CN210263357U - Floor cement component - Google Patents

Abstract

The utility model discloses a floor cement component, include: each floor component comprises a plurality of floor components, the floor components are transversely arranged, and every two floor components are connected through a connecting structure; the plurality of upright post components are uniformly arranged on the lower end surface of the floor slab component; the plurality of beam members are arranged on the lower end surface of the floor slab member, and each beam member is arranged between the two upright column members. The utility model discloses a set up the baffle structure in frame construction to thereby set up steel wire network structure and directly fill thick liquids, reduced production time.

Description

Floor cement component

Technical Field

The utility model relates to a building prefab's technical field, in particular to floor cement component's technical field.

Background

Floors are important components of buildings and floors are horizontal partitioning components used to partition spaces in buildings. The building is divided into a plurality of departments along the vertical direction, the floors are load-bearing members, bear the dead weight and the floor using load and transfer the load to the wall, and the floors play a certain horizontal supporting role on the wall.

In modern buildings, the construction of floor slab members, house beam members and upright post members generally needs to be performed below or around the steel bar keel, the arrangement of the floor slab members is complicated, and the production time is increased.

SUMMERY OF THE UTILITY MODEL

To the above-mentioned not enough, the utility model aims at providing a floor cement component through set up the baffle structure in frame construction to thereby set up steel wire network structure direct filling thick liquids, reduced production time.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

a floor cementitious structure, comprising:

each floor slab component comprises a plurality of floor slab components, the floor slab components are transversely arranged, and every two floor slab components are connected through a connecting structure;

the plurality of upright post components are uniformly arranged on the lower end surface of the floor slab component;

a plurality of beam members disposed on a lower end surface of the floor member, and each beam member is disposed between two of the pillar members.

The floor slab assembly comprises a frame structure with a bottom shell and a plurality of partition plate structures; the frame structure is provided with a plurality of first strip-shaped grooves along one side wall in the length direction, the frame structure is provided with a plurality of second strip-shaped grooves along the other side wall in the length direction, and the plurality of first strip-shaped grooves are respectively opposite to the plurality of second strip-shaped grooves; the two ends of each partition plate structure are respectively arranged in the first strip-shaped groove and the second strip-shaped groove which are opposite to each other.

The floor slab assembly further comprises a plurality of first lug groups, a plurality of second lug groups and a plurality of steel wire net structures; the two end faces, which are opposite to each other, of each two partition plate structures are respectively provided with the first ear hanging group and the second ear hanging group; each two ends of the steel wire mesh structure are respectively arranged on the first ear hanging group and the second ear hanging group.

The floor slab concrete structure, wherein each said connecting structure comprises a connecting piece and a sleeve; the connecting piece set up in frame construction along its width direction's one end lateral wall and its adjacent between the baffle structure, the sleeve sets up in same frame construction along its width direction's the other end lateral wall and its adjacent between the baffle structure.

The floor cement member, wherein the connecting piece and the sleeve are connected through a bolt; and an anchoring piece is arranged on the sleeve, and the anchoring piece is vertically and crossly connected with the sleeve.

In the floor cement component, two sliding grooves are respectively formed in the side wall of each frame structure along the length direction of the frame structure; each both ends of spout all set up an inclined plane, simultaneously the base of spout is greater than the higher authority of spout.

In the above floor cement structural member, a cover plate is disposed between the two sliding chutes of each frame structure; the inclined planes are arranged at two upper edges of each cover plate along the width direction of the cover plate.

In the floor cement member, a waterproof sealant is filled between two adjacent inclined planes of every two adjacent frame structures.

The floor cement member, wherein each frame structure is filled with slurry.

With above technical scheme, can reach following beneficial effect:

the utility model discloses a set up the baffle structure in frame construction to thereby set up steel wire network structure and directly fill thick liquids, reduced production time.

Drawings

FIG. 1 is a schematic view of a floor cement structure according to the present invention;

FIG. 2 is a top view of the connection of two frame structures of a floor slab concrete structure of the present invention, not including a cover plate;

FIG. 3 is a schematic view of a floor cement structural member frame structure and cover plate of the present invention;

fig. 4 is a schematic diagram of the two frame structures of the floor cement member of the present invention connected after the cover plate is disposed.

In the drawings: 1. a floor member; 111. a frame structure; 1111. a first bar-shaped groove; 1112. a second strip groove; 1113. a chute; 11131. a cover plate; 1114. a bevel; 112. a separator structure; 1131. a first ear hanging group; 1132. a second ear hanging group; 114. a steel wire mesh structure; 121. a connecting member; 122. a sleeve; 1221. an anchoring member; 2. a column member; 3. a beam member; 4. and (3) waterproof sealant.

Detailed Description

The present invention will be further described with reference to the accompanying drawings and specific embodiments, but the present invention is not limited thereto.

Fig. 1 is a schematic view of a floor cement structural member of the present invention. Fig. 2 is a top view of the connection of two frame structures of a floor slab of the present invention, which does not include a cover plate. Fig. 3 is a schematic view of a frame structure and a cover plate of a floor cement member according to the present invention. Fig. 4 is a schematic diagram of the two frame structures of the floor cement member of the present invention connected after the cover plate is disposed.

Referring to fig. 1 to 4, in a preferred embodiment, a floor slab concrete structure includes:

the floor slab component 1 comprises a plurality of floor slab components, each floor slab component 1 comprises a plurality of floor slab components, the floor slab components are transversely arranged, and every two floor slab components are connected through a connecting structure.

A plurality of upright post components 2, a plurality of upright post components 2 evenly set up in the lower terminal surface of floor component 1.

A plurality of beam members 3, a plurality of beam members 3 disposed on the lower end surface of the floor member 1, and each beam member 3 disposed between the upright members 2.

The above is merely an example of the preferred embodiments of the present invention, and the embodiments and the protection scope of the present invention are not limited thereby.

Further, in a preferred embodiment, the floor assembly includes a frame structure 111 having a bottom shell and a plurality of spacer structures 112; a plurality of first strip-shaped grooves 1111 are formed in one side wall of the frame structure 111 along the length direction of the frame structure, a plurality of second strip-shaped grooves 1112 are formed in the other side wall of the frame structure 111 along the length direction of the frame structure, and the plurality of first strip-shaped grooves 1111 are opposite to the plurality of second strip-shaped grooves 1112 respectively; two ends of each partition structure 111 are respectively disposed in a pair of first strip-shaped groove 1111 and a second strip-shaped groove 1112 which are opposite to each other.

Further, in a preferred embodiment, the floor assembly 11 further includes a plurality of first hangers 1131, a plurality of second hangers 1132, and a plurality of wire mesh structures 114; a first lug group 1131 and a second lug group 1132 are respectively arranged on two end faces, which are opposite to each other, of each two partition plate structures 112; two ends of each wire mesh structure 114 are respectively disposed on the first tab set 1131 and the second tab set 1132.

Further, in a preferred embodiment, each connecting structure includes a connecting member 121 and a sleeve 122; a connecting piece 121 and a sleeve 122 are arranged in each floor slab assembly; the connecting member 121 is disposed between one side wall of the frame structure 111 in the width direction thereof and its adjacent partition structure 112, and the sleeve 122 is disposed between the other side wall of the frame structure 111 in the width direction thereof and its adjacent partition structure 112.

Further, in a preferred embodiment, the connecting member 121 is connected to the sleeve 122 by bolts; and an anchor 1221 is provided on the sleeve 122, and the anchor 1221 is perpendicularly cross-connected to the sleeve 122.

Further, in a preferred embodiment, two sliding slots 1113 are respectively disposed on the side wall of each frame structure 111 along the length direction thereof; both ends of each sliding slot 1113 are provided with an inclined surface 1114, and the bottom edge of the sliding slot 1113 is larger than the upper edge of the sliding slot 1113, and the arrangement of the inclined surface 1114 is shown in fig. 3.

Further, in a preferred embodiment, a cover 11131 is disposed between the two sliding slots 1113 of each frame structure 111; each cover plate 11131 is provided with inclined surfaces 1114 at both upper edges in the width direction thereof.

Further, in a preferred embodiment, a waterproof sealant 4 is filled between two adjacent slopes 1114 of each two adjacent frame structures 111. After the waterproof sealant is hardened, a waterproof layer is formed at the splicing position of the two adjacent frame structures 111, and water leakage along the splicing position is avoided.

Further, in a preferred embodiment, each frame structure 111 is filled with slurry, and by filling the slurry, the slurry can play a role in enhancing the strength of the floor slab member 1 after the slurry is solidified; and the filling slurry does not influence the construction progress, and the slurry does not need to be hardened.

The above is only a preferred embodiment of the present invention, and not intended to limit the scope of the invention, and it should be appreciated by those skilled in the art that various equivalent substitutions and obvious changes made in the specification and drawings should be included within the scope of the present invention.

Claims (9)

1. A floor cementitious structure, comprising:

each floor slab component comprises a plurality of floor slab components, the floor slab components are transversely arranged, and every two floor slab components are connected through a connecting structure;

the plurality of upright post components are uniformly arranged on the lower end surface of the floor slab component;

a plurality of beam members disposed on a lower end surface of the floor member, and each beam member is disposed between two of the pillar members.

2. A floor cementitious structure as defined in claim 1, wherein said floor slab assembly includes a frame structure having a bottom shell and a plurality of spacer structures; the frame structure is provided with a plurality of first strip-shaped grooves along one side wall in the length direction, the frame structure is provided with a plurality of second strip-shaped grooves along the other side wall in the length direction, and the plurality of first strip-shaped grooves are respectively opposite to the plurality of second strip-shaped grooves; the two ends of each partition plate structure are respectively arranged in the first strip-shaped groove and the second strip-shaped groove which are opposite to each other.

3. The floor cementitious structure of claim 2, wherein the floor assembly further comprises a plurality of first lug sets, a plurality of second lug sets, and a plurality of wire mesh structures; the two end faces, which are opposite to each other, of each two partition plate structures are respectively provided with the first ear hanging group and the second ear hanging group; each two ends of the steel wire mesh structure are respectively arranged on the first ear hanging group and the second ear hanging group.

4. A floor cementitious structure as defined in claim 2 wherein each said connecting structure includes a connector and a sleeve; the connecting piece set up in frame construction along its width direction's one end lateral wall and its adjacent between the baffle structure, the sleeve sets up in same frame construction along its width direction's the other end lateral wall and its adjacent between the baffle structure.

5. A floor cement member as claimed in claim 4, wherein said connector and said sleeve are bolted together; and an anchoring piece is arranged on the sleeve, and the anchoring piece is vertically and crossly connected with the sleeve.

6. A floor cement structural member as claimed in claim 4, wherein each of said frame structures has two sliding grooves formed in the side walls along the length direction thereof; each both ends of spout all set up an inclined plane, simultaneously the base of spout is greater than the higher authority of spout.

7. A floor cementitious structure as defined in claim 6 wherein a cover plate is disposed between said runners of each of said frame structures; the inclined planes are arranged at two upper edges of each cover plate along the width direction of the cover plate.

8. The floor cementitious structure of claim 6, wherein a waterproof sealant is filled between adjacent ones of said inclined surfaces of each of said adjacent frame structures.

9. A floor cementitious structure as defined in claim 2 wherein each of said frame structures is filled with a slurry.

Images