CN219175746U - Building engineering floor comprehensive assembly system - Google Patents

Abstract

The utility model discloses a building engineering floor comprehensive assembly system, which comprises a floor layer, wherein a plurality of supporting pieces distributed in a matrix form are arranged on the floor layer, floor bricks are arranged at the tops of the supporting pieces, and installation spaces are arranged at the bottoms of the floor bricks; the support piece comprises a support piece A and a support piece B, wherein the support piece A and the support piece B comprise a bottom support seat and an upper support seat which are connected in a sliding manner, and fillers are filled in the bottom support seat and the upper support seat; the side part of the bottom support seat of the support member A is provided with a locking screw which locks the whole height of the support member A; pipeline is arranged in the installation space at the bottom of the floor brick. The utility model realizes the efficient leveling of the floor tile and the efficient laying and installation of the water and electricity heating pipeline, and is convenient for the subsequent repair, maintenance and reconstruction of the floor tile and the water and electricity heating pipeline; the method belongs to an assembly type dry construction system, is beneficial to energy conservation and emission reduction, has high construction speed, and is not influenced by environmental temperature; the floor load can be lightened, the floor net height is increased, and the sound insulation effect is improved.

Description

Building engineering floor comprehensive assembly system

Technical Field

The utility model relates to a building floor comprehensive assembly system for building engineering, and belongs to the technical field of building engineering.

Background

At present, the traditional building engineering floor system generally adopts wet forming, namely, a pipeline such as a floor heating pipe, a water pipe, a threading pipe related to an electric power system and the like is embedded by concrete, then floor decorating materials such as floors and ceramic tiles are paved on a concrete layer, the concrete not only plays roles of protecting and fixing pipelines, but also serves as a main channel for transferring heat, the concrete layer can uniformly distribute the heat, and the situation of local overheating or supercooling is reduced.

The construction system of the traditional building engineering floor generally has the following defects:

1. the traditional floor practice adopts cement mortar or bean stone concrete as a floor heating filling layer, so that a large amount of cement, sand and stones are consumed, and a large amount of manpower and financial resources are consumed in the carrying and construction processes; the ground needs maintenance, and the construction period is long; the construction quality of cement mortar and concrete is greatly influenced by environmental temperature, and winter construction needs to be avoided or heating and heat preservation measures are adopted.

2. The use of a large amount of cement, sand and stones damages the environment, consumes a large amount of energy sources, and is unfavorable for realizing the energy conservation and emission reduction targets in the building industry.

3. Wet construction and poor field environment.

4. The pipeline is laid in traditional floor, can't overhaul, can't satisfy the requirement of secondary fitment laying pipeline. Particularly, once water leakage occurs in the floor heating pipe, the fault point is difficult to find, and the maintenance is labor-and time-consuming.

5. The leveling process of the floor is complex and low-efficiency, and is inconvenient to repair, maintain and reform in the follow-up process.

6. The traditional floor heating floor is divided into four layers: the total thickness of the heat insulation layer, the filling layer, the leveling layer and the surface layer is not less than 100mm, and the floor clear height is reduced.

7. The traditional floor heating floor has the advantages that due to the existence of the concrete filling layer, the floor load is increased, so that the load of the whole building structure is increased, and the total construction cost of the building engineering is increased.

8. The concrete floor can not effectively isolate the noise generated by the upper and lower households, and can not meet the indoor acoustic environment requirements of residents on the building.

9. The cement floor has high rigidity, and when the floor is adopted for radiant heating, the floor is cracked due to the non-uniformity of thermal expansion of the floor.

In summary, it is clear that the prior art has inconvenience and defects in practical use, so that improvement is needed.

Disclosure of Invention

Aiming at the defects in the background technology, the utility model provides a building engineering floor comprehensive assembly system, which realizes the efficient leveling of floor tiles and the efficient laying and installation of water and electricity heating pipelines, and is convenient for the subsequent repair, maintenance and reconstruction of the floor tiles and the water and electricity heating pipelines; the method belongs to an assembly type dry construction system, is beneficial to energy conservation and emission reduction, has high construction speed, and is not influenced by environmental temperature; the floor load can be reduced, floor practice is reduced, floor clean height is increased, construction site environment is improved, sound insulation effect is improved, and the problem of floor cracking caused by uneven expansion is solved.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the building engineering floor comprehensive assembly system comprises a floor layer, wherein a plurality of supporting pieces which are distributed in a matrix form are arranged on the floor layer, floor bricks are arranged at the tops of the supporting pieces, and installation spaces are arranged at the bottoms of the floor bricks;

the support piece comprises a support piece A and a support piece B, wherein the support piece A and the support piece B comprise a bottom support seat and an upper support seat which are connected in a sliding manner, and fillers are filled in the bottom support seat and the upper support seat; the side part of the bottom support of the support member A is provided with a locking screw, and the locking screw passes through the bottom support and then presses the upper support to lock the whole height of the support member A;

pipeline is arranged in the installation space at the bottom of the floor brick.

An optimal scheme, the floor layer is laid the heat preservation, is equipped with the trompil on the heat preservation, establishes on support piece through the trompil cover.

Further, the bottom support comprises a bottom plate at the lower part and a cylinder at the upper part, the bottom plate and the cylinder are integrally formed, the bottom plate is of a circular structure, and the bottom plate is contacted with the surface of the floor layer.

Further, the upper support comprises a top plate and a cylinder body at the lower part, the top plate and the cylinder body are integrally formed, the top plate is of a round structure, the top plate is contacted with the lower surface of the floor tile, and the cylinder body of the upper support is in sliding connection with the cylinder body of the bottom support.

Further, a glue injection hole is formed in the top plate, and glue connection fixation of the upper support and the lower surface of the floor tile is achieved through glue injection in the glue injection hole.

Further, a compression spring is arranged between the bottom support and the upper support of the support member B.

Further, compression springs are installed inside the bottom and upper brackets.

Further, the pipeline comprises a water pipe, an electric wire pipe, a heating pipe, a weak electric pipe and a net wire.

After the technical scheme is adopted, compared with the prior art, the utility model has the following advantages:

according to the utility model, the floor bricks are leveled and installed through the supporting piece, and the leveling and installing process is efficient and quick.

Through laying water pipe, wire pipe, heating pipe, light current pipe and net twine etc. in the installation clearance of floor brick bottom, the pipeline is realized high efficiency and is laid, inserts convenient installation ground, and convenient follow-up repair, maintenance and transformation are carried out floor brick and inside pipeline.

The assembly system of the utility model belongs to an assembly type dry construction system, cement, sand, stones and the like are not required to be used, the damage to the environment is reduced, a large amount of energy sources are saved, and the realization of the energy conservation and emission reduction targets in the building industry is facilitated; the construction speed is high, and the construction is not influenced by the environmental temperature; the construction site environment is improved.

Compared with the traditional process, the utility model does not need to cast concrete, can reduce the concrete layer with the thickness of about 100mm, lighten the floor load and reduce the floor load by about 220 kg/square meter, so that the consumption of the reinforced steel bars and the concrete of the whole building is obviously reduced; the method can reduce the floor practice in the room and increase the net height of the floor by about 6cm.

According to the utility model, the air gap is arranged at the bottom of the floor tile, so that the air gap is very important for the whole sound insulation design, the sound insulation performance of the floor is improved by 2-3 times, the noise generated by the upper and lower households is effectively isolated, and the indoor sound environment requirements of residents on the building are met.

When the utility model is used for radiant heating, the expansion is uniform, and the problem of floor cracking caused by uneven expansion is solved.

The utility model is not limited to floor tiles, but can also be used for mounting stone plates.

The utility model will now be described in detail with reference to the drawings and examples.

Drawings

FIG. 1 is a top view of the structure of embodiment 1;

fig. 2 is a structural sectional view of embodiment 1;

fig. 3 is a schematic structural view of the support a;

fig. 4 is a structural sectional view of the support a;

fig. 5 is a structural sectional view of embodiment 2;

fig. 6 is a schematic structural view of the support B;

fig. 7 is a structural sectional view of the support B.

In the figure, the floor layer is 1-floor, the floor tile is 2-, the heat preservation is 3-, the support piece A is 4-, the pipeline is 5-, the support piece B is 6-, the support seat is 7-bottom, the support seat is 8-upper, the filler is 9-, the locking screw is 10-, the compression spring is 11-, and the glue injection hole is 12-.

Detailed Description

For a clearer understanding of technical features, objects, and effects of the present utility model, a specific embodiment of the present utility model will be described with reference to the accompanying drawings.

Example 1

As shown in fig. 1-4 together, the utility model provides a building engineering floor comprehensive assembly system, which comprises a floor layer 1, wherein a plurality of supporting pieces A4 distributed in a matrix form are arranged on the floor layer 1, floor bricks 2 are arranged at the tops of the supporting pieces A4, and installation spaces are arranged at the bottoms of the floor bricks 2.

The supporting piece A4 can be used for adjusting the height of the floor tile 2, leveling the floor tile 2 and fixing the floor tile 2.

The heat preservation layer 3 is paved on the floor layer 1, the heat preservation layer 3 is provided with holes, the heat preservation layer 3 is sleeved on the supporting piece A4 through the holes, and the thickness of the heat preservation layer 3 is 20mm.

The axis of support piece A4 is vertical setting, and support piece A4 includes sliding connection's bottom support 7 and upper portion support 8, and the whole height of support piece A4 can be adjusted in the mutual slip of bottom support 7 and upper portion support 8.

The bottom support 7 comprises a bottom plate at the lower part and a cylinder at the upper part, the bottom plate and the cylinder are integrally formed, the bottom plate is of a circular structure, and the bottom plate is contacted with the surface of the floor layer 1.

The upper support 8 comprises a top plate and a cylinder body at the lower part, the top plate and the cylinder body are integrally formed, the top plate is in a round structure, the top plate is in contact with the lower surface of the floor tile 2, a glue injection hole 12 which is arranged in a penetrating manner is formed in the top plate, and glue connection and fixation of the upper support 8 and the lower surface of the floor tile 2 are realized through glue injection in the glue injection hole 12.

The cylinders of the bottom support 7 and the upper support 8 are internally provided with a filler 9, and the height of the upper support 8 is adjusted by the filler 9.

The cylinder of the bottom support 7 is slidingly connected with the cylinder of the upper support 8.

The side part of the bottom support 7 is provided with a locking screw 10, the locking screw 10 is in threaded connection with the bottom support 7, and the locking screw 10 penetrates through the cylinder of the bottom support 7 and then presses the cylinder of the upper support 8, so that the height of the upper support 8 is locked.

Pipeline 5 is laid in the installation space of floor tile 2 bottom, and pipeline 5 includes water pipe, wire pipe, heating pipe, light current pipe and net twine etc..

The construction method of the building engineering floor comprehensive assembly system comprises the following steps:

s1, mounting bottom supports 7 of supporting pieces A4 on the surface of a floor layer 1, wherein the bottom supports 7 are distributed in a matrix, and the bottoms of the bottom supports 7 are fixedly connected with the floor layer 1;

s2, sleeving the heat preservation layer 3 on the bottom support 7 along the vertical direction, wherein the bottom of the heat preservation layer 3 is contacted with the surface of the floor layer 1;

s3, mounting an upper support 8 of the support A4 on the bottom support 7, filling a filler 9 into the bottom support 7 and the upper support 8, and adjusting the overall height of the support A4 through the filler 9 to ensure that the upper end surfaces of the support A4 are arranged in a coplanar manner;

s4, arranging the pipeline 5 into an installation space between the heat insulation layer 3 and the floor bricks 2;

s5, injecting glue into the glue injection holes 12 of the supporting piece A4, overflowing the glue to the top surface of the supporting piece A4, and fixedly arranging the floor bricks 2 on the supporting piece A4 to finish floor assembly.

Example 2

As shown in fig. 5-7, the present utility model provides a building floor comprehensive assembly system, and embodiment 2 differs from embodiment 1 in that:

in the embodiment 1, the floor tile 2 is supported and leveled by a plurality of supporting pieces A4 distributed in a matrix, the floor tile 2 in the embodiment 2 is supported and leveled by the cooperation of the supporting pieces A4 and the supporting pieces B6, the supporting pieces A4 are distributed in the surrounding area of the floor tile 2, and the supporting pieces B6 are distributed in the middle area of the floor tile 2.

The support piece A4 is used for adjusting the height of the floor tile 2, leveling of the floor tile 2 is achieved, the support piece B6 can be adjusted in a height self-adaptive mode, the support piece B6 and the support piece A4 are matched for use, time consumed by leveling of the support piece A4 can be reduced, and overall installation speed is improved.

The support piece B6 comprises a bottom support seat 7 and an upper support seat 8 which are in sliding connection, a compression spring 11 is arranged between the bottom support seat 7 and the upper support seat 8, the compression spring 11 realizes the height self-adaptive adjustment of the support piece B6, the upper support seat 8 and the bottom of the floor tile 2 are fully contacted with each other through the elastic restoring force of the compression spring 11, and the compression spring 11 is locked in height through the solidified filler 9.

Compression springs 11 are mounted inside the bottom support 7 and the upper support 8.

The construction method of the building engineering floor comprehensive assembly system comprises the following steps:

s1, mounting a support A4 and a bottom support 7 of a support B6 on the surface of a floor layer 1, wherein the bottom supports 7 are distributed in a matrix, and the bottom of the bottom support 7 is fixedly connected with the floor layer 1;

s2, sleeving the heat preservation layer 3 on the bottom support 7 along the vertical direction, wherein the bottom of the heat preservation layer 3 is contacted with the surface of the floor layer 1;

s3, mounting the upper supports 8 of the supporting pieces A4 and B6 on the bottom support 7, filling the filler 9 into the bottom support 7 and the upper support 8, and adjusting the overall height of the supporting pieces A4 through the filler 9 to ensure that the upper end surfaces of the supporting pieces A4 are arranged in a coplanar mode, wherein the height of the supporting pieces B6 does not need to be leveled;

s4, arranging the pipeline 5 into an installation space between the heat insulation layer 3 and the floor bricks 2;

s5, injecting glue into the glue injection holes 12 of the supporting pieces A4 and B6, overflowing the glue to the top surface of the supporting piece A4, fixedly arranging the floor bricks 2 on the supporting pieces A4 and B6, and adaptively adjusting the heights of the supporting pieces B6 to finish the assembly of the floor.

The foregoing is illustrative of the best mode of carrying out the utility model, and is not presented in any detail as is known to those of ordinary skill in the art. The protection scope of the utility model is defined by the claims, and any equivalent transformation based on the technical teaching of the utility model is also within the protection scope of the utility model.

Claims (8)

1. The building engineering floor comprehensive assembly system is characterized by comprising a floor layer (1), wherein a plurality of supporting pieces distributed in a matrix form are arranged on the floor layer (1), floor bricks (2) are arranged at the tops of the supporting pieces, and installation spaces are formed at the bottoms of the floor bricks (2);

the support piece comprises a support piece A (4) and a support piece B (6), wherein the support piece A (4) and the support piece B (6) comprise a bottom support seat (7) and an upper support seat (8) which are connected in a sliding manner, and filler (9) is filled in the bottom support seat (7) and the upper support seat (8); the side part of the bottom support (7) of the support piece A (4) is provided with a locking screw (10), and the locking screw (10) passes through the bottom support (7) and then presses the upper support (8) to lock the whole height of the support piece A (4);

pipeline (5) is arranged in the installation space at the bottom of the floor brick (2).

2. The comprehensive assembly system for the building engineering floor according to claim 1, wherein the heat insulation layer (3) is paved on the floor layer (1), and the heat insulation layer (3) is provided with holes which are sleeved on the supporting piece.

3. The building engineering floor comprehensive assembly system according to claim 1, wherein the bottom support (7) comprises a lower bottom plate and an upper cylinder, the bottom plate and the cylinder are integrally formed, the bottom plate is of a circular structure, and the bottom plate is in contact with the surface of the floor layer (1).

4. A building engineering floor comprehensive assembly system according to claim 3, wherein the upper support (8) comprises an upper top plate and a lower cylinder, the top plate and the cylinder are integrally formed, the top plate is in a circular structure, the top plate is contacted with the lower surface of the floor brick (2), and the cylinder of the upper support (8) is in sliding connection with the cylinder of the bottom support (7).

5. The building engineering floor comprehensive assembly system according to claim 4, wherein the top plate is internally provided with a glue injection hole (12), and glue connection fixation of the upper support (8) and the lower surface of the floor brick (2) is realized through glue injection in the glue injection hole (12).

6. The building engineering floor comprehensive assembly system according to claim 1, wherein a compression spring (11) is arranged between the bottom support (7) and the upper support (8) of the support member B (6).

7. The building engineering floor integrated assembly system according to claim 6, wherein the compression springs (11) are installed inside the bottom support (7) and the upper support (8).

8. The building engineering floor comprehensive assembly system according to claim 1, wherein the pipeline (5) comprises a water pipe, an electric wire pipe, a heating pipe, a weak electric pipe and a network cable.

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