CN218375175U - Lightweight for building combination concatenation template - Google Patents

Abstract

The application provides a lightweight combined splicing template for a building, which comprises splicing plates, wherein the splicing plates are provided with a first side and a second side which are opposite, the first side is provided with a first convex part along a first direction, and the second side is provided with a second convex part along the first direction; the first building board is provided with a first concave part corresponding to the first convex part, and the first concave part is detachably connected with the first convex part; the second building board, be equipped with on the second building board with the corresponding second concave part of second convex part, the second concave part with the connection can be dismantled to the second convex part, first building board, second building board and splice plate utilize above-mentioned concatenation mode can avoid relying on glue to bond, easily dismantle simultaneously, add the piece building efficiency.

Description

Lightweight for building combination concatenation template

Technical Field

The application relates to the technical field of building splicing, in particular to a lightweight combined splicing template for buildings.

Background

The combined building is a novel building mode, firstly, building templates are processed and finished in a processing factory, then the templates are transported to a building site, and the building templates are spliced to form the building.

In the actual operation process, the splicing mode of the building templates adopts glue adhesion, the glue can generate odor volatilization, and the splicing mode of the building templates is not convenient to disassemble; therefore, the combined building splicing template for the lightweight building is provided.

Disclosure of Invention

The utility model provides a to above problem, provide a lightweight building is with combination concatenation template.

The application provides a lightweight combined splicing template for a building, which comprises splicing plates, wherein the splicing plates are provided with a first side and a second side which are opposite, the first side is provided with a first convex part along a first direction, and the second side is provided with a second convex part along the first direction; the first building board is provided with a first concave part corresponding to the first convex part, and the first concave part is detachably connected with the first convex part; and a second building board, wherein a second concave part corresponding to the second convex part is arranged on the second building board, and the second concave part is detachably connected with the second convex part.

According to the technical scheme provided by some embodiments of the application, a first groove with a downward opening is arranged on the first convex part, and a second groove with an upward opening is arranged on the second convex part;

a first elastic telescopic component is arranged in the first groove, the telescopic direction of the first elastic telescopic component is a second direction, and the second direction is perpendicular to the first direction; a second elastic telescopic component is arranged in the second groove, and the telescopic direction of the second elastic telescopic component is the second direction; a first clamping groove is formed in the first concave part, and a second clamping groove is formed in the second concave part; the first elastic telescopic component has a first working state and a second working state, when the first elastic telescopic component is in the first working state, the telescopic end of the first elastic telescopic component is retracted into the first groove, and when the first elastic telescopic component is in the second working state, the telescopic end of the first elastic telescopic component extends out of the notch of the first groove and is inserted into the first clamping groove; the second elastic telescopic assembly is provided with a first working state and a second working state, when the second elastic telescopic assembly is in the first working state, the telescopic end of the second elastic telescopic assembly is retracted into the second groove, and when the second elastic telescopic assembly is in the second working state, the telescopic end of the second elastic telescopic assembly extends out of the notch of the second groove and is inserted into the second clamping groove.

According to the technical scheme provided by some embodiments of the application, a first limiting hole is formed in the splice plate and is communicated with the first groove, and a second limiting hole is formed in the splice plate and is communicated with the second groove; the first elastic telescopic component comprises a first spring; one end of the first spring is connected with the bottom of the first groove; one end of the first spring, which is far away from the bottom of the first groove, is connected with a first telescopic block; the second elastic telescopic component comprises a second spring, and one end of the second spring is connected with the bottom of the second groove; one end of the second spring, which is far away from the bottom of the second groove, is connected with a second telescopic block; the first elastic telescopic component also comprises a first handle, one end of the first handle is connected to the first telescopic block, and the other end of the first handle penetrates through the first limiting hole; the second elastic telescopic assembly further comprises a second handle, one end of the second handle is connected to the second telescopic block, and the other end of the second handle penetrates through the second limiting hole.

According to the technical scheme provided by some embodiments of the present application, the first telescopic block comprises a first connecting block, and the first connecting block is connected with the first spring; a first connecting rod is arranged at one end, far away from the first spring, of the first connecting block; one end of the first connecting rod, which is far away from the first connecting block, is connected with a second connecting block; the second telescopic block comprises a third connecting block, and the third connecting block is connected with the second spring; a second connecting rod is arranged at one end, far away from the second spring, of the third connecting block; one end of the second connecting rod, which is far away from the second connecting block, is connected with a fourth connecting block; the first elastic telescopic component also comprises a first sliding block, and the first sliding block is movably sleeved on the first connecting rod and can slide along the first direction; the first sliding block is fixedly connected with the first handle; the second elastic telescopic component also comprises a second sliding block, and the second sliding block is movably sleeved on the second connecting rod and can slide along the first direction; the second sliding block is fixedly connected with the second handle; the first limiting hole comprises a first hole part; the first hole portion extends in the second direction; one end of the first hole part, which is close to the bottom of the first groove, is communicated with a second hole part; the second hole portion extends in the first direction; the second limiting hole comprises a third hole part; the third hole portion extends in the second direction; one end of the third hole part, which is close to the bottom of the second groove, is communicated with a fourth hole part; the fourth hole portion extends in the first direction.

According to the technical scheme provided by some embodiments of the application, the combined splicing template for the lightweight building comprises a splicing structure, wherein the splicing structure comprises a first splicing convex block, the first splicing convex block is arranged on the first side, and a first splicing groove is formed in the corresponding position of the first building plate; the first splicing lug can be inserted into the first splicing groove; the splicing structure comprises a second splicing lug, the second splicing lug is arranged on the second side, and a second splicing groove is formed in the corresponding position on the second building board; the second splicing convex block can be spliced in the first splicing groove.

Compared with the prior art, the beneficial effect of this application: the split building template is divided into a first building board, a second building board and a splicing board, a first convex part and a second convex part are respectively arranged on two sides of the splicing board, a first concave part corresponding to the first convex part is arranged on the first building board, the first building board is detachably connected with the splicing board through the first convex part and the first concave part, a second concave part corresponding to the second convex part is arranged on the second building board, the second building board is detachably connected with the splicing board through the second convex part and the second concave part, and therefore the first building board, the second building board and the splicing board can be prevented from being bonded by depending on glue by utilizing the splicing mode, and meanwhile, the split building template is easy to detach, and the building efficiency is increased.

Drawings

Fig. 1 is a schematic structural diagram of a lightweight combined splicing formwork for a building provided in an embodiment of the present application;

FIG. 2 is a schematic structural view of the splice bar of FIG. 1;

FIG. 3 is a cross-sectional view of a splice bar with an elastic expansion device;

FIG. 4 is a schematic structural view of a first telescoping block;

FIG. 5 is a schematic structural view of a second telescoping block;

FIG. 6 is a schematic structural diagram of a first slider;

FIG. 7 is a schematic structural diagram of a second slider.

The text labels in the figures are represented as:

1. splicing plates; 10. a first convex portion; 11. a second convex portion; 12. a first telescopic block; 120. a first connection block; 121. a second connecting block; 122. a first connecting rod; 123. a first spring; 124, a first handle; 125. a first slider; 13. a second telescopic block; 130. a third connecting block; 131. a fourth connecting block; 132. a second connecting rod; 133. a second spring; 134, a second handle; 135. a second slider; 14. a first groove; 15. a second groove; 16. a first limiting hole; 17. a second limiting hole; 18. a first stitching bump; 19. a second stitching bump; 2. a first building panel; 20. a first recess; 21. a first card slot; 22 a first splice recess; 3. a second building panel; 30. a second recess; 31. A second card slot; 32. a second splice recess.

Detailed Description

The following detailed description of the present application is given for the purpose of enabling those skilled in the art to better understand the technical solutions of the present application, and the description in this section is only exemplary and explanatory, and should not be taken as limiting the scope of the present application in any way.

Referring to fig. 1, the present embodiment provides a lightweight building combined splicing formwork, including a splicing plate 1, where the splicing plate 1 has a first side and a second side opposite to each other, the first side is provided with a first protrusion 10 along a first direction, and the second side is provided with a second protrusion 11 along the first direction;

the building plate comprises a first building plate 2, wherein a first concave part 20 corresponding to the first convex part 10 is arranged on the first building plate 2, and the first concave part 20 is detachably connected with the first convex part 10;

and a second building board 3, wherein a second concave part 30 corresponding to the second convex part 11 is arranged on the second building board 3, and the second concave part 30 is detachably connected with the second convex part 11.

Specifically, in this embodiment, the first direction is a horizontal direction in fig. 1, the first building board and the second building board are both in an approximate "i" shape, and the splice board is in an approximate "cross" shape.

In the splicing process, the first convex part is spliced with the first concave part, and the second convex part is spliced with the second concave part.

The application provides a lightweight for building combination concatenation template need not to glue and bonds, and the workman can splice the equipment according to the building needs, and this kind of detachable building splice plate has improved the efficiency of construction, has practiced thrift the time of disassembling the building panel because of splicing error.

Further please refer to fig. 1, a first groove 14 with a downward opening is formed on the first protrusion 10, and a second groove 15 with an upward opening is formed on the second protrusion 11; a first elastic telescopic component is arranged in the first groove 14, the telescopic direction of the first elastic telescopic component is a second direction, and the second direction is perpendicular to the first direction; a second elastic telescopic component is arranged in the second groove 15, and the telescopic direction of the second elastic telescopic component is the second direction; a first clamping groove 21 is arranged in the first concave part 20, and a second clamping groove 31 is arranged in the second concave part 30; the first elastic telescopic component has a first working state and a second working state, when the first elastic telescopic component is in the first working state, the telescopic end of the first elastic telescopic component is retracted into the first groove 14, and when the first elastic telescopic component is in the second working state, the telescopic end of the first elastic telescopic component extends out of the notch of the first groove 14 and is inserted into the first clamping groove 21; the second elastic telescopic assembly has a first working state and a second working state, when the second elastic telescopic assembly is in the first working state, the telescopic end of the second elastic telescopic assembly is retracted into the second groove 15, and when the second elastic telescopic assembly is in the second working state, the telescopic end of the second elastic telescopic assembly extends out of the notch of the second groove 15 and is inserted into the second clamping groove 31.

In the splicing process, when the splicing plate is spliced with a first building plate, the first convex part is aligned with the first concave part, and the first elastic telescopic assembly is controlled to be in a first state, namely the first elastic telescopic assembly is contracted into the first groove; inserting the first convex part into the first concave part, controlling the first elastic telescopic component to be in a second state, and even if the first elastic telescopic component extends, extending the telescopic end of the first elastic telescopic component out of the first groove and inserting the telescopic end into the first clamping groove; when the splice plate is spliced with a second building plate, the second convex part is aligned with the second concave part, and the second elastic telescopic component is controlled to be in the first state, namely the second elastic telescopic component is contracted into the second groove; and the second convex part is inserted into the second concave part, the second elastic telescopic component is controlled to be in a second state, and even if the second elastic telescopic component extends, the telescopic end of the second elastic telescopic component extends out of the second groove and is inserted into the second clamping groove.

When the first building board and the splicing board can be spliced by the aid of the first elastic telescopic assembly, alignment and splicing of the first convex part and the first concave part are facilitated, and when the second building board and the splicing board can be spliced by the aid of the second elastic telescopic assembly, alignment and splicing of the second convex part and the second concave part are facilitated.

Further referring to fig. 2 and 3, a first limiting hole 1 is formed in the splice plate 1, the first limiting hole 16 is communicated with the first groove 14, a second limiting hole 17 is formed in the splice plate 1, and the second limiting hole 17 is communicated with the second groove 15; the first elastic telescopic assembly comprises a first spring; one end of the first spring is connected with the bottom of the first groove 14; one end of the first spring, which is far away from the bottom of the first groove, is connected with a first telescopic block 12; the second elastic telescopic component comprises a second spring 133, and one end of the second spring is connected with the bottom of the second groove 15; one end of the second spring, which is far away from the bottom of the second groove, is connected with a second telescopic block 13; the first elastic telescopic component further comprises a first handle 124, one end of the first handle 124 is connected to the first telescopic block 12, and the other end of the first handle 124 penetrates through the first limiting hole 16; the second elastic telescopic assembly further comprises a second handle 134, one end of the second handle 134 is connected to the second telescopic block 13, and the other end of the second handle penetrates through the second limiting hole 17.

Specifically, a cylindrical groove is formed in one side, facing the bottom of the first groove, of the first telescopic block 12, the cylindrical groove is fixedly connected with one end of the first spring, and the other end of the first spring is connected with the bottom of the first groove; a cylindrical groove is formed in one side, facing the bottom of the second groove, of the second telescopic block 13, the cylindrical groove is fixedly connected with one end of the second spring, and the other end of the second spring is connected with the bottom of the second groove.

In the splicing process, when the first handle is controlled to move towards the bottom of the first groove in the first limiting hole, the first telescopic block 12 is driven to move towards the bottom of the first groove, meanwhile, the first spring is compressed by the first telescopic block 12, when the first handle is loosened, the first spring is changed from the compressed state to the expanded state, and under the action of the restoring force of the first spring, the first telescopic block 12 is gradually ejected out of the first groove by the first spring; when the second handle is controlled to move towards the bottom of the second groove in the second limiting hole, the second telescopic block 13 is driven to move towards the bottom of the second groove, meanwhile, the second spring is compressed by the second telescopic block 13, when the second handle is in a free state, the second spring is changed from a compressed state to a relaxed state, and the second telescopic block 13 is ejected out of the second groove by the second spring.

The first handle is connected with the first telescopic block 12 and penetrates through the first limiting hole, so that the first handle is used for controlling the first elastic telescopic component to stretch, and the first building board is conveniently spliced with the splice plate; the second handle is connected with the second telescopic block 13 and penetrates through the second limiting hole, the second handle controls the second elastic telescopic assembly to stretch, and therefore the second building board and the splicing plate can be conveniently spliced.

Further referring to fig. 4, 5, 6 and 7, the first telescopic block 12 includes a first connecting block 120, and the first connecting block 120 is connected to the first spring 123; a first connecting rod 122 is arranged at one end of the first connecting block 120 away from the first spring 123; one end of the first connecting rod 122 far away from the first connecting block 120 is connected with a second connecting block 121; the second telescopic block 13 comprises a third connecting block 130, and the third connecting block 130 is connected with the second spring 133; a second connecting rod 132 is arranged at one end of the third connecting block 130 away from the second spring 133; one end of the second connecting rod 132, which is far away from the second connecting block 121, is connected with a fourth connecting block 131;

the first elastic telescopic element further comprises a first sliding block 125, and the first sliding block 125 is movably sleeved on the first connecting rod 122 and can slide along the first direction; the first slider 125 is fixedly connected with the first handle 124; the second elastic telescopic component further comprises a second sliding block 135, and the second sliding block 135 is movably sleeved on the second connecting rod 132 and can slide along the first direction; the second sliding block 135 is fixedly connected with the second handle 134; the first limiting hole 16 comprises a first hole part; the first hole portion extends in the second direction; a second hole part is communicated with one end of the first hole part, which is close to the bottom of the first groove 14; the second hole portion extends in the first direction; the second stopper hole 17 includes a third hole portion; the third hole portion extends in the second direction; a fourth hole part is communicated with one end, close to the bottom of the second groove 15, of the third hole part; the fourth hole portion extends in the first direction.

Specifically, the first telescopic block 12 and the second telescopic block 13 have the same structure, the first connecting block 120 and the second connecting block 121 have the same cross-sectional size, which is larger than the size of the first connecting rod, and the third connecting block 130 and the fourth connecting block have the same cross-sectional size, which is larger than the size of the second connecting rod 132; the first limiting hole and the second limiting hole are both L-shaped; first sliding block with the size of second sliding block is the same, is the rectangular block, has seted up the bar slot hole on it, the bar slot hole extends along first direction.

In the splicing process, the first handle is pulled from the first hole part to the second hole part, the first sliding block pulls the telescopic block to move to the bottom of the first groove, and then the first handle is clamped with the second hole part of the first limiting hole, so that the first sliding block pulls the first telescopic block 12 in the first groove; and when the second handle is pulled from the third hole part to the fourth hole part, the second sliding block pulls the second telescopic block 13 to move to the bottom of the second groove, and then the second handle is clamped with the fourth hole part of the second limiting hole, so that the second sliding block pulls the second telescopic block 13 in the second groove.

The first hole part and the second hole part extend from the first limiting hole, the first handle moves from the first hole part to the second hole part, the first handle drives the first sliding block to pull the first telescopic block 12 to move towards the bottom of the first groove and fixedly pull the first telescopic block 12 into the first groove, the first handle is clamped with the second hole part in the process, the first handle does not need to be manually and continuously controlled to enable the first telescopic block 12 to be located in the first groove, similarly, the second handle extends from the second limiting hole to be provided with the third hole part and the fourth hole part and moves from the third hole part to the fourth hole part, the second handle drives the second sliding block to pull the second telescopic block 13 to move towards the bottom of the second groove and fixedly pull the second telescopic block 13 into the second groove, the second handle is clamped with the fourth hole part in the process, and the second handle does not need to be manually and continuously controlled to enable the second telescopic block 13 to be located in the second groove.

Referring to fig. 1, the combined splicing formwork for lightweight building further includes: the splicing structure comprises a first splicing lug 18, the first splicing lug 18 is arranged on the first side, and a first splicing groove 22 is formed in the corresponding position on the first building board 2; the first splicing convex block can be spliced in the first splicing groove 22; the splicing structure comprises a second splicing lug 19, the second splicing lug 19 is arranged on the second side, and a second splicing groove 32 is formed in the corresponding position on the second building plate 3; the second engagement projection 19 can be inserted into the first engagement groove 22.

Preferably, the number of the first splicing convex blocks is two, and the two first splicing convex blocks are respectively positioned at the upper side and the lower side of the first convex part; the first building board is provided with first splicing grooves corresponding to the positions of the two first splicing lugs; the second splicing convex blocks are arranged into 2 blocks, and the second building board is provided with second splicing grooves corresponding to the two second splicing convex blocks.

In the splicing process, the first splicing convex block is spliced with the first splicing groove, and the second splicing convex block is spliced with the second splicing groove. Through the splicing of the splicing convex blocks and the splicing grooves, the splicing of the building plate and the splicing plate can be further reinforced.

Further, the first splicing convex block 18 and the second splicing convex block 19 are sleeved with damping rubber sleeves.

In the splicing process, the damping rubber sleeves can be respectively sleeved on the first splicing convex blocks and the second splicing convex blocks to enhance the splicing tightness of the first splicing convex blocks and the first splicing grooves and enhance the splicing tightness of the second splicing convex blocks and the second splicing grooves.

The principles and embodiments of the present application are described herein using specific examples, which are only used to help understand the method and its core idea of the present application. The foregoing is only a preferred embodiment of the present application, and it should be noted that there are no specific structures which are objectively limitless due to the limited character expressions, and it will be apparent to those skilled in the art that a plurality of modifications, decorations or changes can be made without departing from the principle of the present invention, and the technical features mentioned above can be combined in a suitable manner; such modifications, variations, combinations, or adaptations of the invention using its teachings or may be resorted to without departing from the scope of the invention as set forth in the claims that follow.

Claims (6)

1. The utility model provides a lightweight for building combination concatenation template which characterized in that includes:

the splicing plate (1) is provided with a first side and a second side which are opposite, the first side is provided with a first convex part (10) along a first direction, and the second side is provided with a second convex part (11) along the first direction;

the first building board (2) is provided with a first concave part (20) corresponding to the first convex part (10), and the first concave part (20) is detachably connected with the first convex part (10);

and a second building board (3), wherein a second concave part (30) corresponding to the second convex part (11) is arranged on the second building board (3), and the second concave part (30) is detachably connected with the second convex part (11).

2. The lightweight building composite splice formwork according to claim 1, wherein the first convex portion (10) is provided with a first groove (14) which is open downward, and the second convex portion (11) is provided with a second groove (15) which is open upward;

a first elastic telescopic component is arranged in the first groove (14), the telescopic direction of the first elastic telescopic component is a second direction, and the second direction is perpendicular to the first direction; a second elastic telescopic component is arranged in the second groove (15), and the telescopic direction of the second elastic telescopic component is the second direction;

a first clamping groove (21) is formed in the first concave part (20), and a second clamping groove (31) is formed in the second concave part (30);

the first elastic telescopic component has a first working state and a second working state, when the first elastic telescopic component is in the first working state, the telescopic end of the first elastic telescopic component is retracted into the first groove (14), and when the first elastic telescopic component is in the second working state, the telescopic end of the first elastic telescopic component extends out of the notch of the first groove (14) and is inserted into the first clamping groove (21);

the second elastic telescopic assembly is provided with a first working state and a second working state, when the second elastic telescopic assembly is in the first working state, the telescopic end of the second elastic telescopic assembly is retracted into the second groove (15), and when the second elastic telescopic assembly is in the second working state, the telescopic end of the second elastic telescopic assembly extends out of the notch of the second groove (15) and is inserted into the second clamping groove (31).

3. The lightweight building combined splicing template according to claim 2, wherein a first limiting hole (16) is formed in the splicing plate (1), the first limiting hole (16) is communicated with the first groove (14), a second limiting hole (17) is further formed in the splicing plate (1), and the second limiting hole (17) is communicated with the second groove (15);

the first resilient and resilient telescopic assembly comprises a first spring (123); one end of the first spring (123) is connected with the bottom of the first groove (14); one end, far away from the bottom of the first groove (14), of the first spring (123) is connected with a first telescopic block (12);

the second elastic telescopic assembly comprises a second spring (133), and one end of the second spring (133) is connected with the bottom of the second groove (15); one end, far away from the bottom of the second groove (15), of the second spring (133) is connected with a second telescopic block (13);

the first elastic telescopic component also comprises a first handle (124), one end of the first handle (124) is connected to the first telescopic block (12), and the other end of the first handle (124) penetrates through the first limiting hole (16);

the second elastic telescopic assembly further comprises a second handle (134), one end of the second handle (134) is connected to the second telescopic block (13), and the other end of the second handle penetrates through the second limiting hole (17).

4. The lightweight building composite splice formwork of claim 3, wherein said first expansion block (12) comprises a first connecting block (120), said first connecting block (120) being connected to said first spring (123); a first connecting rod (122) is arranged at one end, far away from the first spring (123), of the first connecting block (120); one end, far away from the first connecting block (120), of the first connecting rod (122) is connected with a second connecting block (121);

the second telescopic block (13) comprises a third connecting block (130), and the third connecting block (130) is connected with the second spring (133); a second connecting rod (132) is arranged at one end, away from the second spring (133), of the third connecting block (130); one end, far away from the second connecting block (121), of the second connecting rod (132) is connected with a fourth connecting block (131);

the first elastic telescopic component further comprises a first sliding block (125), and the first sliding block (125) is movably sleeved on the first connecting rod (122) and can slide along the first direction; the first sliding block (125) is fixedly connected with the first handle (124);

the second elastic telescopic component also comprises a second sliding block (135), and the second sliding block (135) is movably sleeved on the second connecting rod (132) and can slide along the first direction; the second sliding block (135) is fixedly connected with the second handle (134);

the first limiting hole (16) comprises a first hole part; the first hole portion extends in the second direction; one end of the first hole part, which is close to the bottom of the first groove (14), is communicated with a second hole part; the second hole portion extends in the first direction;

the second limiting hole (17) comprises a third hole part; the third hole portion extends in the second direction; one end of the third hole part, which is close to the bottom of the second groove (15), is communicated with a fourth hole part; the fourth hole portion extends in the first direction.

5. The lightweight building composite splice formwork of claim 1, further comprising:

the splicing structure comprises a first splicing lug (18), the first splicing lug (18) is arranged on the first side, and a first splicing groove (22) is formed in a corresponding position on the first building board (2); the first splicing lug (18) can be inserted into the first splicing groove (22);

the splicing structure further comprises a second splicing lug (19), the second splicing lug (19) is installed on the second side, and a second splicing groove (32) is formed in the corresponding position on the second building board (3); the second splicing projections (19) can be inserted into the second splicing grooves (32).

6. The lightweight building composite splice formwork of claim 5, wherein: the first splicing convex block (18) and the second splicing convex block (19) are sleeved with damping rubber sleeves.

Images