CN221321297U - Efficient splicing structure based on green energy-saving house assembled heat-preserving integrated board - Google Patents

Abstract

The utility model provides an efficient splicing structure based on an assembled heat-preserving integrated plate of a green energy-saving house, which relates to the technical field of the green energy-saving house, and comprises a first plate and a second plate, wherein one end of the first plate is provided with a connecting groove, and one end of the second plate is fixedly provided with a connecting block mutually matched with the connecting groove; through reserving first mounting hole in the inside of first panel and installing first connecting piece, set up the second connecting piece in the inside of second panel and connecting block to offer a plurality of through-holes that communicate each other with first mounting hole at the inner wall of spread groove, can when two panels meet, the spacing post of second connecting piece and install the spacing piece on spacing post can enter into the inside of fixed block, then rotate first connecting piece in order to carry out spacingly to the second connecting piece through spacing piece, and then connect fixedly second panel and first panel.

Description

Based on the efficient splicing structure of green energy-saving house prefabricated insulation integrated board

Technical Field

The utility model relates to the technical field of green energy-saving houses, in particular to a highly efficient splicing structure of assembled thermal insulation integrated panels based on green energy-saving houses.

Background technique

As society pays more and more attention to environmental protection, energy conservation and sustainable development, green buildings have become the development trend of the future.

Traditional green energy-saving house prefabricated insulation integrated panel high-efficiency splicing structure mostly uses connecting blocks and fixing structures such as fixing blocks to splice the integrated panels. The splicing structure has poor connection and fixing effect, is inconvenient to install and has low stability. It is easy to shake and fall off for green energy-saving houses after long-term use, which poses certain safety hazards and endangers personal safety.

Utility Model Content

The purpose of the utility model is to provide an efficient splicing structure based on green energy-saving assembled thermal insulation integrated panels for houses, aiming to solve the problem in general technology that the efficient splicing structure based on green energy-saving assembled thermal insulation integrated panels for houses is inconvenient to install and the fixing effect is not good enough.

To achieve the above-mentioned purpose, the utility model adopts the following technical scheme: the efficient splicing structure based on the assembled insulation integrated panel of the green energy-saving house includes a first plate and a second plate, a connecting groove is provided at one end of the first plate, and a connecting block that is compatible with the connecting groove is fixedly installed at one end of the second plate, the connecting block can enter the connecting groove and stop each other at its bottom wall, and the bottom wall of the connecting groove is provided with a plurality of through holes; a first connecting member and a second connecting member are respectively installed inside the first plate and the second plate, and the second connecting member has a plurality of limiting columns and limiting plates installed at the ends of the limiting columns, and the limiting columns and the limiting plates can enter into the interior of the first connecting member through the through holes when the first plate and the second plate are connected, and the first connecting member can limit the limiting plate after rotating ninety degrees to connect the second plate to the first plate.

The beneficial effect is: by opening a connecting groove at one end of the first plate to install the second plate with the connecting block fixedly installed, reserving a first mounting hole inside the first plate to install the first connecting piece, arranging a second connecting piece inside the second plate and the connecting block, and opening a plurality of through holes interconnected with the first mounting hole on the inner wall of the connecting groove, when the two plates are connected, the limiting column of the second connecting piece and the limiting plate installed on the limiting column can enter the interior of the fixed block, and then the first connecting piece is rotated to limit the second connecting piece through the limiting plate, and then the second plate is connected and fixed to the first plate, which not only makes it convenient for users to install the two plates, but also can ensure the fixing effect of the two plates through multiple limiting columns and limiting plates, thereby achieving the purpose of easy installation and good fixing effect.

A further technical solution of the present invention is that a first mounting hole for mounting the first connecting member is reserved on the top of the first plate.

A further technical solution of the present invention is that the first connecting member includes a plurality of fixing blocks, and the plurality of fixing blocks are connected by connecting columns.

A further technical solution of the utility model is that the fixing block is cylindrical, a through groove is provided inside the fixing block, and a limiting groove which is perpendicular to and communicates with the through groove is provided on the circumferential surface of the fixing block.

A further technical solution of the utility model is that a sliding groove for connecting the limiting groove and one end of the through groove is also provided on the circumferential surface of the fixed block. When the first connecting member rotates, the limiting column slides along the sliding groove from the inside of the through groove into the inside of the limiting groove, so that the limiting plate and the inner wall of the through groove stop against each other.

A further technical solution of the utility model is that a rotating block is fixedly installed on the top of the fixed block at the top, and a rotating groove for rotating the first connecting member as a whole is opened inside the rotating block.

The beneficial effect is that it is convenient for the user to simultaneously rotate multiple fasteners through the rotating groove to simultaneously limit multiple limiting plates.

A further technical solution of the utility model is that a mounting block is fixedly mounted on the bottom of the fixing block at the bottom, and a threaded hole is provided inside the mounting block.

A further technical solution of the utility model is that a third mounting hole is opened inside the fixed block, the connecting column and the rotating block, and a limiting rod for limiting the second connecting member is slidably installed in the third mounting hole, and the limiting rod passes through the third mounting hole and is threadedly installed in the interior of the threaded hole through the threaded section at the bottom.

A further technical solution of the utility model is that the second connecting member also includes a reinforcement plate installed at one end of multiple limit columns, the reinforcement plate is pre-buried inside the second plate material, and a fourth mounting hole for installing the limit rod is opened on the outer circumferential surface of the limit plate.

The beneficial effect is that the limiting rod is inserted into the inside of the third mounting hole and the fourth mounting hole and finally threadedly installed in the threaded hole, so that the limiting piece is initially fixed and limited by the limiting rod.

A further technical solution of the utility model is that a second mounting hole for mounting a limiting column of the second connecting member is reserved inside the connecting block and the second plate.

BRIEF DESCRIPTION OF THE DRAWINGS

Fig. 1 is a schematic structural diagram of the utility model.

FIG. 2 is a schematic structural diagram of a first connecting member and a second connecting member in a specific embodiment of the present invention.

FIG. 3 is a schematic structural diagram of a first plate in a specific embodiment of the present invention.

FIG. 4 is a schematic structural diagram of a second plate in a specific embodiment of the present invention.

FIG. 5 is a schematic structural diagram of a first connecting member in a specific embodiment of the present utility model.

FIG. 6 is an enlarged schematic diagram of the structure of point A in FIG. 5 of the present invention.

FIG. 7 is a schematic structural diagram of a second connecting member in a specific embodiment of the present utility model.

In the figure: 1-first plate, 11-connecting groove, 12-first mounting hole, 13-through hole, 2-second plate, 21-connecting block, 22-second mounting hole, 3-first connecting piece, 31-fixed block, 311-through groove, 312-limiting groove, 313-slide groove, 32-connecting column, 33-rotating block, 331-rotating groove, 34-mounting block, 341-threaded hole, 35-third mounting hole, 36-limiting rod, 4-second connecting piece, 41-limiting column, 42-reinforcement plate, 43-limiting piece, 431-fourth mounting hole.

Detailed ways

The specific implementation of the utility model is further described below in conjunction with the accompanying drawings.

As shown in Figures 1 to 4, an efficient splicing structure of prefabricated thermal insulation integrated panels for green energy-saving houses includes a first plate 1 and a second plate 2. A connecting groove 11 is provided at one end of the first plate 1, and one end of the second plate 2 is installed in the connecting groove 11 through a connecting block 21. A first mounting hole 12 for installing a first connecting member 3 is reserved at the top of the first plate 1, and second mounting holes 22 for installing a second connecting member 4 are reserved in the connecting block 21 and the second plate 2. A plurality of through holes 13 interconnected with the first mounting holes 12 are provided on the side walls of the connecting groove 11 of the first plate 1, and the second connecting member 4 can enter into the first connecting member 3 through the through holes 13 and be connected to the first connecting member 3.

As shown in FIGS. 5 and 6 , the first connecting member 3 includes a plurality of fixed blocks 31, the fixed blocks 31 are cylindrical, and a through groove 311 is provided inside the fixed blocks 31, and a limiting groove 312 which is perpendicular to and connected to the through groove 311 is provided on the circumferential surface of the fixed blocks 31, and a sliding groove 313 for connecting the limiting groove 312 with one end of the through groove 311 is also provided on the circumferential surface of the fixed blocks 31, and the second connecting member 4 can enter the through groove 311 and rotate the fixed blocks 311 to slide the second connecting member 4 to the inside of the limiting groove 312 through the sliding groove 313 to limit the second connecting member 4, and the plurality of fixed The blocks 31 are connected by connecting columns 32. A rotating block 33 is fixedly installed on the top of the fixed block 31 at the top, and a rotating groove 331 is provided inside the rotating block 33. A mounting block 34 is fixedly installed on the bottom of the fixed block 31 at the bottom, and a threaded hole 341 is provided inside the mounting block 34. A third mounting hole 35 is provided inside the fixed block 31, the connecting column 32 and the rotating block 33. A limiting rod 36 for limiting the second connecting member 4 is slidably installed in the third mounting hole 35. The limiting rod 36 passes through the third mounting hole 35 and is threadedly installed in the threaded hole 341 through the threaded section at the bottom.

As shown in Figure 7, the second connecting member 4 includes a plurality of limit columns 41 installed inside the second mounting hole 22, and one end of each of the limit columns 41 is fixedly installed with a reinforcement plate 42 for connecting and reinforcing them. The reinforcement plate 42 is pre-buried inside the second plate 2, and one end of each of the limit columns 41 is fixedly installed with a limit plate 43. The limit plate 43 is circular, and a fourth mounting hole 431 for installing the limit rod 36 is provided on the outer circumferential surface of the limit plate 43.

During use, when the first plate 1 and the second plate 2 are close to each other, the limiting column 41 drives the limiting plate 43 to enter the middle of the through groove 311, and then the limiting rod 36 is inserted into the third mounting hole 35 and the fourth mounting hole 431 and finally threadedly installed in the threaded hole 341, so as to perform preliminary fixed limit on the limiting plate 43 by the limiting rod 36, and then rotate the first connecting member 3 to make the limiting column 41 rotate through the sliding groove 313 with the limiting rod 36 as the center to enter the inside of the limiting groove 312, at this time, the limiting plate 43 and the inner wall of the through groove 311 stop each other, thereby completing the limit of the second connecting member 4 to complete the connection and fixation of the two plates.

In the utility model, a connecting groove 11 is opened at one end of the first plate 1 to install the second plate 2 fixedly installed with a connecting block 21, a first mounting hole 12 is reserved inside the first plate 1 to install the first connecting member 3, a second connecting member 4 is arranged inside the second plate 2 and the connecting block 21, and a plurality of through holes 13 interconnected with the first mounting hole 12 are opened on the inner wall of the connecting groove 11, so that when the two plates are connected, the limiting column 41 of the second connecting member 4 and the limiting plate 43 installed on the limiting column 41 can enter the interior of the fixed block 31, and then the first connecting member 3 is rotated to limit the second connecting member 4 through the limiting plate 43, so as to connect and fix the second plate 2 to the first plate 1.

Claims (10)

1. The utility model provides a high-efficient mosaic structure of building assembled heat preservation intergral template based on green energy-conserving house, includes first panel (1) and second panel (2), characterized by, spread groove (11) have been seted up to first panel (1) one end, one end fixed mounting of second panel (2) has connecting block (21) with spread groove (11) looks adaptation each other, connecting block (21) can get into spread groove (11) and stop each other in its diapire, a plurality of through-holes (13) have been seted up to the diapire of spread groove (11);

The inside of first panel (1) and second panel (2) is installed first connecting piece (3) and second connecting piece (4) respectively, second connecting piece (4) have a plurality of spacing posts (41) and install spacing piece (43) in spacing post (41) tip, spacing post (41) and spacing piece (43) can be when first panel (1) and second panel (2) meet through hole (13) get into the inside of first connecting piece (3), first connecting piece (3) can be spacing in order to be connected second panel (2) with first panel (1) to spacing piece (43) after rotating ninety degrees.

2. The efficient splicing structure based on the green energy-saving house assembled heat preservation integrated board is characterized in that a first mounting hole (12) for mounting a first connecting piece (3) is reserved at the top of the first board (1).

3. The efficient splicing structure based on the green energy-saving house assembled heat preservation integrated board according to claim 1 is characterized in that the first connecting piece (3) comprises a plurality of fixing blocks (31), and the fixing blocks (31) are connected through connecting columns (32).

4. The efficient splicing structure based on the assembled heat preservation integrated board of the green energy-saving house according to claim 3, wherein the fixed block (31) is cylindrical, a through groove (311) is formed in the fixed block (31), and a limit groove (312) which is perpendicular to and communicated with the through groove (311) is formed in the circumferential surface of the fixed block (31).

5. The efficient splicing structure based on the assembled heat-preserving integrated board of the green energy-saving house according to claim 3, wherein a chute (313) used for communicating the limiting groove (312) with one end of the penetrating groove (311) is further formed in the circumferential surface of the fixed block (31), and the limiting column (41) slides from the inside of the penetrating groove (311) along the chute (313) to the inside of the limiting groove (312) when the first connecting piece (3) rotates, so that the limiting sheet (43) is mutually abutted with the inner wall of the penetrating groove (311).

6. The efficient splicing structure based on the green energy-saving house assembled heat preservation integrated plate, according to claim 3, is characterized in that a rotating block (33) is fixedly installed at the top of the fixed block (31) at the top, and a rotating groove (331) for integrally rotating the first connecting piece (3) is formed in the rotating block (33).

7. The efficient splicing structure based on the green energy-saving house assembled heat preservation integrated board according to claim 3, wherein an installation block (34) is fixedly installed at the bottom of the fixed block (31) at the bottom, and a threaded hole (341) is formed in the installation block (34).

8. The efficient splicing structure based on the green energy-saving house assembled heat preservation integrated plate, according to claim 3, characterized in that the third mounting holes (35) are formed in the fixing blocks (31), the connecting columns (32) and the rotating blocks (33), the third mounting holes (35) are slidably provided with limiting rods (36) used for limiting the second connecting pieces (4), and the limiting rods (36) penetrate through the third mounting holes (35) and are installed in the threaded holes (341) through thread sections at the bottoms.

9. The efficient splicing structure based on the assembled heat preservation integrated board of the green energy-saving house according to claim 1, wherein the second connecting piece (4) further comprises a reinforcing plate (42) arranged at one end of the limiting columns (41), the reinforcing plate (42) is embedded in the second board (2), and a fourth mounting hole (431) for mounting the limiting rod (36) is formed in the outer circumferential surface of the limiting piece (43).

10. The efficient splicing structure based on the green energy-saving house assembled heat preservation integrated board according to any one of claims 1 to 9, wherein the connecting block (21) and the second board (2) are both reserved with second mounting holes (22) for mounting the limit posts (41) of the second connecting piece (4).