CN221030929U - Clamping type subway ceiling plate based on BIM technology - Google Patents

Abstract

The utility model relates to the field of subway suspended ceilings, in particular to a clamping type subway suspended ceiling based on BIM technology, which comprises a supporting plate, wherein the supporting plate is U-shaped, two sides of the inner wall of the supporting plate are provided with mutually symmetrical sliding grooves, a suspended ceiling body is arranged in each sliding groove, a backing plate is arranged below the end part of the suspended ceiling body, a groove is arranged on the surface of the supporting plate, a limiting component is arranged in each groove and is used for rapidly fixing the backing plate.

Description

Clamping type subway ceiling plate based on BIM technology

Technical Field

The utility model relates to the field of subway suspended ceilings, in particular to a clamping type subway suspended ceiling based on BIM technology.

Background

BIM refers to a building information model, which is built based on various relevant information data of a building engineering project, the real information of a building is simulated through digital information simulation, the construction flow can be simulated too quickly in the installation process of a suspended ceiling in a subway through BIM technology, and the installation process of the suspended ceiling is generally as follows: the keel is hung and fixed on the inner top surface of the building, and then the side edge of the inorganic board is fixed on the keel through screws or other mounting members.

For ceiling tiles, there are many existing products, such as:

Chinese patent publication No. CN211572212U discloses a ceiling tile comprising an inorganic board and a connector, wherein: the inorganic board comprises a connecting surface, a mounting surface and a side surface, wherein the connecting surface and the mounting surface are arranged in a back-to-back manner, the side surface is connected between the connecting surface and the mounting surface, a concave notch is formed at one end of the connecting surface and extends to the side surface, and the concave notch comprises a joint surface and an abutting surface which are connected; the connecting piece includes the draw-in groove, and the notch direction of draw-in groove is towards inorganic board, and the one end joint of indent breach has been seted up to inorganic board is in the draw-in groove, and the draw-in groove is including relative first cell wall and the second cell wall that sets up, installs on the laminating face towards one side laminating of second cell wall on the first cell wall.

Therefore, when the conventional suspended ceiling plate is installed, the side edge of the inorganic plate is clamped on the connecting piece, the side edge structural strength of the suspended ceiling plate is increased, but in the suspended ceiling plate installation process, the suspended ceiling plate is required to be limited and fixed through bolts, so that the construction is troublesome, in the suspended ceiling plate fixing process, the suspended ceiling plate position is easy to deviate, secondary fixing is required, and the operation efficiency is low.

In view of the above, the utility model provides a clamping type subway ceiling plate based on BIM technology.

Disclosure of utility model

The utility model aims to solve the defects and provide the clamping type subway ceiling plate capable of rapidly limiting and fixing the ceiling plate.

Carry out quick fixed spacing to the furred ceiling board body through spacing subassembly, avoid the furred ceiling board body to remove in the installation, simultaneously, carry out spacingly to the furred ceiling board body through the spout, avoid taking place the skew to its installation location, improve installation effectiveness.

Therefore, the utility model provides a clamping type subway ceiling plate based on BIM technology, which comprises a supporting plate, wherein the supporting plate is U-shaped, two sides of the inner wall of the supporting plate are provided with mutually symmetrical sliding grooves, a ceiling plate body is arranged in each sliding groove, a base plate is arranged below the end part of the ceiling plate body, a groove is arranged on the surface of the supporting plate, a limiting component is arranged in the groove, and the limiting component is used for rapidly limiting and fixing the base plate.

As a further improvement of the technical scheme, the limiting assembly comprises an arc plate arranged in the groove, the arc plate slides on the inner wall of the groove, and an elastic piece is arranged between the groove and the arc plate.

As a further improvement of the technical scheme, the contact part of the arc-shaped plate and the end part of the backing plate is arc-shaped.

As a further improvement of the technical scheme, the side wall of the end part of the suspended ceiling plate body is provided with a side groove, a gap is formed between the side groove and the end part of the chute, and the side wall of the side groove is deleted to be one half of the length of the inner wall of the chute.

As a further improvement of the technical scheme, limit blocks which are symmetrical to each other are arranged on two sides of the end part of the side groove, and the limit blocks slide on the inner wall of the pressing groove.

As a further improvement of the technical scheme, the surface of the suspended ceiling plate body is provided with a pressing groove, and the pressing groove is positioned above the arc plate when the clamping and fixing between the suspended ceiling plate body and the arc plate are completed.

Compared with the prior art, the utility model has the beneficial effects that:

This joint formula subway furred ceiling based on BIM technique is through placing furred ceiling body tip at the backup pad surface, the backing plate of furred ceiling body bottom slides to the backup pad inboard, along arc arcwall face one side extrusion slip when spacing subassembly, the arc receives external force effect along recess inner wall downwardly moving, when the backing plate is when spacing subassembly completely, the arc receives elastic component effort to reset, it is spacing to block the backing plate lateral wall simultaneously, avoid the backing plate to drive the furred ceiling body and rock, thereby carry out quick fixed to the furred ceiling body, simultaneously, the furred ceiling body is in slip in-process side and pressing groove laminating, avoid carrying out the in-process furred ceiling body position deviation to the furred ceiling body, thereby improve furred ceiling body installation effectiveness.

Drawings

The utility model is described in more detail below, by way of example, with reference to the accompanying drawings, in which:

FIG. 1 is a schematic diagram of the overall structure of the present utility model;

FIG. 2 is a cross-sectional view of the overall structure of the present utility model;

FIG. 3 is a schematic view of a structure of a support plate according to the present utility model;

FIG. 4 is a schematic view of a limiting assembly according to the present utility model;

fig. 5 is a schematic structural view of a ceiling tile body according to the present utility model.

The meaning of each reference sign in the figure is:

100. A support plate; 101. a chute; 200. a ceiling plate body; 204. a backing plate; 102. a groove; 300. a limit component; 301. an arc-shaped plate; 302. an elastic member; 202. a side groove; 203. a limiting block; 201. pressing the groove.

Detailed Description

In order that those skilled in the art will better understand the present application, a technical solution in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in which it is apparent that the described embodiments are only some embodiments of the present application, not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present application without making any inventive effort, shall fall within the scope of the present application.

Specifically, as shown in fig. 1-5, a clamping type subway ceiling board based on a BIM technology includes a supporting board 100, the supporting board 100 is in a "U" shape, two sides of an inner wall of the supporting board 100 are provided with mutually symmetrical sliding grooves 101 (as shown in fig. 3), a ceiling board body 200 is arranged in each sliding groove 101, a backing board 204 is arranged below an end portion of the ceiling board body 200, a groove 102 is arranged on a surface of the supporting board 100, a limiting component 300 is arranged in the groove 102, and the limiting component 300 is used for rapidly limiting and fixing the backing board 204.

The improvement of the embodiment is that: the suspended ceiling plate body 200 is fixed and limited rapidly through the limiting assembly 300, the suspended ceiling plate body 200 is prevented from moving in the installation process, meanwhile, the suspended ceiling plate body 200 is limited through the sliding groove 101, position deviation in the installation process is avoided, and the installation efficiency is improved.

Further, in order to facilitate quick clamping and limiting of the ceiling board body 200, and improve the installation efficiency, the limiting assembly 300 includes an arc plate 301 disposed inside the groove 102, the arc plate 301 slides on the inner wall of the groove 102, an elastic member 302 is disposed between the groove 102 and the arc plate 301, and a contact portion between the arc plate 301 and the end portion of the backing plate 204 is arc-shaped. Through placing furred ceiling body 200 tip at backup pad 100 surface, the backing plate 204 of furred ceiling body 200 bottom slides to backup pad 100 inboard, extrudees along arc 301 arcwall face one side when spacing subassembly 300 and slides, and arc 301 receives the exogenic action along recess 102 inner wall downwardly moving and compress elastic component 302, and when backing plate 204 passed through spacing subassembly 300 completely, arc 301 received elastic component 302 effort to reset, blockked the spacing to backing plate 204 lateral wall simultaneously, avoided backing plate 204 to drive furred ceiling body 200 and rock to carry out quick fixed to furred ceiling body 200.

In addition, in order to reduce the frictional force between the side wall of the suspended ceiling body 200 and the chute 101, the side wall of the end portion of the suspended ceiling body 200 is provided with a side groove 202, a gap exists between the side groove 202 and the end portion of the chute 101, the length of the side wall of the side groove 202 is one half of the length of the inner wall of the chute 101, two sides of the end portion of the side groove 202 are provided with mutually symmetrical limiting blocks 203, the limiting blocks 203 slide on the inner wall of the pressing groove 201, and the side groove 202 is arranged at the end portion of the suspended ceiling body 200, so that the frictional force between the suspended ceiling body 200 and the side edge of the supporting plate 100 is reduced, and the suspended ceiling body 200 is conveniently and rapidly pushed to be installed.

Meanwhile, in order to facilitate the rapid disassembly of the suspended ceiling plate body 200, the pressing groove 201 is formed in the surface of the suspended ceiling plate body 200, when the clamping and fixing between the suspended ceiling plate body 200 and the arc plate 301 are completed, the pressing groove 201 is located right above the arc plate 301, the arc plate 301 below the pressing groove 201 is pressed, the surface of the arc plate 301 is completely moved to the inside of the groove 102, and the suspended ceiling plate body 200 is pulled to rapidly disassemble.

In summary, the working principle of the scheme is as follows: through placing the roof board body 200 tip at backup pad 100 surface, the backing plate 204 of roof board body 200 bottom slides to backup pad 100 inboard, carry out extrusion slip along arc 301 arcwall face one side when spacing subassembly 300, arc 301 receives exogenic action along recess 102 inner wall downwardly moving, when the backing plate 204 is complete when spacing subassembly 300, arc 301 receives elastic component 302 effort to reset, block spacing to the backing plate 204 lateral wall simultaneously, avoid backing plate 204 to drive roof board body 200 and rock, thereby carry out quick fixed to roof board body 200, simultaneously, roof board body 200 is laminated with pressing groove 201 at slip in-process side, roof board body 200 position skew in the process of avoiding installing roof board body 200, improve roof board body 200 installation effectiveness.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (6)

1. A joint formula subway furred ceiling board based on BIM technique, its characterized in that: including backup pad (100), backup pad (100) are "U" type, spout (101) of mutual symmetry have all been seted up to backup pad (100) inner wall both sides, be equipped with furred ceiling board body (200) in spout (101), furred ceiling board body (200) tip below is equipped with backing plate (204), backup pad (100) surface is equipped with recess (102), be equipped with spacing subassembly (300) in recess (102), spacing subassembly (300) are used for carrying out quick spacing to backing plate (204) fixedly.

2. The clip-on subway ceiling tile based on BIM technology as set forth in claim 1, wherein: the limiting assembly (300) comprises an arc-shaped plate (301) arranged in the groove (102), the arc-shaped plate (301) slides on the inner wall of the groove (102), and an elastic piece (302) is arranged between the groove (102) and the arc-shaped plate (301).

3. The clip-on subway ceiling tile based on BIM technology as set forth in claim 2, wherein: the contact part of the arc-shaped plate (301) and the end part of the backing plate (204) is arc-shaped.

4. The clip-on subway ceiling tile based on BIM technology as set forth in claim 1, wherein: the side wall of the end part of the suspended ceiling plate body (200) is provided with a side groove (202), a gap exists between the side groove (202) and the end part of the sliding groove (101), and the length of the side wall of the side groove (202) is one half of the length of the inner wall of the sliding groove (101).

5. The clip-on subway ceiling tile based on BIM technology as set forth in claim 4, wherein: limiting blocks (203) which are symmetrical to each other are arranged on two sides of the end part of the side groove (202), and the limiting blocks (203) slide on the inner wall of the pressing groove (201).

6. The clip-on subway ceiling tile based on BIM technology as set forth in claim 4, wherein: the suspended ceiling plate is characterized in that a pressing groove (201) is formed in the surface of the suspended ceiling plate body (200), and the pressing groove (201) is located above the arc-shaped plate (301) when the clamping and fixing between the suspended ceiling plate body (200) and the arc-shaped plate (301) are completed.