CN219100598U

CN219100598U - Socket-joint opposite-buckling type assembled overhead ground system

Info

Publication number: CN219100598U
Application number: CN202223484996.7U
Authority: CN
Inventors: 李淑强
Original assignee: Chengda Construction Engineering Co ltd; Jangho Group Co Ltd
Current assignee: Chengda Construction Engineering Co ltd; Jangho Group Co Ltd
Priority date: 2022-12-26
Filing date: 2022-12-26
Publication date: 2023-05-30
Anticipated expiration: 2032-12-26

Abstract

The socket-and-spigot butt-buckling type assembled overhead ground system comprises an annular building wall, wherein a plurality of overhead floor units are arranged above a floor in the building wall, and adjusting supports are arranged at the bottoms of four end corners of each overhead floor unit; the raised floor unit comprises a rectangular unit board, wherein an adhesive layer is arranged on the bottom surface of the unit board; the bottom of the unit board is provided with a fixed frame, and the fixed frame is provided with a first slot and a second slot; the adjusting support comprises a first support plate, a second support plate, a third support plate and a fourth support plate; two sides of the middle part of the fourth supporting plate are respectively provided with a sliding plate; the first slot and the second slot of each raised floor unit are mutually spliced with the corresponding third supporting plate, the fourth plate and the ninth plate end of each raised floor unit are positioned on the top surface of the corresponding fourth supporting plate, and the bottom plate end of each raised floor unit is positioned on the top surface of the corresponding second supporting plate; the length directions of the protruding parts of the bottom plates of the raised floor units are all parallel to form a pipeline groove.

Description

Socket-joint opposite-buckling type assembled overhead ground system

Technical Field

The utility model belongs to the technical field of interior decoration, and particularly relates to a socket-and-spigot-and-socket type assembled overhead ground system.

Background

The conventional floor has the following problems in construction and decoration: 1. the working procedures are complex, the construction working procedures are more, the construction is dependent on workers to manufacture on a construction site, the installation accuracy error is controlled manually, the construction quality is dependent on the skill of the workers, and the quality control and consistency are poor; 2. the construction period is long, and each link is as follows: preparing various materials, transporting, installing keels, building, plastering, manufacturing and installing base layers and facing layers, necessary time, time consumed by procedure connection and the like, so that the floor tiles/stones/and other plates are long in working time, low in efficiency and unfavorable for construction period; 3. the floor facing is basically undetachable after being built, the possibility of reutilization is low, the cost is high, and the flexibility is poor.

Disclosure of Invention

The utility model aims to provide a socket-and-spigot-and-socket type assembled overhead ground system, which has the advantages of high factory production and installation precision, guaranteed construction quality and construction period, reusability and cost saving.

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

the socket-joint opposite-buckling type assembled overhead ground system comprises an annular building wall body, wherein a plurality of overhead floor units are arranged above a floor in the building wall body, each overhead floor unit is rectangular, and adjusting supports are arranged at the bottoms of four end corners of each overhead floor unit;

the raised floor unit comprises a rectangular unit board, wherein an adhesive layer is arranged on the bottom surface of the unit board; the bottom of the unit plate is provided with a fixed frame, the fixed frame comprises a rectangular bottom plate, four edges of the bottom plate are sequentially provided with a first edge, a second edge, a third edge and a fourth edge, the first edge and the third edge are respectively provided with a folded line type side plate in an upward extending mode, the side plate comprises a first plate, a second plate, a third plate and a fourth plate which are sequentially and mutually vertically connected, the top of the first plate is provided with a horizontal fifth plate, and a first slot with an outward opening is formed between the fifth plate and the second plate; the first plate is vertically connected with the end part of the bottom plate, and the top surface of the fourth plate is bonded with the bottom surface of the unit plate through the adhesive layer; the bottom plate is provided with a plurality of raised parts which are raised upwards, so that the section of the bottom plate is wavy, the section of the raised parts is semicircular, and the height of the raised parts is smaller than or equal to that of the first plate; the second side and the fourth side are respectively provided with a folded line type end plate in an upward extending mode, the end plate comprises a sixth plate, a seventh plate, an eighth plate and a ninth plate which are sequentially and vertically connected with each other, the top of the sixth plate is provided with a horizontal tenth plate, and a second slot with an outward opening is formed between the tenth plate and the seventh plate; the sixth plate is vertically connected with the end part of the bottom plate and is provided with semicircular notches corresponding to the protruding parts, and the top surface of the ninth plate is bonded with the bottom surface of the unit plate through the adhesive layer; the bottom plate, the side plates and the end plates form a containing space with the bottom and the periphery being closed, the containing space is filled with concrete, and the top of the concrete is bonded with the bottom surface of the unit plate through the adhesive layer;

the adjusting support comprises a first support plate fixedly connected with the floor, a vertical screw rod is arranged in the middle of the top surface of the first support plate, a sleeve with internal threads is sleeved at the top of the screw rod, a second support plate is arranged at the bottom end of the sleeve, a third support plate is arranged at the top end of the sleeve, and the first support plate, the second support plate and the third support plate are all horizontal; the third supporting plate is rectangular, and a vertical fourth supporting plate is arranged in the middle of the third supporting plate; the top surface of the third supporting plate is provided with a plurality of first sliding grooves parallel to the fourth supporting plate, and the first sliding grooves on two sides of the fourth supporting plate are in mirror symmetry; a plurality of second sliding grooves parallel to the first sliding grooves are symmetrically arranged on two side surfaces of the fourth supporting plate; two sides of the middle part of the fourth supporting plate are respectively provided with a sliding plate vertical to the third supporting plate and the fourth supporting plate, the sliding plate is rectangular, the bottom of the sliding plate is provided with first bulges corresponding to the first sliding grooves, the side surface of the sliding plate is provided with second bulges corresponding to the second sliding grooves, the first bulges are positioned in the corresponding first sliding grooves, and the second bulges are positioned in the corresponding second sliding grooves;

the top of the third supporting plate is divided into four installation spaces by the third supporting plate, the fourth supporting plate and the two sliding plates; adjacent end angles of the four adjacent raised floor units are respectively positioned in the four installation spaces, the first slot and the second slot of each raised floor unit are mutually spliced with the third support plate in the corresponding installation space, the fourth plate and the ninth plate end of each raised floor unit are positioned on the top surface of the fourth support plate in the corresponding installation space, and the bottom plate end of each raised floor unit is positioned on the top surface of the corresponding second support plate; the length directions of the protruding parts of the raised floor units are all parallel to form a pipeline groove.

Further, a support keel is arranged at the bottom of the building wall body, the support keel comprises a first vertical keel plate, and the first keel plate is fixedly connected with the side surface of the building wall body through expansion bolts; the bottom end of the first keel plate is provided with a horizontal second keel plate, and the second keel plate is positioned on the floor; the tail end of the second keel plate is provided with a vertical third keel plate, the top end of the third keel plate is provided with a horizontal fourth keel plate, the middle part of the first keel plate is provided with a horizontal fifth keel plate, and the height of the fifth keel plate is higher than that of the fourth keel plate; the first slot and/or the second slot of the raised floor unit close to the building wall are mutually spliced with the corresponding fifth keel plate, and the end part of the bottom plate of the raised floor unit close to the building wall is positioned on the top surface of the corresponding fourth keel plate; the end of the unit plate of the raised floor unit close to the building wall body is propped against the side surface of the corresponding first keel plate.

Further, a skirting line mounting plate is arranged above the supporting keels, the skirting line mounting plate is fixedly connected with the side face of the building wall body, and the outer side of the skirting line mounting plate is connected with the skirting line plate in a buckling mode.

Further, reinforcing ribs are arranged between two adjacent protruding portions, and two ends of each reinforcing rib are fixedly connected with two end plates respectively.

Further, the bottom surface of the unit plate is provided with a plurality of anti-skid grooves.

Further, the concrete is lightweight concrete.

Further, the screw rod sleeve is provided with a limit nut, the side surface of the limit nut is provided with an annular supporting rib plate, and the top of the supporting rib plate is propped against the bottom surface of the second supporting plate.

Further, the first support plate and the second support plate are rectangular.

Further, a sealing rubber strip is arranged between the end parts of the unit plates, and the bottom end of the sealing rubber strip is arranged in the rubber strip grooves on the fourth plate and the ninth plate.

Further, the unit plate is a stone plate or a ceramic tile.

The beneficial effects of the utility model are as follows:

1. the industrial processing consistency and precision are high, and the construction quality is ensured.

2. Time can be saved, construction period is facilitated, and the problem of delay of construction period caused by cross operation of other work types in a construction site is avoided.

3. The unit plates can be repeatedly used, and are easy to detach, so that the cost is saved.

Drawings

FIG. 1 is a schematic diagram of the structure of the socket-and-spigot-and-socket type assembled overhead ground system of the present utility model.

FIG. 2 is a schematic illustration of the connection of a raised floor unit to an adjustment support of the socket and spigot-and-socket type fabricated overhead ground system of the present utility model.

Fig. 2A is an enlarged schematic view at a in fig. 2.

Fig. 3 is a front view of a raised floor unit of the socket and spigot-and-socket type fabricated overhead ground system of the present utility model.

Fig. 3A is a sectional view in the direction B-B in fig. 3.

Fig. 3B is an enlarged schematic view at C in fig. 3A.

Fig. 3C is a sectional view in the direction D-D in fig. 3.

Fig. 3D is an enlarged schematic view at E in fig. 3C.

Fig. 3E is a rear view of a raised floor unit of the socket and spigot-and-socket type fabricated overhead ground system of the utility model.

Fig. 4 is a front view of an adjustment bracket of the socket-and-spigot-and-socket type assembled overhead ground system of the present utility model.

Fig. 4A is a top view of an adjustment bracket of the socket-and-spigot-and-socket type assembled overhead ground system of the present utility model.

Fig. 4B is an exploded schematic view of an adjustment bracket of the socket-and-spigot-and-socket type assembled overhead ground system of the present utility model.

Fig. 4C is a schematic illustration of the installation process of the skid plate of the socket-and-spigot-and-socket type assembled overhead ground system of the present utility model.

FIG. 5 is a schematic illustration of the installation process of the raised floor unit of the socket and spigot-and-socket type fabricated overhead ground system of the present utility model.

Fig. 5A is a top view of the utility model after installation of the raised floor unit of the socket and spigot-and-socket type fabricated overhead ground system.

Fig. 5B is an enlarged schematic view at F in fig. 5A.

FIG. 6 is a schematic structural view of one embodiment of a connection structure of a raised floor unit to a building wall of the socket and spigot-and-socket type fabricated raised floor system of the present utility model.

Fig. 6A is a schematic diagram of the installation process of the embodiment shown in fig. 6.

Detailed Description

The following description will illustrate the structure and the technical effects to be achieved by the present utility model with reference to the accompanying drawings by specific examples, which are chosen for illustration only and are not intended to limit the scope of the present utility model.

As shown in fig. 1 and 2, the utility model provides a socket-and-spigot buckle type assembled overhead ground system, which comprises an annular building wall body 1, wherein a plurality of overhead floor units 2 are arranged above a floor 11 in the building wall body 1, each overhead floor unit 2 is rectangular, and adjusting supports 3 are arranged at the bottoms of four end corners of each overhead floor unit 2.

As shown in fig. 3 to 3E, the raised floor unit 2 includes a rectangular unit plate 21, and the unit plate 21 may be a stone plate or a tile. The unit plate 21 is provided with an adhesive layer 22 on the bottom surface, and preferably, the unit plate 21 is provided with a plurality of anti-slip grooves 211 on the bottom surface to improve the connection strength with the adhesive layer 22 and the lower member. The bottom of the unit plate 21 is provided with a fixing frame 23, the fixing frame 23 includes a rectangular bottom plate 231, four edges of the bottom plate 231 are sequentially a first edge 2311, a second edge 2312, a third edge 2313 and a fourth edge 2314, the first edge 2311 and the third edge 2313 are respectively provided with a folded line type side plate 232 in an upward extending manner, the side plate 232 includes a first plate 2321, a second plate 2322, a third plate 2323 and a fourth plate 2324 which are sequentially and vertically connected with each other, a horizontal fifth plate 2325 is arranged at the top of the first plate 2321, and a first slot 24 with an outward opening is formed between the fifth plate 2325 and the second plate 2322. The first plate 2321 is perpendicularly connected to the end of the bottom plate 231, and the top surface of the fourth plate 2324 and the bottom surface of the unit plate 21 are bonded by the adhesive layer 22. The bottom plate 231 is provided with a plurality of protruding portions 2315 protruding upwards, so that the cross section of the bottom plate 231 is wavy, and the cross section of the protruding portions 2315 is semicircular and has a height smaller than or equal to that of the first plate 2321. The second edge 2312 and the fourth edge 2314 each extend upwards to form a folded line type end plate 233, the end plate 233 comprises a sixth plate 2331, a seventh plate 2332, an eighth plate 2333 and a ninth plate 2334 which are sequentially and vertically connected with each other, a horizontal tenth plate 2335 is arranged at the top of the sixth plate 2331, and a second slot 25 with an outward opening is formed between the tenth plate 2335 and the seventh plate 2332. The sixth plate 2331 is vertically connected to the end of the bottom plate 231 and has a semicircular notch corresponding to each of the protrusions 2315, and the top surface of the ninth plate 2334 is bonded to the bottom surface of the unit plate 231 by the adhesive layer 22. The bottom plate 231, the side plates 232 and the end plates 233 form a closed bottom and four sides of the accommodating space, the accommodating space is filled with concrete 26, preferably light concrete, and the top of the concrete 26 is bonded with the bottom surface of the unit plate 21 through the adhesive layer 22. In order to enhance the structural strength, a reinforcing rib 27 is disposed between two adjacent protrusions 2315, and two ends of each reinforcing rib 27 are fixedly connected to two end plates 233.

As shown in fig. 4-4C, the adjusting support 3 includes a rectangular first support plate 31 fixedly connected with the floor 11, a vertical screw 311 is disposed in the middle of the top surface of the first support plate 31, a sleeve 312 with internal threads is sleeved on the top of the screw 311, a rectangular second support plate 32 is disposed at the bottom of the sleeve 312, a third support plate 33 is disposed at the top of the sleeve 312, and the first support plate 31, the second support plate 32 and the third support plate 33 are all horizontal. In order to improve the supporting capability, the screw 311 is sleeved with a limit nut 313, the side surface of the limit nut 313 is provided with an annular supporting rib plate 314, and the top of the supporting rib plate 314 is propped against the bottom surface of the second supporting plate 32. The third support plate 33 is rectangular, and a vertical rectangular fourth support plate 34 is provided in the middle. The top surface of the third supporting plate 33 is provided with a plurality of first sliding grooves 331 parallel to the fourth supporting plate 34, and the first sliding grooves 331 on two sides of the fourth supporting plate 34 are mirror-symmetrical. A plurality of second sliding grooves 341 parallel to the first sliding groove 331 are symmetrically disposed on two sides of the fourth supporting plate 34. Two sides of the middle part of the fourth supporting plate 34 are respectively provided with a sliding plate 35 perpendicular to the third supporting plate 33 and the fourth supporting plate 34, the sliding plate 35 is rectangular, the bottom is provided with a first bulge 351 corresponding to each first sliding groove 331, the side surface is provided with a second bulge 352 corresponding to each second sliding groove 341, the first bulge 351 is positioned in the corresponding first sliding groove 331, and the second bulge 352 is positioned in the corresponding second sliding groove 341. The third support plate 33, the fourth support plate 34 and the two sliding plates 35 divide the top of the third support plate 33 into four installation spaces 36.

As shown in fig. 1, 5A and 5B, adjacent end corners of adjacent four raised floor units 2 are located in the four installation spaces 36, as shown in fig. 2A and 5, the first slot 24 and the second slot 25 of each raised floor unit 2 are mutually inserted with the third support plate 33 in the corresponding installation space 36, the ends of the fourth plate 2324 and the ninth plate 2334 of each raised floor unit 2 are located on the top surface of the fourth support plate 34 in the corresponding installation space 36, and the end of the bottom plate 231 of each raised floor unit 2 is located on the top surface of the corresponding second support plate 32. A sealing rubber strip 28 is arranged between the ends of the unit plates 21, and the bottom ends of the sealing rubber strips 28 are arranged in rubber strip grooves on the fourth plate 2324 and the ninth plate 2334 so as to improve the sealing performance of the raised floor unit 2. The protruding portions 2315 of each raised floor unit 2 are all parallel in length direction, forming a line groove, facilitating the laying of a line thereunder.

As shown in fig. 6 and 6A, the present utility model further provides a connection between the raised floor unit 2 and the building wall 1, wherein the bottom of the building wall 1 is provided with a supporting keel 4, the supporting keel 4 comprises a first vertical keel plate 41, and the first keel plate 41 is fixedly connected with the side surface of the building wall 1 through expansion bolts 12. The bottom end of the first keel plate 41 is provided with a horizontal second keel plate 42, the second keel plate 42 being located on the floor 11. The end of the second keel plate 42 is provided with a vertical third keel plate 43, the top end of the third keel plate 43 is provided with a horizontal fourth keel plate 44, the middle part of the first keel plate 41 is provided with a horizontal fifth keel plate 45, and the height of the fifth keel plate 45 is higher than that of the fourth keel plate 44. The first slot 24 and/or the second slot 25 of the raised floor unit 2 adjacent to the building wall 1 are inserted into each other with the corresponding fifth keel plate 45, and the end of the bottom plate 231 of the raised floor unit 2 adjacent to the building wall 1 is positioned on the top surface of the corresponding fourth keel plate 44. The end of the unit panel 21 adjacent to the raised floor unit 2 of the building wall 1 abuts against the corresponding side of the first joist board 41. The skirting line mounting plate 5 is arranged above the supporting keel 4, the skirting line mounting plate 5 is fixedly connected with the side face of the building wall body 1 through the fixing screw 13, and the outer side of the skirting line mounting plate 5 is in buckling connection with the skirting line plate 51.

The utility model relates to a socket-and-spigot-and-socket type assembled overhead ground system, which comprises the following production and installation processes: the fabrication of the raised floor unit 2 is completed in a factory, comprising the fixing frame 23, the unit plates 21, the concrete 25 and the reinforcing ribs 27, to form one raised floor unit 2, the adjusting brackets 3 are individually processed in a matched manner, the fabrication is carried to the site, and the heights of the sleeve 312, the third supporting plate 33 at the top thereof and the second supporting plate 32 at the bottom thereof are adjusted by rotating the screw 311 of each adjusting bracket. The heights of the third supporting plate 33 and the second supporting plate 32 of each adjusting support 3 are consistent, so that the surface of the subsequently installed raised floor unit 2 is leveled; and then the first slot 24, the second slot 25 of the raised floor unit 2 and the third supporting plate 33 of the adjusting support 3 are connected in a socket-and-socket manner, and the fixing is firm, so that the raised floor unit is completed.

The socket-joint opposite-buckling type assembled overhead ground system has the advantages that: the raised floor unit and the adjusting bracket are processed into single elements through industrialization, the single elements are transported to a construction site to be installed conveniently, the raised floor unit is connected with the adjusting bracket through a specially designed socket type fixing frame, the raised floor unit is fixed firmly and not loose, and finally the raised floor unit is fixed and locked through a sliding plate on the adjusting bracket, so that the construction is convenient, gaps among plates are small, and the appearance is attractive.

The utility model is defined by the claims. Based thereon, however, one of ordinary skill in the art could make various obvious changes and modifications that would be within the spirit and scope of the present utility model.

Claims

1. The socket-joint opposite-buckling type assembled overhead ground system is characterized by comprising an annular building wall body, wherein a plurality of overhead floor units are arranged above a floor in the building wall body, each overhead floor unit is rectangular, and adjusting supports are arranged at the bottoms of four end corners of each overhead floor unit;

2. The socket and spigot-and-socket type assembled overhead ground system of claim 1, wherein: the bottom of the building wall body is provided with a supporting keel, the supporting keel comprises a first vertical keel plate, and the first keel plate is fixedly connected with the side surface of the building wall body through an expansion bolt; the bottom end of the first keel plate is provided with a horizontal second keel plate, and the second keel plate is positioned on the floor; the tail end of the second keel plate is provided with a vertical third keel plate, the top end of the third keel plate is provided with a horizontal fourth keel plate, the middle part of the first keel plate is provided with a horizontal fifth keel plate, and the height of the fifth keel plate is higher than that of the fourth keel plate; the first slot and/or the second slot of the raised floor unit close to the building wall are mutually spliced with the corresponding fifth keel plate, and the end part of the bottom plate of the raised floor unit close to the building wall is positioned on the top surface of the corresponding fourth keel plate; the end of the unit plate of the raised floor unit close to the building wall body is propped against the side surface of the corresponding first keel plate.

3. The socket and spigot joint type fabricated overhead ground system of claim 2, wherein: the support keel top is equipped with the skirting line mounting panel, this skirting line mounting panel with building wall side fixed connection, this skirting line mounting panel outside and skirting line board buckle are connected.

4. A socket-and-spigot-and-socket type assembled overhead ground system according to any one of claims 1 to 3, wherein: and reinforcing ribs are arranged between two adjacent protruding parts, and two ends of each reinforcing rib are fixedly connected with two end plates respectively.

5. A socket-and-spigot-and-socket type assembled overhead ground system according to any one of claims 1 to 3, wherein: the bottom surface of the unit plate is provided with a plurality of anti-skid grooves.

6. A socket-and-spigot-and-socket type assembled overhead ground system according to any one of claims 1 to 3, wherein: the concrete is light concrete.

7. A socket-and-spigot-and-socket type assembled overhead ground system according to any one of claims 1 to 3, wherein: the screw rod cover is equipped with stop nut, and this stop nut side is equipped with annular support rib board, this support rib board top with second backup pad bottom surface offsets.

8. A socket-and-spigot-and-socket type assembled overhead ground system according to any one of claims 1 to 3, wherein: the first support plate and the second support plate are rectangular.

9. A socket-and-spigot-and-socket type assembled overhead ground system according to any one of claims 1 to 3, wherein: and sealing rubber strips are arranged between the end parts of the unit plates, and the bottom ends of the sealing rubber strips are arranged in rubber strip grooves on the fourth plate and the ninth plate.

10. A socket-and-spigot-and-socket type assembled overhead ground system according to any one of claims 1 to 3, wherein: the unit plates are stone plates or ceramic tiles.