CN117841822B - Device is stacked to equidistant fragment of brick of arranging of ceramic tile - Google Patents

Abstract

The invention relates to the technical field of tile paving, in particular to a tile stacking device with tiles arranged at equal intervals, which comprises: the storage box body is rotatably provided with wheels for driving the storage box body to do linear motion; the arc-shaped parts are provided with a plurality of groups and form a driving belt wheel, and the arc-shaped parts are connected with the rotating shafts of the wheels through a transmission structure; the lifting table is arranged on the stagnation accommodating box body, two groups of limiting plates are symmetrically arranged on the lifting table, and the two groups of limiting plates are matched to limit the ceramic tile; the follow-up assembly is arranged on the stagnation-accommodating box body and connected with the arc-shaped piece and the limiting plate, and when the two groups of limiting plates move away from each other, the radius of the driving belt wheel can be increased by the follow-up assembly; the jacking component is arranged in the stagnation-accommodating box body and connected with the lifting table, and can drive the lifting table to move upwards relative to the stagnation-accommodating box body when the stagnation-accommodating box body moves linearly, so that portability is improved.

Description

Device is stacked to equidistant fragment of brick of arranging of ceramic tile

Technical Field

The invention relates to the technical field of tile paving, in particular to a tile stacking device for equidistant tile arrangement.

Background

Ceramic tiles are a common building material, which is formed by molding, drying and firing clay and other raw materials, and are commonly used for decoration of floors and wall surfaces. Ceramic tiles can be classified into porcelain tiles, glazed tiles, full glazed tiles, and the like according to different compositions and processes.

In practical application, if the tiles are paved on the ground, a paving person needs to move the tiles to a paving place in a reciprocating manner, so that the paving efficiency of the tiles is reduced.

Therefore, in the prior art, an automatic tile conveying device is developed, which can follow the action of a paving person to reduce the labor intensity of the paving person, but the device also has a certain problem, mainly in that the displacement amount of each movement of the device needs to be controlled manually, and when the specification and the model of the tile change, the displacement amount of the device needs to be controlled to change, so that the operation difficulty of the device is high, and the device is not convenient to use.

Disclosure of Invention

The invention aims to provide a brick stacking device with tiles arranged at equal intervals, so as to solve the problems in the prior art.

In order to achieve the above purpose, the present invention provides the following technical solutions:

A tile stacking apparatus for equally spaced tiles comprising:

The storage box body is rotatably provided with wheels for driving the storage box body to do linear motion;

the arc-shaped parts are provided with a plurality of groups and form a driving belt wheel, and the arc-shaped parts are connected with the rotating shafts of the wheels through a transmission structure;

the lifting table is arranged on the stagnation accommodating box body, two groups of limiting plates are symmetrically arranged on the lifting table, and the two groups of limiting plates are matched to limit the ceramic tile;

The follow-up assembly is arranged on the stagnation-accommodating box body and connected with the arc-shaped piece and the limiting plate, and when the two groups of limiting plates move away from each other, the radius of the driving belt wheel can be increased by the follow-up assembly;

the jacking component is arranged in the stagnation-accommodating box body and connected with the lifting table, and can drive the lifting table to move upwards relative to the stagnation-accommodating box body when the stagnation-accommodating box body moves linearly.

As a further scheme of the invention: the transmission structure comprises two tensioning wheels which are arranged on the hysteresis box body and form a triangle structure with the driving belt wheel, a first belt is sleeved between the driving belt wheel and the two tensioning wheels, and one of the tensioning wheels is connected with a rotating shaft of the wheel through a second belt;

the transmission structure also comprises an energy storage sleeve member which is arranged on the stagnation-accommodating box body and connected with the other tensioning wheel.

As still further aspects of the invention: the energy storage suite comprises a side plate fixedly arranged on the stagnation-accommodating box body, a sliding groove is formed in the side plate along the length direction of the side plate, and a third sliding block connected with the tensioning wheel rotating shaft is arranged in the sliding groove in a sliding manner;

the energy storage external member is still including setting up in the sliding tray and connect No. two springs of No. three sliders.

As still further aspects of the invention: the lifting platform is provided with a second chute and a bearing plate, the bearing plate extends into the second chute and is in sliding connection with a transverse shaft arranged in the second chute, and the bearing plate is connected with the limiting plate;

And a first spring is sleeved on the transverse shaft, one end of the first spring is connected with the inner wall of the second sliding groove, and the other end of the first spring is connected with the bearing plate.

As still further aspects of the invention: the follow-up assembly comprises two first sliding grooves arranged on the side part of the stagnation-accommodating box body, a first sliding block is slidably arranged in the first sliding grooves, and a follow-up shaft which is slidably connected with the bearing plate is fixed on one side of the first sliding block;

The side part of the stagnation-accommodating box body is provided with a lifting plate, the lifting plate is provided with a third sliding groove, and the third sliding groove is in sliding connection with a second sliding block arranged on the stagnation-accommodating box body;

The lifting plate is also provided with a second inclined groove body, and a convex shaft arranged on the other side of the first sliding block can slide in the second inclined groove body;

The follow-up assembly further comprises a supporting structure for connecting the lifting plate and the arc-shaped piece.

As still further aspects of the invention: the supporting structure comprises a plurality of teeth arranged on the lifting plate and gears rotatably arranged on the side parts of the stagnation-accommodating box body, the gears are meshed with the teeth, and a rotating shaft of the gears is connected with a connecting sleeve arranged on the second sliding block.

As still further aspects of the invention: the connecting sleeve comprises a transverse moving sleeve which is sleeved on the gear rotating shaft in a sliding manner, and the transverse moving sleeve is sleeved with a guide piece connected with the second sliding block in a sliding manner;

A spiral groove is formed in a rotating shaft of the gear, and an embedded shaft arranged in the transverse moving sleeve can slide in the spiral groove;

The lateral sliding sleeve is provided with a limiting block which is in sliding fit with a limiting groove arranged in the guide piece.

As still further aspects of the invention: the side part of the stagnation-accommodating box body is fixedly provided with a second driving device, a plurality of groups of rotary sleeve plates are arranged on an output shaft of the second driving device at equal intervals in circumference, a telescopic plate connected with the arc-shaped piece is arranged in the rotary sleeve plates in a sliding mode, a supporting rod is rotatably arranged on the telescopic plate, and one end, far away from the telescopic plate, of the supporting rod is rotatably connected with the transverse moving sleeve.

As still further aspects of the invention: the jacking assembly comprises a bidirectional screw rod rotatably installed in the stagnation-accommodating box body, the bidirectional screw rod is connected with a first driving device fixed on the stagnation-accommodating box body, two threaded sleeves in threaded connection with the bidirectional screw rod are symmetrically arranged on the bidirectional screw rod, two cross rods are symmetrically arranged on the threaded sleeves, and the cross rods are connected with the lifting table through grooved pulley sleeve members.

As still further aspects of the invention: the sheave external member comprises a pulley rotatably arranged at one end of the cross rod far away from the threaded sleeve and a first inclined groove body arranged on the inner wall of the lifting platform, and the pulley is matched with the first inclined groove body;

two guide rods are further arranged in the stagnation accommodating box body, and the guide rods are in sliding connection with the cross rods.

Compared with the prior art, the invention has the beneficial effects that:

The radius of the driving belt wheel can be changed along with the length change of the ceramic tile under the condition that the number of turns of the second driving device is constant every time, so that wheels can rotate the number of turns matched with the driving belt wheel when the device transports ceramic tiles of different specifications, the moving length of the device is matched with the paving length of the ceramic tile, the portability of the ceramic tile paving is improved, and the operation difficulty of the device is effectively reduced by adopting an automatic matching mode.

Drawings

Fig. 1 is a schematic view of an embodiment of a stacking apparatus for tiles arranged at equal intervals.

Fig. 2 is a schematic view of another angle of an embodiment of a tile stacking apparatus with equally spaced tiles.

Fig. 3 is an enlarged view of the structure at a in fig. 1.

Fig. 4 is an exploded view of the jacking assembly of one embodiment of the tile stacking apparatus with equally spaced tiles.

Fig. 5 is a schematic structural view of a lifting table and a limiting plate in an embodiment of a tile stacking apparatus with tiles arranged at equal intervals.

Fig. 6 is a schematic view of a partial structure of a follower assembly in one embodiment of a tile stacking apparatus with equally spaced tiles.

Fig. 7 is a partial exploded view of the follower assembly of one embodiment of the tile stacking device with equally spaced tiles.

Fig. 8 is a schematic view of a driving structure of an embodiment of a tile stacking apparatus with tiles arranged at equal intervals.

Fig. 9 is an enlarged view of the structure at B in fig. 8.

In the figure: 1. a stagnation-accommodating box body; 101. a first chute; 2. a wheel; 3. a lifting table; 301. a second chute; 302. a first inclined groove body; 4. a first driving device; 5. a two-way screw rod; 6. a threaded sleeve; 7. a cross bar; 8. a pulley; 9. a guide rod; 10. a horizontal axis; 11. a first spring; 12. a receiving plate; 13. a limiting plate; 14. a follower shaft; 15. a first sliding block; 16. a protruding shaft; 17. a lifting plate; 1701. a second inclined groove body; 1702. teeth; 1703. a third chute; 18. a gear; 1801. a spiral groove; 19. traversing the sleeve; 1901. a fitting shaft; 1902. a limiting block; 20. a guide member; 2001. a limit groove; 21. a second slide block; 22. rotating the sleeve plate; 23. a telescoping plate; 24. an arc-shaped member; 25. a first belt; 26. a second belt; 27. a side plate; 28. a tensioning wheel; 29. a second spring; 30. a third slider; 31. a support rod; 32. and a second driving device.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

In addition, an element in the present disclosure may be referred to as being "fixed" or "disposed" on another element or being directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only and are not meant to be the only embodiment.

Referring to fig. 1 to 9, in an embodiment of the present invention, a brick stacking device for equidistant arrangement of tiles includes: the holding stagnates box 1, arc 24, elevating platform 3, follower assembly, jacking subassembly for under the constant circumstances of number of turns at every turn of No. two drive arrangement 32, the radius of driving pulley can change along with the length variation of ceramic tile, so that when the device transportation different specification ceramic tile, wheel 2 can rotate the number of turns that matches with it, and make the removal length of device and the length phase-match of laying of ceramic tile, and the portability when improving the ceramic tile and laying, and adopt automatic matching's mode, effectively reduced the operation degree of difficulty of device.

The method comprises the following steps: the hysteresis container 1 is rotatably provided with wheels 2 for driving the hysteresis container to do linear motion;

The arc-shaped pieces 24 are provided with a plurality of groups and form driving pulleys, the arc-shaped pieces 24 are connected with the rotating shafts of the wheels 2 through a transmission structure, the transmission structure comprises two tensioning wheels 28 which are arranged on the stagnation-accommodating box body 1 and form a triangle structure with the driving pulleys, a first belt 25 is sleeved between the driving pulleys and the two tensioning wheels 28, and one tensioning wheel 28 is connected with the rotating shafts of the wheels 2 through a second belt 26;

The transmission structure further comprises an energy storage sleeve piece which is arranged on the stagnation-accommodating box body 1 and connected with the other tension wheel 28, the energy storage sleeve piece comprises a side plate 27 fixedly arranged on the stagnation-accommodating box body 1, a sliding groove is formed in the length direction of the side plate 27, and a third sliding block 30 which is connected with the rotation shaft of the tension wheel 28 is arranged in the sliding groove in a sliding manner;

The energy storage sleeve piece further comprises a second spring 29 which is arranged in the sliding groove and connected with the third sliding block 30;

The side part of the stagnation-accommodating box body 1 is fixedly provided with a second driving device 32, a plurality of groups of rotating sleeve plates 22 are circumferentially equidistantly arranged on an output shaft of the second driving device 32, a telescopic plate 23 connected with the arc-shaped piece 24 is slidably arranged on the rotating sleeve plates 22, a supporting rod 31 is rotatably arranged on the telescopic plate 23, and one end, far away from the telescopic plate 23, of the supporting rod 31 is rotatably connected with the follow-up assembly;

the lifting table 3 is arranged on the stagnation-accommodating box body 1, two groups of limiting plates 13 are symmetrically arranged on the lifting table 3, the two groups of limiting plates 13 are matched and can limit ceramic tiles, a second sliding chute 301 and a bearing plate 12 are arranged on the lifting table 3, the bearing plate 12 extends into the second sliding chute 301 and is in sliding connection with a transverse shaft 10 arranged in the second sliding chute 301, and the bearing plate 12 is connected with the limiting plates 13;

The transverse shaft 10 is sleeved with a first spring 11, one end of the first spring 11 is connected with the inner wall of the second chute 301, and the other end of the first spring is connected with the bearing plate 12.

When the ceramic tile feeding device is used, the second driving device 32 is controlled to work, the output shaft of the second driving device 32 drives the arc-shaped pieces 24 to move circularly through the rotary sleeve plate 22 and the telescopic plate 23, so that a driving belt wheel formed by the arc-shaped pieces 24 rotates, and the driving belt wheel drives the wheel 2 to rotate through the first belt 25 and the second belt 26, so that the storage box body 1 can be driven to do linear motion, and ceramic tiles can be fed.

When the length of the ceramic tile placed between the two limiting plates 13 is changed, the distance between the two limiting plates 13 is also changed, and the circumference radius of the driving pulley is changed under the action of the follow-up assembly, so that the number of turns rotated by the wheel 2 is changed under the condition that the output shaft of the second driving device 32 rotates for a preset number of turns, the displacement length of the stagnation box 1 can be matched with the length of the ceramic tile, and the operation difficulty of the device is reduced.

Further, when the radius of the driving pulley is increased or decreased, the third slider 30 will act along with it, but under the action of the second spring 29, the first belt 25 can be kept in a tight state all the time, so that when the radius of the driving pulley is changed, it can drive the wheel 2 to rotate through the first belt 25 and the second belt 26 all the time.

In the present application, the number of turns of the second driving device 32 per operation is constant, and the number of turns of the wheel 2 is different by changing the transmission ratio, thereby matching the length of the tile.

Through the above-mentioned setting for under the constant circumstances of number of turns at every turn of No. two drive arrangement 32, the radius of driving pulley can change along with the length variation of ceramic tile, so that when the device transportation different specification's ceramic tile, wheel 2 can rotate the number of turns that matches with it, and make the removal length of device and the length phase-match of laying of ceramic tile, and improve the portability when ceramic tile lays, and adopt the mode of automatic matching, effectively reduced the operation degree of difficulty of device.

Referring to fig. 3, 6 and 7-9, the follower assembly is disposed on the hysteresis box 1 and connected to the arc-shaped member 24 and the limiting plate 13, and when the two groups of limiting plates 13 move away from each other, the follower assembly can increase the radius of the driving pulley;

The follow-up assembly comprises two first sliding grooves 101 arranged on the side part of the stagnation-accommodating box body 1, a first sliding block 15 is slidably arranged in the first sliding grooves 101, and a follow-up shaft 14 which is slidably connected with the bearing plate 12 is fixed on one side of the first sliding block 15;

The side part of the stagnation accommodating box body 1 is provided with a lifting plate 17, the lifting plate 17 is provided with a third sliding chute 1703, and the third sliding chute 1703 is in sliding connection with a second sliding block 21 arranged on the stagnation accommodating box body 1;

The lifting plate 17 is also provided with a second inclined groove 1701, and the convex shaft 16 arranged on the other side of the first sliding block 15 can slide in the second inclined groove 1701;

The following assembly further comprises a supporting structure for connecting the lifting plate 17 and the arc-shaped piece 24, the supporting structure comprises a plurality of teeth 1702 arranged on the lifting plate 17 and a gear 18 rotatably arranged on the side part of the stagnation-accommodating box body 1, the gear 18 is meshed with the teeth 1702, a rotating shaft of the gear 18 is connected with a connecting sleeve piece arranged on the second sliding block 21, the connecting sleeve piece comprises a transverse moving sleeve 19 which is sleeved on the rotating shaft of the gear 18 in a sliding manner, and the transverse moving sleeve 19 is sleeved with a guide piece 20 connected with the second sliding block 21 in a sliding manner;

A spiral groove 1801 is provided on the rotation shaft of the gear 18, and a fitting shaft 1901 provided in the traverse sleeve 19 is slidable in the spiral groove 1801;

A stopper 1902 is formed on the traversing sleeve 19, and the stopper 1902 is slidably engaged with a stopper groove 2001 provided in the guide member 20.

When a tile with a longer length is placed between the two limiting plates 13, the distance between the two limiting plates 13 and each other is increased, at this time, the two groups of protruding shafts 16 move away from each other, under the cooperation with the second inclined groove 1701, the lifting plate 17 moves downwards, the gear 18 and the teeth 1702 are in a meshed state, when the lifting plate 17 moves downwards, the gear 18 can rotate and drive the spiral groove 1801 to rotate, the spiral groove 1801 is in sliding fit with the embedded shaft 1901, at the same time, under the cooperation of the limiting block 1902 and the limiting groove 2001, the traversing sleeve 19 can move away from the holding box 1 when the traversing sleeve 19 pushes the telescopic plate 23 to move away from the rotating sleeve plate 22 through the supporting rod 31, and the arc pieces 24 move away from each other, so that the radius of the driving pulley is increased, at this time, in the process of rotating the second driving device 32 for a constant number of turns, the number of turns of the wheel 2 can be made to rotate, and the displacement of the holding box 1 is matched with the length of the tile automatically.

Through the arrangement, when the specification of the ceramic tile is changed, the radius of the driving belt wheel formed by the plurality of arc-shaped pieces 24 is also changed, and the stroke amount of the wheels 2 driving the motion of the stagnation accommodating box body 1 is changed, so that the automatic matching of the ceramic tile length and the motion length of the stagnation accommodating box body 1 is realized.

Referring to fig. 2 and 4, the lifting assembly is disposed in the stagnation housing 1 and connected to the lifting platform 3, and the lifting assembly can drive the lifting platform 3 to move upwards relative to the stagnation housing 1 when the stagnation housing 1 moves linearly;

The jacking assembly comprises a bidirectional screw rod 5 rotatably installed in the stagnation-accommodating box body 1, the bidirectional screw rod 5 is connected with a first driving device 4 fixed on the stagnation-accommodating box body 1, two threaded sleeves 6 in threaded connection with the bidirectional screw rod 5 are symmetrically arranged on the bidirectional screw rod 5, two cross rods 7 are symmetrically arranged on the threaded sleeves 6, and the cross rods 7 are connected with the lifting table 3 through a grooved pulley sleeve;

The sheave assembly comprises a pulley 8 rotatably installed at one end of the cross rod 7, which is far away from the threaded sleeve 6, and a first inclined groove body 302 arranged on the inner wall of the lifting platform 3, wherein the pulley 8 is matched with the first inclined groove body 302;

two guide rods 9 are further installed in the stagnation accommodating box body 1, and the guide rods 9 are in sliding connection with the cross rods 7.

When in use, the stagnation-accommodating box body 1 performs stepping motion, and when the stagnation-accommodating box body 1 moves, the first driving device 4 works to drive the bidirectional screw rod 5 to rotate, at the moment, the two threaded sleeves 6 arranged on the bidirectional screw rod 5 move close to each other, and under the cooperation of the pulley 8 and the first inclined groove body 302, the lifting platform 3 moves upwards, and the main purpose in the process is as follows: make at every turn when taking the ceramic tile, the high invariable of ceramic tile to can install the manipulator of automatic uninstallation ceramic tile additional on this device, the high invariable of ceramic tile is also favorable to manual ceramic tile of taking simultaneously.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (6)

1. A device for stacking tiles in equidistant arrangement, comprising:

The device comprises a stagnation accommodating box body (1), wherein wheels (2) for driving the stagnation accommodating box body (1) to do linear motion are rotatably arranged on the stagnation accommodating box body (1);

The arc-shaped pieces (24) are provided with a plurality of groups and form driving pulleys, and the arc-shaped pieces (24) are connected with the rotating shafts of the wheels (2) through transmission structures;

The lifting table (3) is arranged on the stagnation-accommodating box body (1), two groups of limiting plates (13) are symmetrically arranged on the lifting table (3), the two groups of limiting plates (13) are matched and can limit ceramic tiles, a second sliding chute (301) and a bearing plate (12) are arranged on the lifting table (3), the bearing plate (12) extends into the second sliding chute (301), and the bearing plate (12) is connected with the limiting plates (13);

the follow-up assembly is arranged on the stagnation-accommodating box body (1) and connected with the arc-shaped piece (24) and the limiting plates (13), and when the two groups of limiting plates (13) move away from each other, the radius of the driving belt wheel can be increased by the follow-up assembly;

The follow-up assembly comprises two first sliding grooves (101) arranged on the side part of the stagnation-accommodating box body (1), a first sliding block (15) is slidably arranged in the first sliding grooves (101), and a follow-up shaft (14) which is slidably connected with the bearing plate (12) is fixed on one side of the first sliding block (15);

The side part of the stagnation-accommodating box body (1) is provided with a lifting plate (17), the lifting plate (17) is provided with a third sliding groove (1703), and the third sliding groove (1703) is in sliding connection with a second sliding block (21) arranged on the stagnation-accommodating box body (1);

A second inclined groove body (1701) is further arranged on the lifting plate (17), and a protruding shaft (16) arranged on the other side of the first sliding block (15) can slide in the second inclined groove body (1701);

The follower assembly further comprises a support structure connecting the lifting plate (17) and the arc-shaped member (24);

The supporting structure comprises a plurality of teeth (1702) arranged on the lifting plate (17) and gears (18) rotatably arranged on the side parts of the stagnation-accommodating box body (1), the gears (18) are meshed with the teeth (1702), and the rotating shaft of the gears (18) is connected with a connecting sleeve piece arranged on the second sliding block (21);

the connecting sleeve comprises a traversing sleeve (19) which is sleeved on the rotating shaft of the gear (18) in a sliding way, and the traversing sleeve (19) is sleeved with a guide piece (20) connected with the second sliding block (21) in a sliding way;

a spiral groove (1801) is arranged on the rotating shaft of the gear (18), and a jogged shaft (1901) arranged in the transverse moving sleeve (19) can slide in the spiral groove (1801);

A limiting block (1902) is formed on the transverse moving sleeve (19), and the limiting block (1902) is in sliding fit with a limiting groove (2001) arranged in the guide piece (20);

The side part of the stagnation-accommodating box body (1) is fixedly provided with a second driving device (32), a plurality of groups of rotating sleeve plates (22) are circumferentially equidistantly arranged on an output shaft of the second driving device (32), telescopic plates (23) connected with the arc-shaped pieces (24) are slidably arranged in the rotating sleeve plates (22), support rods (31) are rotatably arranged on the telescopic plates (23), and one ends, far away from the telescopic plates (23), of the support rods (31) are rotatably connected with the transverse moving sleeve (19);

The jacking component is arranged in the stagnation-containing box body (1) and is connected with the lifting table (3), and the jacking component can drive the lifting table (3) to move upwards relative to the stagnation-containing box body (1) when the stagnation-containing box body (1) moves linearly.

2. The tile stacking device according to claim 1, wherein the transmission structure comprises two tensioning wheels (28) which are arranged on the stagnation-accommodating box body (1) and form a triangle structure with the driving belt wheel, a first belt (25) is sleeved between the driving belt wheel and the two tensioning wheels (28), and one tensioning wheel (28) is connected with a rotating shaft of the wheel (2) through a second belt (26);

The transmission structure also comprises an energy storage sleeve member which is arranged on the stagnation-accommodating box body (1) and is connected with the other tensioning wheel (28).

3. The tile stacking device according to claim 2, wherein the energy storage kit comprises a side plate (27) fixedly mounted on the storage box body (1), a sliding groove is formed on the side plate (27) along the length direction of the side plate, and a third sliding block (30) connected with the rotating shaft of the tensioning wheel (28) is slidably mounted in the sliding groove;

The energy storage external member still includes setting up in the sliding tray and connect No. two springs (29) of No. three slider (30).

4. The tile stacking device according to claim 1, wherein the receiving plate (12) is slidably connected to a transverse shaft (10) provided in the second chute (301);

A first spring (11) is sleeved on the transverse shaft (10), one end of the first spring (11) is connected with the inner wall of the second sliding groove (301), and the other end of the first spring is connected with the bearing plate (12).

5. The tile stacking device according to claim 1, wherein the jacking assembly comprises a bidirectional screw rod (5) rotatably installed in the storage box body (1), the bidirectional screw rod (5) is connected with a first driving device (4) fixed on the storage box body (1), two threaded sleeves (6) in threaded connection with the bidirectional screw rod (5) are symmetrically arranged on the bidirectional screw rod (5), two cross rods (7) are symmetrically arranged on the threaded sleeves (6), and the cross rods (7) are connected with the lifting table (3) through grooved pulley assemblies.

6. The tile stacking device according to claim 5, wherein the grooved pulley sleeve comprises a pulley (8) rotatably mounted at one end of the cross rod (7) far away from the threaded sleeve (6) and a first inclined groove body (302) arranged on the inner wall of the lifting platform (3), and the pulley (8) is matched with the first inclined groove body (302);

Two guide rods (9) are further arranged in the stagnation-accommodating box body (1), and the guide rods (9) are in sliding connection with the cross rods (7).