CN221321659U - Indoor ground ceramic tile paving structure - Google Patents

Abstract

The utility model discloses an indoor ground tile paving structure, which relates to the technical field of ground tile paving and comprises a support vertical rod arranged on one side of a support bottom plate, and further comprises a top plate, wherein a sliding opening is formed in the middle position of the upper surface of the top plate in a penetrating manner, a movable block is arranged in the sliding opening, a telescopic rod is arranged on the upper surface of the movable block in a penetrating manner, the lower end of the telescopic rod is fixedly connected with a first sucker, the outer side surface of the telescopic rod is fixedly connected with four groups of connecting rods close to the bottom end, the outer ends of the four groups of connecting rods are fixedly connected with second suckers, the top plate is fixedly connected to the upper end of the support vertical rod, and the top plate and the support bottom plate are arranged in parallel; the utility model has the advantages that: the labor intensity of workers is reduced, the tile paving efficiency is improved, the convenient auxiliary adjusting function is realized, the transferring time of the tiles is shortened, and the tile paving efficiency is further improved.

Description

Indoor ground ceramic tile paving structure

Technical Field

The utility model relates to the technical field of floor tile paving, in particular to an indoor floor tile paving structure.

Background

The ceramic tile is made of refractory metal oxide and semi-metal oxide through grinding, mixing, pressing, glazing and sintering, and is one kind of ceramic or stone wall or floor decorating material with acid and alkali resistance, and its material is mixed with clay, quartz sand, etc.

However, in the prior art, the existing indoor floor tiles are usually manually carried and paved, and the weight of the tiles is relatively heavy, so that the time and the labor are relatively wasted, and the paving efficiency of the floor tiles is greatly reduced.

Disclosure of utility model

The technical problem to be solved by the utility model is to provide an indoor floor tile paving structure, wherein the existing indoor floor tiles are usually manually carried and paved, and the paving efficiency of the floor tiles is greatly reduced due to the fact that the weight of the tiles is relatively heavy, time and labor are relatively wasted.

In order to solve the technical problems, the technical scheme of the utility model is that the indoor floor tile paving structure comprises a support vertical rod arranged on one side of a support bottom plate, and further comprises a top plate, wherein a sliding opening is formed in the middle of the upper surface of the top plate in a penetrating manner, a moving block is arranged in the sliding opening, a telescopic rod is arranged in the upper surface of the moving block in a penetrating manner, the lower end of the telescopic rod is fixedly connected with a first sucker, the outer side surface of the telescopic rod is close to the bottom end and is fixedly connected with four groups of connecting rods, and the outer ends of the four groups of connecting rods are fixedly connected with a second sucker.

As a further aspect of the utility model: the roof fixed connection is in the upper end of supporting the montant, and roof and supporting baseplate parallel arrangement, the lower surface of supporting baseplate is close to the equal movable mounting of corner position and has the wheel that rolls.

As a further aspect of the utility model: the sliding blocks are fixedly connected to the two sides of the moving block, sliding grooves are formed in the two inner side walls of the sliding opening, and the two groups of sliding blocks are located in the two groups of sliding grooves respectively.

As a further aspect of the utility model: the top plate is close to one end fixed mounting who supports the montant has first motor, the screw shaft is installed to the output of first motor, and first screw has been seted up in running through on one side of slider, and slider passes through first screw and screw shaft threaded connection.

As a further aspect of the utility model: the upper surface fixed mounting of movable block has electronic jar, and telescopic link movable mounting is in the output of electronic jar, first sucking disc passes through telescopic link movable mounting in the below of roof, four groups second sucking disc and four groups connecting rods all set up about the telescopic link symmetry.

As a further aspect of the utility model: the middle positions of two sides of the supporting bottom plate are respectively and fixedly provided with a first vertical groove shell and a second vertical groove shell, the upper end of the first vertical groove shell is fixedly provided with a second motor, the output end of the second motor is provided with a main screw shaft, the second vertical groove shell is rotatably provided with a secondary screw shaft, and the main screw shaft and the secondary screw shaft are mutually parallel.

As a further aspect of the utility model: the outer bottom of the main screw shaft is fixedly sleeved with a main gear, the outer bottom of the auxiliary screw shaft is fixedly sleeved with an auxiliary gear, the lower side of the supporting bottom plate is provided with a saw-tooth belt, and the main gear and the auxiliary gear are both meshed with the saw-tooth belt.

As a further aspect of the utility model: the upper side of supporting baseplate is provided with the loading board, the equal fixedly connected with lifter plate in both sides intermediate position of loading board, two sets of the upper surface of lifter plate all runs through and has seted up the second screw, and two sets of lifter plates pass through second screw and main screw axle and follow screw axle threaded connection respectively.

As a further aspect of the utility model: the upper surface of supporting baseplate is close to the equal fixedly connected with spacing montant of corner position, and the upper surface of loading board is close to the corner position and has all run through and has seted up the slide opening, and the loading board passes through four sets of slide openings and four sets of spacing montants sliding connection.

Compared with the prior art, the utility model has the following advantages: the first suckers and the four groups of second suckers are attached to the uppermost ceramic tile on the upper side of the bearing plate together, the first motor at one end of the top plate is started again, the threaded shaft is driven to rotate, the sliding block is driven to move along the inner side of the sliding groove under the cooperation of the first screw hole, the moving block is driven to slide along the sliding opening until the ceramic tile is far away from the position right above the supporting bottom plate, then the electric cylinder on the upper surface of the moving block is started, the telescopic rod is driven to extend, and accordingly the first suckers and the four groups of second suckers are driven to move downwards together until the ceramic tile is attached to the ground, the function of automatically paving the ceramic tile is achieved, manual paving of the ceramic tile is not needed, labor intensity of workers is reduced, and ceramic tile paving efficiency is improved.

Through the second motor of starting first perpendicular cell-shell upper end, drive main screw shaft and main gear and rotate together, thereby it is rotatory to drive the follow screw shaft on the second perpendicular cell-shell under the cooperation of follow gear and sawtooth area, and then drive the loading board through four sets of limit montants of two sets of lifter plates cooperation and four sets of slide holes and upwards move, until the loading board carries out the lifting to a plurality of ceramic tiles, so that the quick actuation of ceramic tile is in first sucking disc and second sucking disc downside, convenient auxiliary regulation function has been reduced the transfer time of ceramic tile, further the paving efficiency of ceramic tile has been improved.

Drawings

FIG. 1 is a schematic view of an indoor floor tile paving structure according to an embodiment of the present utility model;

FIG. 2 is a schematic view of a connection structure of a top plate according to an embodiment of the present utility model;

FIG. 3 is a schematic diagram of a connection structure between a first housing and a second housing according to an embodiment of the present utility model;

fig. 4 is a front view of an indoor floor tile laying structure according to an embodiment of the present utility model.

In the figure: 1. a support base plate; 2. a supporting vertical rod; 3. a top plate; 4. a first motor; 5. a threaded shaft; 6. a moving block; 7. a slide block; 8. an electric cylinder; 9. a telescopic rod; 10. a first suction cup; 11. a connecting rod; 12. a second suction cup; 13. a first vertical cell housing; 14. a second vertical cell housing; 15. a second motor; 16. a main screw shaft; 17. a main gear; 18. a slave screw shaft; 19. a slave gear; 20. a toothed belt; 21. a carrying plate; 22. a lifting plate; 23. a limit vertical rod; 24. a slide hole; 25. a sliding port; 26. and rolling the wheel.

Detailed Description

The following describes the embodiments of the present utility model further with reference to the drawings. The description of these embodiments is provided to assist understanding of the present utility model, but is not intended to limit the present utility model. In addition, the technical features of the embodiments of the present utility model described below may be combined with each other as long as they do not collide with each other.

Embodiment 1 please refer to fig. 1-4, an indoor ground tile paving structure, including setting up the support montant 2 in supporting baseplate 1 one side, still include roof 3, the upper surface intermediate position of roof 3 runs through and has seted up slide opening 25, the inside of slide opening 25 is provided with movable block 6, the upper surface of movable block 6 runs through and is provided with telescopic link 9, telescopic link 9's lower extreme fixedly connected with first sucking disc 10, telescopic link 9's lateral surface is close to bottom fixedly connected with four sets of connecting rods 11, the outer end of four sets of connecting rods 11 is all fixedly connected with second sucking disc 12.

The roof 3 fixed connection is in the upper end of supporting montant 2, and roof 3 and supporting baseplate 1 parallel arrangement, and the lower surface of supporting baseplate 1 is close to the equal movable mounting of corner position and has the wheel 26 that rolls.

In this embodiment, the top plate 3 is conveniently arranged in parallel right above the supporting bottom plate 1 by the supporting vertical rods 2.

Both sides of the moving block 6 are fixedly connected with sliding blocks 7, sliding grooves are formed in both inner side walls of the sliding opening 25, and two groups of sliding blocks 7 are respectively positioned in the two groups of sliding grooves.

In this embodiment, the two sets of sliding blocks 7 are matched with the two sets of sliding grooves to facilitate the movement of the moving block 6 in the sliding opening 25.

The one end fixed mounting that roof 3 is close to support montant 2 has first motor 4, and screw shaft 5 is installed to the output of first motor 4, and a screw hole has been seted up in running through one side of slider 7, and slider 7 passes through first screw and screw shaft 5 threaded connection.

In this embodiment, the sliding block 7 is convenient to slide along the sliding groove through the threaded connection of the sliding block 7 and the threaded shaft 5.

The upper surface fixed mounting of movable block 6 has electric cylinder 8, and telescopic link 9 movable mounting is at electric cylinder 8's output, and first sucking disc 10 passes through telescopic link 9 movable mounting in roof 3's below, and four second sucking discs 12 of group and four connecting rods 11 all set up about telescopic link 9 symmetry.

In this embodiment, the first suction cup 10 and the four groups of second suction cups 12 are convenient to lift together through the telescopic rod 9.

Specifically, the first suction disc 10 and the four groups of second suction discs 12 are attached to the uppermost ceramic tile on the upper side of the bearing plate 21 together, the first motor 4 at one end of the top plate 3 is started again, the threaded shaft 5 is driven to rotate, the sliding block 7 is driven to move along the inner side of the sliding groove under the cooperation of the first screw hole, the moving block 6 is driven to slide along the sliding opening 25 until the ceramic tile is far away from the position right above the supporting bottom plate 1, the electric cylinder 8 on the upper surface of the moving block 6 is started, the telescopic rod 9 is driven to extend, and the first suction disc 10 and the four groups of second suction discs 12 are driven to move downwards together until the ceramic tile is attached to the ground, so that the function of automatically paving the ceramic tile is realized, manual paving of the ceramic tile is not needed, the labor intensity of workers is reduced, and the ceramic tile paving efficiency is improved.

In embodiment 2, referring to fig. 1-4, in an indoor floor tile paving structure, a first vertical groove shell 13 and a second vertical groove shell 14 are fixedly installed at middle positions of two sides of a supporting base plate 1 respectively, a second motor 15 is fixedly installed at the upper end of the first vertical groove shell 13, a main screw shaft 16 is installed at the output end of the second motor 15, a secondary screw shaft 18 is rotatably installed on the second vertical groove shell 14, and the main screw shaft 16 and the secondary screw shaft 18 are mutually parallel.

The outside bottom of main screw shaft 16 fixedly cup joints main gear 17, and the outside bottom of follow screw shaft 18 fixedly cup joints from gear 19, and the downside of supporting baseplate 1 is provided with sawtooth belt 20, and main gear 17 and follow gear 19 all mesh with sawtooth belt 20 and install.

In this embodiment, the slave screw shaft 18 is facilitated to rotate with the master screw shaft 16 by the co-operation of the master gear 17 and the slave gear 19 with the toothed belt 20.

The upper side of the supporting bottom plate 1 is provided with a bearing plate 21, the middle positions of two sides of the bearing plate 21 are fixedly connected with lifting plates 22, second screw holes are formed in the upper surfaces of the two groups of lifting plates 22 in a penetrating mode, and the two groups of lifting plates 22 are in threaded connection with the main screw shaft 16 and the auxiliary screw shaft 18 through the second screw holes respectively.

In this embodiment, the two sets of lifting plates 22 are moved along the inside of the first vertical housing 13 and the second vertical housing 14 by the main screw shaft 16 and the sub screw shaft 18 in cooperation with the second screw holes, respectively.

The upper surface of supporting baseplate 1 is close to the equal fixedly connected with spacing montant 23 of corner position, and the upper surface of loading board 21 is close to the corner position and has all run through and has offered slide hole 24, and loading board 21 passes through four sets of slide hole 24 and four sets of spacing montants 23 sliding connection.

In this embodiment, the four sets of limiting posts 23 are matched with the four sets of sliding holes 24 to facilitate the lifting movement of the carrier plate 21.

Specifically, the second motor 15 at the upper end of the first vertical groove shell 13 is started to drive the main screw shaft 16 and the main gear 17 to rotate together, so that the auxiliary screw shaft 18 on the second vertical groove shell 14 is driven to rotate under the cooperation of the auxiliary gear 19 and the sawtooth belt 20, and then the bearing plate 21 is driven to move upwards through the cooperation of the two groups of lifting plates 22 and the four groups of limiting vertical rods 23 and the four groups of sliding holes 24 until the bearing plate 21 lifts a plurality of groups of ceramic tiles, so that the ceramic tiles are quickly attracted to the lower sides of the first sucker 10 and the second sucker 12, a convenient auxiliary adjusting function is provided, the transfer time of the ceramic tiles is shortened, and the paving efficiency of the ceramic tiles is further improved.

The embodiments of the present utility model have been described in detail above with reference to the accompanying drawings, but the present utility model is not limited to the described embodiments. It will be apparent to those skilled in the art that various changes, modifications, substitutions and alterations can be made to these embodiments without departing from the principles and spirit of the utility model, and yet fall within the scope of the utility model.

Claims (9)

1. The utility model provides an indoor ground ceramic tile spreads and pastes structure, includes support montant (2) of setting in supporting baseplate (1) one side, its characterized in that: still include roof (3), slide opening (25) have been run through to the upper surface intermediate position of roof (3), the inside of slide opening (25) is provided with movable block (6), the upper surface of movable block (6) runs through and is provided with telescopic link (9), the lower extreme fixedly connected with first sucking disc (10) of telescopic link (9), the lateral surface of telescopic link (9) is close to four sets of connecting rods (11) of bottom fixedly connected with, four sets of equal fixedly connected with second sucking disc (12) of outer end of connecting rod (11).

2. An indoor floor tile flooring structure as claimed in claim 1, wherein: the top plate (3) is fixedly connected to the upper end of the supporting vertical rod (2), the top plate (3) and the supporting bottom plate (1) are arranged in parallel, and rolling wheels (26) are movably mounted on the lower surface of the supporting bottom plate (1) close to the corner positions.

3. An indoor floor tile flooring structure as claimed in claim 1, wherein: both sides of movable block (6) all fixedly connected with slider (7), the spout has all been seted up to two inside walls of sliding opening (25), and two sets of sliders (7) are located the inside of two sets of spouts respectively.

4. An indoor floor tile flooring structure as claimed in claim 1, wherein: the top plate (3) is close to one end fixed mounting who supports montant (2) has first motor (4), screw shaft (5) are installed to the output of first motor (4), and first screw has been run through to one side of slider (7), and slider (7) pass through first screw and screw shaft (5) threaded connection.

5. An indoor floor tile flooring structure as claimed in claim 1, wherein: the upper surface fixed mounting of movable block (6) has electronic jar (8), and telescopic link (9) movable mounting is in the output of electronic jar (8), first sucking disc (10) are through telescopic link (9) movable mounting in the below of roof (3), four groups second sucking disc (12) and four groups connecting rod (11) all set up with telescopic link (9) symmetry.

6. An indoor floor tile flooring structure as claimed in claim 1, wherein: the utility model discloses a motor, including supporting baseplate (1), first perpendicular cell shell (13) and second perpendicular cell shell (14) are fixed mounting respectively to the both sides intermediate position of supporting baseplate (1), the upper end fixed mounting of first perpendicular cell shell (13) has second motor (15), main screw shaft (16) are installed to the output of second motor (15), rotate on second perpendicular cell shell (14) and install from screw shaft (18), and main screw shaft (16) and from screw shaft (18) are parallel arrangement each other.

7. An indoor floor tile flooring structure as claimed in claim 6, wherein: the outer bottom of the main screw shaft (16) is fixedly sleeved with a main gear (17), the outer bottom of the auxiliary screw shaft (18) is fixedly sleeved with an auxiliary gear (19), the lower side of the supporting bottom plate (1) is provided with a sawtooth belt (20), and the main gear (17) and the auxiliary gear (19) are all meshed with the sawtooth belt (20).

8. An indoor floor tile flooring structure as claimed in claim 1, wherein: the upper side of supporting baseplate (1) is provided with loading board (21), the equal fixedly connected with lifter plate (22) in both sides intermediate position of loading board (21), two sets of the upper surface of lifter plate (22) has all run through and has seted up the second screw, and two sets of lifter plate (22) are respectively through second screw and main lead screw axle (16) and follow lead screw axle (18) threaded connection.

9. An indoor floor tile flooring structure as claimed in claim 1, wherein: limiting vertical rods (23) are fixedly connected to the upper surface of the supporting bottom plate (1) close to the corner positions, sliding holes (24) are formed in the upper surface of the bearing plate (21) close to the corner positions in a penetrating mode, and the bearing plate (21) is in sliding connection with the four groups of limiting vertical rods (23) through the four groups of sliding holes (24).