electric hydraulic cylinders 9 of the operation B stretch, thereby the lifting plate 10 drives the adsorbed tiles to be placed above the anti-slip pads 21 through the electric suction cups 11, the stacking of the tiles is completed, the electric hydraulic cylinders 3 of the staff operate the operation A, thereby the supporting plate 4 drives the stacked tiles to be lowered, when the heights of the supporting plate 4 are lower than the heights of the two groups of the electric hydraulic cylinders 9 of the electric suction cups 11, the stacked tiles are placed on the second conveyor belt 19 of the two groups of the guide rollers are made to be mutually matched, and the second conveyor belts are made to be mutually matched to transport the second conveyor belts 19, and the two groups of the stacked tiles are made to be well stacked, and the second conveyor belts are made to be mutually matched to be stacked, and the two 20.

The controller 2, the electric hydraulic cylinder A3, the electric turntable 5, the electric hydraulic cylinder B9, the electric sucking disc 11, the motor I15 and the motor II 20 of the ceramic tile stacking transfer machine are purchased in the market, and can be installed and operated by a person skilled in the art according to the attached use instruction without creative labor of the person skilled in the art.

The foregoing is merely a preferred embodiment of the present utility model, and it should be noted that it will be apparent to those skilled in the art that modifications and variations can be made without departing from the technical principles of the present utility model, and these modifications and variations should also be regarded as the scope of the utility model.

Claims (4)

1. The ceramic tile stacking and transferring machine comprises a bottom plate (1), a first conveying mechanism and a second conveying mechanism, wherein the first conveying mechanism and the second conveying mechanism are all arranged at the top end of the bottom plate (1), and the ceramic tile stacking and transferring machine is characterized by further comprising a controller (2), an A electric hydraulic cylinder (3), a supporting plate (4) and a stacking mechanism, wherein the controller (2), the A electric hydraulic cylinder (3) and the stacking mechanism are all arranged at the top end of the bottom plate (1), the supporting plate (4) is arranged at the top moving end of the A electric hydraulic cylinder (3), and the first conveying mechanism, the second conveying mechanism, the stacking mechanism and the A electric hydraulic cylinder (3) are all electrically connected with the controller (2);

the stacking mechanism comprises an electric rotating disc (5), a stand column (6), a connecting plate (7), a support plate (8), a B electric hydraulic cylinder (9), a lifting plate (10) and an electric sucking disc (11), wherein the electric rotating disc (5) is installed at the top end of the bottom plate (1), the stand column (6) is arranged at the top end of the electric rotating disc (5), the connecting plate (7) is arranged at the left end of the stand column (6), the support plate (8) is arranged at the left end of the connecting plate (7), the B electric hydraulic cylinder (9) is installed at the top end of the support plate (8), the bottom moving end of the B electric hydraulic cylinder (9) extends to the lower part of the support plate (8) and is connected with the top end of the lifting plate (10), the electric sucking disc (11) is arranged at the bottom end of the lifting plate (10), and the electric rotating disc (5), the B electric hydraulic cylinder (9) and the electric sucking disc (11) are electrically connected with the controller (2).

The first conveying mechanism comprises a conveying frame (12), a first guide roller (13), a first conveying belt (14), a first motor (15) and supporting legs (16), the supporting legs (16) are respectively arranged at four corners of the bottom end of the conveying frame (12), the bottom ends of the four groups of supporting legs (16) are all connected with the top end of a bottom plate (1), a plurality of groups of first guide rollers (13) are rotatably arranged on the conveying frame (12), a plurality of groups of first guide rollers (13) are driven by the first conveying belt (14), the first motor (15) is arranged at the left end of the conveying frame (12), the output end of the first motor (15) is connected with the left end of the group of first guide rollers (13), and the first motor (15) is electrically connected with the controller (2);

The second conveying mechanism comprises a vertical plate (17), a second guide roller (18), a second conveying belt (19) and a second motor (20), wherein the two groups of vertical plates (17) are all arranged at the top end of the bottom plate (1), a plurality of groups of second guide rollers (18) are rotatably arranged between the two groups of vertical plates (17), two groups of annular grooves are formed in each group of second guide rollers (18), a group of second conveying belts (19) are respectively sleeved in the annular grooves parallel to each other in the plurality of groups of second guide rollers (18), the second motor (20) is arranged at the outer end of the group of vertical plates (17), the output end of the second motor (20) is connected with the right end of the group of second guide rollers (18), and an A electric hydraulic cylinder (3) and a supporting plate (4) are arranged between the two groups of second conveying belts (19), and the second motor (20) is electrically connected with the controller (2).

2. A tile laminate handler as claimed in claim 1, further comprising a non-slip pad (21), the top end of the support plate (4) being provided with the non-slip pad (21).

3. The tile stacking transfer machine according to claim 1, further comprising telescopic rods (22), wherein the telescopic rods (22) are respectively arranged at four corners of the bottom end of the supporting plate (4), and the bottoms of the four groups of telescopic rods (22) are connected with the top end of the bottom plate (1).

4. A tile laminate handler as claimed in claim 1, further comprising a reinforcing plate (23), the reinforcing plate (23) being mounted at one end of the upright (6), the top end of the reinforcing plate (23) being connected to the bottom end of the connecting plate (7).