CN220814359U - Spliced wallboard mounting structure - Google Patents

Abstract

The application relates to a spliced wallboard mounting structure, which belongs to the technical field of wallboards and comprises a first panel and a second panel, wherein a connecting groove is formed in the side wall of the first panel, which faces the second panel, a plurality of mounting blocks are arranged in the connecting groove, rotating shafts are fixedly arranged in the mounting blocks, two ends of each rotating shaft penetrate through the mounting blocks and are rotationally connected with the first panel, connecting blocks which are in plug-in fit with the connecting grooves are fixedly arranged in the side wall of the second panel, the number of the connecting blocks is the same as that of the mounting blocks, one ends of the mounting blocks are connected with clamping blocks, and clamping grooves which are in plug-in fit with the clamping blocks are formed in the side wall of the connecting blocks.

Description

Spliced wallboard mounting structure

Technical Field

The application relates to the technical field of wallboards, in particular to a spliced wallboard mounting structure.

Background

The wall board is a house structure of a bearing system consisting of walls and floor slabs, and the bearing wall of the wall board structure can be made of bricks, building blocks, prefabricated or cast-in-place concrete and can be divided into three types of mixed structures, assembled large plate structures and cast-in-place wall board structures according to the different materials and construction methods.

At present, most of the existing spliced wallboard is provided with tenons, mortises and joint slots, and bolts are used for fixing during splicing.

In view of the above related art, the inventors consider that the fixing operation with bolts is complicated, the splicing time is long, and there is a defect of low installation efficiency.

Disclosure of utility model

In order to improve the installation efficiency, the application provides a spliced wallboard installation structure.

The application provides a spliced wallboard mounting structure, which adopts the following technical scheme:

The utility model provides a concatenation formula wallboard mounting structure, includes first panel and second panel, the spread groove has been seted up to the lateral wall of first panel towards the second panel, be provided with a plurality of installation pieces in the spread groove, set firmly the pivot in the installation piece, the both ends of pivot all run through the installation piece and rotate between with first panel to be connected, the second panel has set firmly the connecting block with the spread groove grafting adaptation towards the lateral wall of first panel, the quantity and the same and one-to-one of installation piece of connecting block, the one end of installation piece is connected with the fixture block, the draw-in groove with the fixture block grafting adaptation has been seted up to the lateral wall of connecting block towards the installation piece.

Through adopting above-mentioned technical scheme, the staff inserts the spread groove with the connecting block, and the connecting block is at the in-process of inserting, and the connecting block extrusion installation piece makes the installation piece revolute the axle and rotates, and when the connecting block inserts the spread groove completely, the installation piece is in the horizontality, and fixture block and draw-in groove are in the joint state this moment to splice first panel and second panel fixedly. Through above structure, easy operation, the concatenation time is shorter, has realized improving the effect of installation effectiveness.

Optionally, the mounting block has seted up towards the lateral wall of connecting block and has accomodate the groove, and the fixture block setting is in accomodating the inslot, and the fixture block is along accomodating the length direction and the mounting block sliding connection of groove, has set firmly the spring between fixture block and the mounting block.

By adopting the technical scheme, the clamping block is extruded by the connecting block and contracted into the containing groove in the rotating process of the mounting block, and the spring is in a compressed state at the moment; when the installation piece rotates to the horizontality, accomodate the groove and align with the draw-in groove, spring release elasticity is with the fixture block jack-in draw-in groove. Through above structure, the effect of being convenient for fixture block and draw-in groove joint adaptation has been realized.

Optionally, the cavity has been seted up in the second panel, be provided with the rack in the cavity along vertical direction, sliding connection between rack and the second panel along vertical direction, the rack has set firmly the connecting rod towards the lateral wall of first panel, the one end that the rack was kept away from to the connecting rod runs through the second panel and stretches out to the outside, the second panel runs through the lateral wall of first panel and has been seted up the groove of dodging that is used for the connecting rod to remove, dodging the groove and be linked together with the cavity, the connecting rod stretches out the tip of second panel set firmly with draw-in groove grafting adaptation's inserted bar, be provided with the drive assembly who drives the rack and follow vertical direction and remove in the cavity.

Through adopting above-mentioned technical scheme, the staff starts drive assembly, and drive assembly makes rack upward movement to the rack makes the inserted bar insert in the draw-in groove through the connecting rod, and then the inserted bar is ejecting the draw-in groove with the fixture block, and consequently the staff separates first panel and second panel, has realized convenient to detach's effect.

Optionally, the drive assembly includes drive gear and driving motor, and drive gear sets up in the rack one side that deviates from the connecting rod, and drive gear meshes with the rack mutually, and driving motor installs in one side of drive gear, and driving motor's output shaft and drive gear fixed connection.

Through adopting above-mentioned technical scheme, driving motor starts and makes the drive gear rotate through self output shaft to drive gear makes rack motion, has realized the effect that drive assembly drove rack motion.

Optionally, one side that the connecting block deviates from the installation piece is provided with the reinforcement piece along the horizontal direction, fixed connection between reinforcement piece and the first panel, the jack of pegging graft the adaptation with the inserted bar is offered towards the lateral wall of connecting block to the reinforcement piece, and the jack aligns with the draw-in groove.

Through adopting above-mentioned technical scheme, drive assembly starts and makes rack downstream to in the rack makes inserted bar downstream insert the jack, strengthen the joint strength of first panel and second panel, realized that first panel and second panel are connected firm effect.

Optionally, be provided with the guide bar along vertical direction in the cavity, the both ends of guide bar all with the inner wall fixed connection of second panel in cavity department, the guide bar runs through the rack and sliding connection between the two.

Through adopting above-mentioned technical scheme, along the guide bar motion when the rack moves, the guide bar plays direction and spacing effect to the rack.

Optionally, one end of the clamping block, which is away from the spring, is provided with an oval shape.

Through adopting above-mentioned technical scheme, when the inserted bar was ejecting the draw-in groove with the fixture block, even the fixture block did not break away from the draw-in groove completely, in the dismantlement process, the oval department of fixture block received the extrusion that the connecting block can shrink into accomodate the inslot, has further realized convenient to detach's effect.

Optionally, a torsion spring is installed at the rotation connection part of the rotating shaft and the first panel.

Through adopting above-mentioned technical scheme, when the connecting block breaks away from the spread groove, the torsional spring release elasticity makes the installation piece revolute the rotation of rotating shaft to the installation piece assists the fixture block to break away from the draw-in groove, has further realized convenient to detach's effect.

In summary, the present application includes at least one of the following beneficial technical effects:

1. When the connecting block is completely inserted into the connecting groove, the mounting block is extruded and rotated to be in a horizontal state, and the clamping block is clamped with the clamping groove, so that the first panel and the second panel are spliced, and when the connecting block needs to be disassembled, the inserting rod is inserted into the clamping groove, so that the clamping block is ejected out of the clamping groove, and the effect of convenient installation and disassembly is realized through the structure;

2. The inserted link is moved to insert the inserted link into the insertion hole, so that the connection strength of the first panel and the second panel is enhanced through the inserted link and the reinforcing plate;

3. In the disassembly process, the torsion spring releases elasticity to enable the installation block to rotate, so that the installation block drives the clamping block to be separated from the clamping groove, and the effect of auxiliary disassembly is realized.

Drawings

FIG. 1 is a schematic view of a spliced wallboard mounting structure according to an embodiment of the present application;

FIG. 2 is a partial cross-sectional view of an embodiment of the present application showing the structure in a connecting groove;

Fig. 3 is a partial cross-sectional view of an embodiment of the present application showing the structure within the cavity.

In the figure, 1, a first panel; 11. a connecting groove; 2. a second panel; 21. a connecting block; 211. a clamping groove; 22. a cavity; 23. an avoidance groove; 3. a mounting block; 31. a rotating shaft; 32. a clamping block; 321. an oval shape; 33. a storage groove; 34. a spring; 4. a rack; 41. a connecting rod; 411. a rod; 5. a drive assembly; 51. a drive gear; 52. a driving motor; 6. a reinforcing block; 61. a jack; 7. a guide rod; 8. and (3) a torsion spring.

Detailed Description

The application is described in further detail below with reference to fig. 1-3.

The embodiment of the application discloses a spliced wallboard mounting structure.

Referring to fig. 1 and 2, a splice type wallboard mounting structure includes first panel 1 and second panel 2, first panel 1 and second panel 2 all set up along vertical direction, first panel 1 and second panel 2 set up side by side and the butt between the two, spread groove 11 has been seted up to the lateral wall of first panel 1 towards second panel 2, spread groove 11 runs through the roof and the diapire of first panel 1, second panel 2 has set firmly the connecting block 21 with spread groove 11 grafting adaptation towards the lateral wall of first panel 1, connecting block 21 is provided with three, the even interval setting of vertical direction is followed to three connecting block 21.

When assembling, a worker pushes the second panel 2, and the second panel 2 drives the connecting block 21 to be inserted into the connecting groove 11; when the connecting block 21 is detached, the worker pulls the second panel 2, and the second panel 2 drives the connecting block 21 to be separated from the connecting groove 11.

Referring to fig. 2, the installation blocks 3 are provided in the connection groove 11, the number of the installation blocks 3 is the same as and corresponds to the number of the connection blocks 21 one by one, and the installation blocks 3 are provided above the connection blocks 21.

Referring to fig. 2, a rotating shaft 31 is fixedly arranged in the mounting block 3, both ends of the rotating shaft 31 penetrate through the mounting block 3 and extend to the outer side, the end part of the rotating shaft 31 extending out of the mounting block 3 is rotationally connected with the inner wall of the first panel 1 at the connecting groove 11, a torsion spring 8 is arranged at the rotational connection part of the rotating shaft 31 and the first panel 1, and the torsion spring 8 is sleeved on the circumferential side wall of the rotating shaft 31.

When the connection block 21 is inserted into the connection groove 11, the connection block 21 presses the mounting block 3, and the mounting block 3 rotates around the central axis of the rotation shaft 31 until the mounting block 3 rotates to a horizontal state, at which time the torsion spring 8 is in a stretched state. When the connecting block 21 is separated from the connecting groove 11, the torsion spring 8 releases the elastic force to drive the mounting block 3 to rotate until the mounting block 3 rotates to a vertical state.

Referring to fig. 2, a storage groove 33 is formed in the side wall of the mounting block 3 facing the connecting block 21, the storage groove 33 is formed in one end of the mounting block 3, a clamping block 32 is slidably connected in the storage groove 33, a spring 34 is arranged in the storage groove 33, two ends of the spring 34 are fixedly connected with the clamping block 32 and the mounting block 3 respectively, one end, deviating from the spring 34, of the clamping block 32 is arranged to be an ellipse 321, and a clamping groove 211 matched with the clamping block 32 in a clamping mode is formed in the side wall of the connecting block 21 facing the mounting block 3 in a penetrating mode.

Referring to fig. 2 and 3, a plug rod 411 is provided on one side of the connection block 21 facing away from the mounting seat along the vertical direction, the plug rod 411 is in plug-in fit with the clamping groove 211, a reinforcing plate is provided in the connection groove 11 along the horizontal direction, the side wall of the reinforcing plate is fixedly connected with the inner wall of the first panel 1 at the connection groove 11, and a jack 61 in plug-in fit with the plug rod 411 is provided through one end of the reinforcing plate, which is close to the second panel 2.

When assembled, the insert rod 411 is moved downward, so that the insert rod 411 is inserted into the insertion hole 61. When the connection block 21 is required to be detached, the inserting rod 411 moves upwards to be inserted into the clamping groove 211, so that the inserting rod 411 ejects the clamping block 32 out of the clamping groove 211, and a worker can pull out the connection block 21 from the connection groove 11.

Referring to fig. 3, a cavity 22 is formed in the second panel 2, the cavity 22 is formed in one side, close to the first panel 1, of the second panel 2, a rack 4 is arranged in the cavity 22 along the vertical direction, a guide rod 7 is slidably connected in the rack 4 along the vertical direction, two ends of the guide rod 7 penetrate through the rack 4, and two ends of the guide rod 7 are fixedly connected with the inner top wall and the inner bottom wall of the second panel 2 at the cavity 22 respectively.

Referring to fig. 1 and 3, the second panel 2 is provided with a through groove 23 for moving the connecting rod 41 towards the side wall of the first panel 1, the through groove 23 is provided along the vertical direction, the through groove 23 is communicated with the cavity 22, the connecting rod 41 is fixedly connected between the rack 4 and the sliding rod along the horizontal direction, and the connecting rod 41 penetrates through the through groove 23.

Referring to fig. 3, a driving assembly 5 is disposed in the cavity 22, the driving assembly 5 includes a driving gear 51 and a driving motor 52, the driving gear 51 is disposed on a side of the rack 4 away from the connecting rod 41, the driving gear 51 is meshed with the rack 4, the driving motor 52 is mounted on a side of the driving gear 51, the driving motor 52 is fixedly connected with an inner wall of the second panel 2 at the cavity 22, and an output shaft of the driving motor 52 is fixedly connected with the driving gear 51.

During assembly, the driving motor 52 rotates to drive the driving gear 51 to rotate, the driving gear 51 drives the rack 4 to move downwards, the rack 4 drives the connecting rod 41 to move downwards, and the connecting rod 41 drives the inserting rod 411 to move downwards, so that the inserting rod 411 is inserted into the inserting hole 61. When the rack is disassembled, the driving motor 52 is reversely rotated to drive the driving gear 51 to reversely rotate, the driving gear 51 drives the rack 4 to move upwards, and the rack 4 drives the inserting rod 411 to move upwards through the connecting rod 41, so that the inserting rod 411 is inserted into the clamping groove 211.

The implementation principle of the spliced wallboard mounting structure provided by the embodiment of the application is as follows: the worker pushes the second panel 2 to insert the connecting block 21 into the connecting groove 11, so that the connecting block 21 extrudes the mounting block 3 to enable the mounting block 3 to rotate around the rotating shaft 31 until the mounting block 3 rotates to be in a horizontal state, at the moment, the clamping block 32 is clamped and matched with the clamping groove 211, then the worker starts the driving motor 52, the driving motor 52 drives the rack 4 to descend through the driving gear 51, and the rack 4 drives the inserting rod 411 to be inserted into the inserting hole 61 through the connecting rod 41. When the disassembly is needed, the operator starts the driving motor 52, the driving motor 52 rotates reversely to drive the driving gear 51 to rotate reversely, so that the rack 4 drives the inserting rod 411 to be separated from the jack 61 through the connecting rod 41 until the inserting rod 411 is inserted into the clamping groove 211, the clamping block 32 is separated from the clamping groove 211 at the moment, and then the operator pulls the second panel 2 to separate the connecting block 21 from the connecting groove 11. Through the above structure, the effect of improving the installation efficiency is realized.

The embodiments of the present application are all preferred embodiments of the present application, and are not intended to limit the scope of the present application in this way, therefore: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (8)

1. The utility model provides a concatenation formula wallboard mounting structure, includes first panel (1) and second panel (2), its characterized in that: the utility model discloses a solar panel, including first panel (1), connecting groove (11) have been seted up towards the lateral wall of second panel (2), be provided with a plurality of installation piece (3) in connecting groove (11), install fixedly in piece (3) pivot (31), the both ends of pivot (31) all run through installation piece (3) and rotate between first panel (1) and be connected, connecting block (21) with connecting groove (11) grafting adaptation are set firmly towards the lateral wall of first panel (1) in second panel (2), the quantity of connecting block (21) is the same and one-to-one with the quantity of installation piece (3), the one end of installation piece (3) is connected with fixture block (32), draw-in groove (211) with fixture block (32) grafting adaptation are seted up towards the lateral wall of installation piece (3) in connecting block (21).

2. The spliced wallboard mounting structure of claim 1, wherein: the mounting block (3) is provided with a storage groove (33) towards the side wall of the connecting block (21), the clamping block (32) is arranged in the storage groove (33), the clamping block (32) is connected with the mounting block (3) in a sliding mode along the length direction of the storage groove (33), and a spring (34) is fixedly arranged between the clamping block (32) and the mounting block (3).

3. The spliced wallboard mounting structure of claim 1, wherein: the utility model discloses a drive assembly, including first panel (2), second panel (2), cavity (22) have been seted up in second panel (2), be provided with rack (4) in cavity (22) along vertical direction, sliding connection between rack (4) and second panel (2) is followed, rack (4) set firmly connecting rod (41) towards the lateral wall of first panel (1), the one end that rack (4) was kept away from to connecting rod (41) runs through second panel (2) and stretches out to the outside, the lateral wall that second panel (2) were kept away from towards first panel (1) runs through and has been offered and be used for dodging groove (23) that connecting rod (41) removed, dodging groove (23) are linked together with cavity (22), connecting rod (41) stretch out the tip of second panel (2) set firmly with inserted bar (411) of draw-in groove (211) grafting adaptation, be provided with in cavity (22) drive rack (4) along drive assembly (5) that vertical direction removed.

4. A splice-type wallboard mounting structure as claimed in claim 3, wherein: the driving assembly (5) comprises a driving gear (51) and a driving motor (52), the driving gear (51) is arranged on one side, deviating from the connecting rod (41), of the rack (4), the driving gear (51) is meshed with the rack (4), the driving motor (52) is arranged on one side of the driving gear (51), and an output shaft of the driving motor (52) is fixedly connected with the driving gear (51).

5. A splice-type wallboard mounting structure as claimed in claim 3, wherein: one side of connecting block (21) deviates from installation piece (3) is provided with reinforcing block (6) along the horizontal direction, fixed connection between reinforcing block (6) and first panel (1), reinforcing block (6) are offered jack (61) with inserted bar (411) grafting adaptation towards the lateral wall of connecting block (21), and jack (61) are aligned with draw-in groove (211).

6. A splice-type wallboard mounting structure as claimed in claim 3, wherein: guide rods (7) are arranged in the cavities (22) along the vertical direction, two ends of each guide rod (7) are fixedly connected with the inner wall of the second panel (2) at the cavity (22), and the guide rods (7) penetrate through the racks (4) and are in sliding connection with each other.

7. A splice-type wallboard mounting structure as claimed in claim 3, wherein: one end of the clamping block (32) deviating from the spring (34) is provided with an oval shape (321).

8. The spliced wallboard mounting structure of claim 1, wherein: a torsion spring (8) is arranged at the rotation connection part of the rotating shaft (31) and the first panel (1).