CN106639032B - Screw-in type framework, connecting framework and wall splicing structure and splicing method thereof - Google Patents

Abstract

The invention provides a screw-in type framework which comprises a splicing panel and side plates arranged on two sides of the splicing panel, wherein the splicing panel comprises a buckling part, a locking part and a matching part, the buckling part is provided with a buckling protrusion and a sealing pressing plate, and the locking part comprises a convex strip or a groove. Still provide a connection skeleton, including concatenation panel and the curb plate of setting in concatenation panel both sides, the concatenation panel includes laminating portion, location portion and sealing, and the sealing includes sealed recess, and location portion contains location sand grip or positioning groove. In addition, the screw-in type framework and the connecting framework are respectively embedded into the connecting surface of the first wall body and the second wall body, and the screw-in type framework and the connecting framework form a transverse locking and buckling structure. Also discloses a connecting method of the wall splicing structure, which mainly comprises the following steps: fixing the skeleton, inserting and rotating the wall body. The invention relates to the field of buildings, and provides a wall splicing structure which is high in sealing performance, firm in connection and capable of effectively preventing separation.

Description

Screw-in type framework, connecting framework and wall splicing structure and splicing method thereof

Technical Field

The field relates to the field of buildings, in particular to a screw-in type framework, a connecting framework, a wall splicing structure and a splicing method thereof.

Background

Traditional housing construction especially steel construction and the building of monolithic concreting structure, its building is inside except that structural bearing post is empty, sets up the wall body according to specific house usage needs, divide into indoor partition wall and building outer wall again, divides into individual functional room with whole floor. The inner partition wall is usually made of light steel keels and gypsum boards for field construction, and the building outer wall is usually built in situ or built by red bricks and building blocks, so that the construction site is messy, construction wastes such as wastes and leftover materials are too much, the construction wastes are not suitable for the detachable cyclic utilization of the wall body, the field labor amount is large, the labor cost is too high, and the construction size precision is low. In order to respond to national policy guidelines on green, environment-friendly, factory-like, rapidity, detachability and material recycling of novel buildings, the novel assembly wall body technology is vigorously developed, conventional modulus is set according to building size, the inside and outside integrated functional wall body is produced and completed in a factory in a large scale mode, and the building construction site is conveyed to be only fixedly installed between an upper floor and a lower floor, so that the building construction site is rapid and concise.

In order to achieve the technical effects, a plurality of walls are assembled into the whole wall, the assembling surfaces between the walls mostly adopt simple convex-concave plug-in type connecting pieces, but the wall using the existing connecting pieces is easy to separate from the plane of the wall to cause cracks, so that the sealing property is poor, and the sound insulation and heat insulation requirements of the whole wall cannot be met.

Disclosure of Invention

The invention aims to provide a screw-in type framework, a connecting framework and a wall splicing structure which are high in sealing performance, firm in connection and capable of preventing separation.

In order to achieve the purpose of the invention, the technical scheme adopted by the invention is as follows:

the invention discloses a screw-in type framework which is a long strip-shaped section and is used for splicing assembled walls, and the screw-in type framework comprises a splicing panel and side plates arranged on two sides of the splicing panel.

Preferably, a reinforcing rib is provided between the locking portion and the side plate.

Preferably, the screw-in type skeleton further comprises a bottom plate, and the bottom plate is connected with the side plates, so that the cross section of the screw-in type skeleton forms a full-surrounding structure.

Preferably, the joint of the buckling part and the locking part is provided with a rounding, a chamfer or a bend towards the inner side of the connecting keel.

Preferably, the screw-in type framework is formed by extrusion molding of plastic resin or extrusion molding of aluminum alloy.

The invention also discloses a connecting framework which is a strip-shaped section bar and is used for splicing assembled walls, the connecting framework comprises a splicing panel and side plates arranged on two sides of the splicing panel, and the connecting framework is characterized in that the splicing panel comprises a joint part, a positioning part and a sealing part which are sequentially connected, the sealing part comprises a sealing groove, and the positioning part comprises a positioning convex strip protruding towards the lateral direction of the connecting framework or a recessed positioning groove.

Preferably, a reinforcing rib is arranged between the positioning part and the side panel.

Preferably, the connection framework further comprises a bottom plate, and the bottom plate is connected with the side plates, so that the cross section of the connection framework forms a full-surrounding structure.

Preferably, the connecting framework is formed by extruding plastic resin or aluminum alloy.

In addition, a wall body mosaic structure is disclosed, its characterized in that, including first wall body and second wall body and foretell screw-in skeleton and foretell connection skeleton, screw-in skeleton and connection skeleton imbed the connection face of first wall body and second wall body respectively, the sand grip cooperates with positioning groove or recess and positioning sand grip cooperation form horizontal locking, the buckle arch stretches into in the sealed recess and forms buckle structure with the lateral wall laminating that sealed recess is close to the side board.

Preferably, the fitting portion and the attaching portion are fitted and attached to each other.

Preferably, a sealing rubber strip is filled in the sealing groove, and the sealing pressing plate extrudes the sealing rubber strip to form sealing.

The invention also discloses a splicing method of the wall splicing structure, which is characterized by comprising the following steps:

1) embedding the connecting framework into the first wall body and the second wall body respectively, vertically fixing the second wall body, and erecting the first wall body so that the splicing surfaces of the second wall body and the first wall body are opposite, and the first wall body and the second wall body are arranged at an angle;

2) the first wall body is close to the second wall body, so that the buckle bulge of the first wall body extends into the sealing groove;

3) rotatory first wall body makes the sand grip of first wall body and positioning groove laminating perhaps recess and positioning sand grip laminating make cooperation portion and laminating portion cooperation hug closely, make the protruding lateral wall laminating with sealed recess of buckle forms buckle structure.

Preferably, the sealing rubber strip is filled in the sealing groove before the step 2).

Compared with the prior art, the invention has the following beneficial effects:

the wall splicing structure can transversely lock two walls, is simple in structure, does not need to additionally add splicing hardware, is firm in connection, does not crack when being vibrated, and can be disassembled and reused.

The invention adopts a buckle structure to longitudinally lock the two spliced walls, so that the spliced part of the two walls becomes an integral flat wall surface, and the dislocation between the walls is prevented.

According to the invention, the sealing material is filled in the sealing groove, so that the heat insulation and sound insulation performance of the wall connecting structure is improved, and the sealing performance is good.

The invention utilizes the long-strip section bar to form connection of the wall body, and the rigidity strength of the wall body is enhanced through the framework.

Drawings

FIG. 1 is a cross-sectional view of an embodiment of a screw-in skeleton;

FIG. 2 is a cross-sectional view of a second embodiment of a screw-in skeleton;

FIG. 3 is a cross-sectional view of an embodiment of a connecting skeleton;

FIG. 4 is a cross-sectional view of a second embodiment of a connecting armature;

FIG. 5 is a three section view of an embodiment of a connecting skeleton;

FIG. 6 is a schematic cross-sectional view of a first embodiment of a wall splicing structure;

FIG. 7 is a schematic cross-sectional view of a second embodiment of a wall splicing structure;

FIG. 8 is a schematic cross-sectional view of a third embodiment of a wall splicing structure;

fig. 9 is a diagram of relative positions of the wall splicing structure in the connection process.

Reference numerals: 1-splicing panel, 101-buckling part, 1011-buckling protrusion, 1012-sealing pressing plate, 102-locking part, 1021-convex strip, 1022-groove, 103-sealing part, 2-side plate, 3-side plate, 4-bottom plate, 5-reinforcing rib, 6-splicing panel, 601-matching part, 602-locking part, 6021-positioning groove, 6022-positioning convex strip, 603-sealing part, 6031-sealing groove, 7-side plate, 8-side plate, 9-bottom plate, 10-reinforcing rib, 11-first wall, 12-second wall and 13-sealing rubber strip.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the following description of the embodiments of the present invention with reference to the accompanying drawings is provided, and it should be noted that, in the case of conflict, features in the embodiments and the embodiments in the present application may be arbitrarily combined with each other.

Examples referring to fig. 1, fig. 1 is a cross-sectional view of an example of a screw-in skeleton. A screw-in type framework is a strip section and is used for splicing assembled walls, a full-surrounding structure which is formed by a splicing panel 2, a side plate 3 and a bottom plate 4 in a cross section view and is formed by surrounding a screw-in type framework 1 can be produced by plastic resin through an extrusion method or aluminum alloy extrusion, wherein the plastic resin can be added with natural organic materials such as wood flour, bamboo powder, rice hulls, sawdust, plant straws and the like and inorganic materials such as calcium carbonate, slag, calcium silicate, glass beads, glass fibers and the like according to needs to enhance the overall performance. The splice panel 1 includes a latch portion 101, a lock portion 102, and a fitting portion 103 connected in this order. One end of the buckling part 101 is connected with the side plate 2, the buckling part 101 comprises a buckling protrusion 1011 and a sealing pressure plate 1012, and the sealing pressure plate 1012 is an arc-shaped plate, but is not limited to the arc-shaped plate and can also be a flat plate; the snap-fit protrusion 1011 is disposed near the edge of the splice panel 1, preferably a vertical plate, or other shapes. The locking portion 102 is a vertical plate and is provided with a convex strip 1021 protruding towards the lateral direction of the screw-in type framework, the convex strip 2021 can be in an arc shape or other shapes, such as a right-angle shape, the convex strip 1021 is connected with the sealing pressure plate 1012 and can be an extension of the sealing pressure plate 1012. The engaging portions 103 are connected to the convex strips 1012 and the side plates 3, respectively, and the sealing portions 103 are flat and horizontal plates. Reinforcing ribs 5 are arranged between the connecting part of the matching part 103 and the lock top part 102 and the side plates, so that the overall strength of the framework is improved.

Referring to fig. 2, fig. 2 is a cross-sectional view of a screw-in skeleton according to an embodiment. The screw-in type framework is a full-surrounding structure which is formed by surrounding a splicing panel 1, a side plate 2, a side plate 3 and a bottom plate 4 through a cross section diagram, can be produced by plastic resin through an extrusion method or aluminum alloy extrusion, wherein natural organic materials such as wood flour, bamboo powder, rice hulls, sawdust and plant straws and inorganic materials such as calcium carbonate, slag, calcium silicate, glass beads and glass fibers can be added into the plastic resin according to needs to enhance the overall performance. The splice panel 1 includes a latch portion 101, a lock portion 102, and a fitting portion 103 connected in this order. One end of the buckling part 101 is connected with the side plate 2, the buckling part 101 comprises a buckling protrusion 1011 and a sealing pressure plate 1012, and the sealing pressure plate 1012 is a flat plate, but is not limited to this, and may also be a flat plate; the snap-fit protrusion 1011 is disposed near the edge of the splice panel 1, preferably a vertical plate, or other shapes. The locking part 102 is a vertical plate and is provided with a groove 1022 recessed towards the lateral direction of the screw-in skeleton, the groove 1022 can be in a right-angle shape or in other shapes such as an arc shape, the buckling part 101 is connected with the locking part 102, and an inward right-angle-shaped bend is arranged at the joint, so that the locking part is not limited to be bent, and can also be a chamfer or a radius, and the installation is convenient. The fitting portion 103 is connected to the side plate 3, and the fitting portion 103 is a horizontal flat plate. Reinforcing ribs 5 are arranged between the joint of the matching part 103 and the locking part 102 and the side plates, and the reinforcing ribs 5 are also arranged between the right-angle bends and the side plates 2, so that the overall strength of the framework is improved.

Examples referring to fig. 3, fig. 3 is a cross-sectional view of an embodiment of a connecting skeleton. The connecting framework is a strip-shaped section and is used for splicing assembled walls, a full-surrounding structure formed by surrounding a splicing panel 6, a side plate 7, a side plate 8 and a bottom plate 9 is provided with a cross section, plastic resin can be produced by an extrusion method or aluminum alloy extrusion, and natural organic materials such as wood flour, bamboo powder, rice hulls, sawdust and plant straws and inorganic materials such as calcium carbonate, slag, calcium silicate, glass beads and glass fibers can be added into the plastic resin according to needs to enhance the overall performance. The splice panel 6 includes a fitting portion 601, a positioning portion 602, and a sealing portion 603 connected in this order. One end of the bonding portion 601 is connected to the side plate 7, and the bonding portion 601 is a flat plate. The positioning portion 602 is a vertical plate and is provided with a positioning groove 6021 recessed toward the side of the connecting frame, and the positioning groove 6021 may be circular arc or in other shapes, such as right angle. Sealing portion 603 is connected with curb plate 8, and sealing portion 603 includes sealing groove 6031, and sealing groove 6031 is circular-arc, and sealing groove 6031 is connected with positioning groove 6021, and can be the extension of positioning groove 6021's circular arc, and is the lateral wall of sealing groove 6031 at the vertical board of the one end of being connected with curb plate 8, and the panel of this lateral wall of sealing groove 6031 is the extension of the panel of curb plate 8. The joint of the sealing groove 6031 and the positioning groove 6021 is provided with the reinforcing rib 10, and the reinforcing rib 10 is also connected with the side plate 7, so that the overall strength of the framework is improved.

Referring to fig. 4, fig. 4 is a cross-sectional view of an embodiment of a connecting skeleton. The connecting framework is a strip-shaped section and is used for splicing assembled walls, a full-surrounding structure formed by surrounding a splicing panel 6, a side plate 7, a side plate 8 and a bottom plate 9 is provided with a cross section, plastic resin can be produced by an extrusion method or aluminum alloy extrusion, and natural organic materials such as wood flour, bamboo powder, rice hulls, sawdust and plant straws and inorganic materials such as calcium carbonate, slag, calcium silicate, glass beads and glass fibers can be added into the plastic resin according to needs to enhance the overall performance. The splice panel 6 includes a fitting portion 601, a positioning portion 602, and a sealing portion 603 connected in this order. One end of the bonding portion 601 is connected to the side plate 7, and the bonding portion 601 is a flat plate. The positioning portion 602 is a vertical plate and is provided with a positioning groove 6021 recessed toward the side of the connecting frame, and the positioning groove 6021 may be circular arc or in other shapes, such as right angle. Sealing portion 603 is connected with curb plate 8, and sealing portion 603 includes sealing groove 6031, and sealing groove 6031 is the rectangle form, and sealing groove 6031 is connected with positioning groove 6021 through one end arcuation panel, and the arcuation panel can be the extension of the circular arc of positioning groove 6021, and is the lateral wall of sealing groove 6031 at the vertical board of the one end that is connected with curb plate 8, and the panel of this lateral wall of sealing groove 6031 is the extension of the panel of curb plate 7. And a reinforcing rib 10 is arranged between the positioning groove 6021 and the side plate 8, so that the overall strength of the framework is improved.

Referring to fig. 5, fig. 5 is a three-sectional view of an embodiment of a connecting skeleton. The connecting framework is a strip-shaped section and is used for splicing assembled walls, a full-surrounding structure formed by surrounding a splicing panel 6, a side plate 7, a side plate 8 and a bottom plate 9 is provided with a cross section, plastic resin can be produced by an extrusion method or aluminum alloy extrusion, and natural organic materials such as wood flour, bamboo powder, rice hulls, sawdust and plant straws and inorganic materials such as calcium carbonate, slag, calcium silicate, glass beads and glass fibers can be added into the plastic resin according to needs to enhance the overall performance. The splice panel 6 includes a fitting portion 601, a positioning portion 602, and a sealing portion 603 connected in this order. One end of the bonding portion 601 is connected to the side plate 7, and the bonding portion 601 is a flat plate. The positioning portion 602 is a vertical plate and is provided with a positioning protrusion 6022 protruding toward the side of the connecting frame, and the positioning protrusion 6022 may be rectangular or in other shapes, such as circular arc. Sealing portion 603 is connected with curb plate 8, and sealing portion 603 includes sealed recess 6031, and sealed recess 6031 is the rectangle form, and sealed recess 6031 is connected with the panel of location portion 102 through a lateral wall panel, and is another lateral wall of sealed recess 6031 at the vertical board of the one end of being connected with curb plate 8, and the panel of this lateral wall of sealed recess 6031 is the extension of the panel of curb plate 8. And a reinforcing rib 10 is arranged between the positioning and positioning part 602 and the side plate 7, so that the overall strength of the framework is improved.

Fig. 6 is a schematic cross-sectional view of a first wall splicing structure embodiment, where the wall splicing structure includes the first screw-in type framework embodiment, the first connecting framework embodiment, a first wall, and a second wall. As shown in fig. 6, the first wall 11 includes wall boards 1101, a screw-in framework is embedded between the wall boards 1101, the side boards 2 and 3 are both attached to the wall boards 1101, and the splicing panel 1 of the screw-in framework serves as a connecting surface of the first wall 11; second wall body 12 includes wallboard 1201, connects between skeleton embedding wallboard 1201, and curb plate 7 and curb plate 8 all laminate with wallboard 1201, and the concatenation panel 6 of connecting the skeleton is as the connection face of first wall body 12. The matching part 103 of the screw-in type framework is jointed with the jointing part 601 of the connecting framework, the locking part 102 is matched with the positioning part 602, and the convex strip 1021 of the screw-in type framework is inserted into the positioning groove 6021 of the connecting framework to transversely lock the two walls; the snap protrusions 1011 extend into the sealing groove 6031 and are attached to the side wall of the sealing groove 6031 to form a snap, so that two walls are longitudinally locked.

Fig. 7 is a schematic cross-sectional view of a second wall splicing structure embodiment, where the wall splicing structure includes the first screw-in type framework embodiment, the second connecting framework embodiment, the first wall and the second wall. As shown in fig. 7, the first wall 11 includes wall boards 1101, a screw-in framework is embedded between the wall boards 1101, the side boards 2 and 3 are both attached to the wall boards 1101, and the splice panel 1 of the screw-in framework serves as a connecting surface of the first wall 11; second wall body 12 includes wallboard 1201, connects between skeleton embedding wallboard 1201, and curb plate 7 and curb plate 8 all laminate with wallboard 1201, and the concatenation panel 6 of connecting the skeleton is as the connection face of first wall body 12. The matching part 103 of the screw-in type framework is jointed with the jointing part 601 of the connecting framework, the locking part 102 is matched with the positioning part 602, and the convex strip 1021 of the screw-in type framework is inserted into the positioning groove 6021 of the connecting framework to transversely lock the two walls; the snap protrusions 1011 extend into the sealing groove 6031 and are attached to the side wall of the sealing groove 6031 to form a snap, so that two walls are longitudinally locked. A sealing rubber strip 13 is arranged in the sealing groove, a sealing pressure plate 1022 of the screw-in type framework is screwed in, and the sealing rubber strip is extruded to form sealing. The sealing rubber strip 13 may be organic foam material such as polystyrene foam, phenolic foam, polyurethane foam, or polymer rubber material, or inorganic material such as rock wool, glass wool, and aluminum silicate wool.

Fig. 8 is a schematic cross-sectional view of a third wall splicing structure embodiment, where the wall splicing structure includes the second screw-in type framework embodiment, the third connecting framework embodiment, the first wall and the second wall. As shown in fig. 8, the first wall 11 includes wall boards 1101, a screw-in framework is embedded between the wall boards 1101, the side boards 2 and 3 are both attached to the wall boards 1101, and the splice panel 1 of the screw-in framework serves as a connecting surface of the first wall 11; second wall body 12 includes wallboard 1201, connects between skeleton embedding wallboard 1201, and curb plate 7 and curb plate 8 all laminate with wallboard 1201, and the concatenation panel 6 of connecting the skeleton is as the connection face of first wall body 12. The matching part 103 of the screw-in type framework is jointed with the jointing part 601 of the connecting framework, the locking part 102 is matched with the positioning part 602, and the positioning convex strip 6022 of the connecting framework is inserted into the groove 1022 of the screw-in type framework to transversely lock the two walls; the snap protrusions 1011 extend into the sealing groove 6031 and are attached to the side wall of the sealing groove 6031 to form a snap, so that two walls are longitudinally locked. A sealing rubber strip 13 is arranged in the sealing groove, a sealing pressure plate 1022 of the screw-in type framework is screwed in, and the sealing rubber strip is extruded to form sealing. The sealing rubber strip 13 may be organic foam material such as polystyrene foam, phenolic foam, polyurethane foam, or polymer rubber material, or inorganic material such as rock wool, glass wool, and aluminum silicate wool.

As shown in fig. 9, fig. 9 is a diagram of relative positions of the wall splicing structure during the connection process. The splicing method of the wall connecting structure includes as shown in a in fig. 9, firstly, embedding a screw-in type skeleton into a first wall 11, embedding a connecting skeleton into a second wall 12, vertically fixing the second wall 12, and erecting the first wall 11, so that splicing surfaces of the second wall 12 and the first wall 11 are opposite, the first wall 11 and the second wall 12 are arranged at an angle, and a sealing rubber strip 13 is filled in a sealing groove 6031, just as shown in a in fig. 9. Then, the first wall 11 is moved to make the joint surface of the first wall 11 close to the joint surface of the second wall 12, and the fastening protrusion 1011 of the screw-in type framework is inserted into the sealing groove 6031 of the connecting framework, as shown in b in fig. 9. Finally, the first wall body 11 is rotated by taking the buckling protrusion 1011 as an axis, the right-angle-shaped bend of the connection part of the buckling part 101 and the locking part 102 towards the inner side ensures smooth rotation, so that the groove 1022 of the screw-in type framework is attached to the positioning convex strip 6022, the matching part 103 of the screw-in type framework is attached to the attaching part 601 of the connection framework, the buckling protrusion 1011 is attached to the side wall of the sealing groove 6031, and the sealing pressure plate 1012 extrudes the sealing rubber strip 5, so that the connection of the wall body structure is completed. By the way, more walls are spliced, fastened and installed into the whole wall in sequence, and the house wall is assembled, fastened and spliced.

When the wall body needs to be disassembled, the wall body is sequentially rotated and moved according to the sequence opposite to the splicing and installation, and the spliced wall body can be conveniently and sequentially disassembled.

Although the embodiments of the present invention have been described above, the contents thereof are merely embodiments adopted to facilitate understanding of the technical aspects of the present invention, and are not intended to limit the present invention. It will be apparent to persons skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (9)

1. A screw-in type framework is a strip-shaped section bar and is used for splicing assembled walls and comprises a splicing panel and side plates arranged on two sides of the splicing panel, and the screw-in type framework is characterized in that the splicing panel comprises a buckling part, a locking part and a matching part which are sequentially connected, the buckling part is provided with a buckling protrusion and a sealing pressing plate, and the locking part comprises a convex strip protruding towards the lateral direction of the screw-in type framework or a concave groove; the buckle bulge is arranged close to the splicing panel and is arranged as a vertical plate;

the joint of the buckling part and the locking part is provided with a rounding, a chamfer or a bend towards the inner side of the connecting keel.

2. The screw-in skeleton of claim 1, wherein a reinforcing rib is provided between the locking part and the side plate.

3. The screw-in framework of claim 1, further comprising a bottom plate, wherein the bottom plate is connected with the side plates, so that the cross section of the screw-in framework forms a full-enclosure structure.

4. A screw-in skeleton according to any one of claims 1 to 3, wherein the screw-in skeleton is formed by extrusion molding of a plastic resin or an aluminum alloy.

5. A wall splicing structure is characterized by comprising a first wall, a second wall, a screw-in type framework and a connecting framework as claimed in claims 1-4, wherein the connecting framework is a long section bar and is used for splicing assembled walls, the connecting framework comprises a splicing panel and side plates arranged on two sides of the splicing panel, the splicing panel comprises a joint part, a positioning part and a sealing part which are sequentially connected, the sealing part comprises a sealing groove, the positioning part comprises a positioning convex strip protruding towards the lateral direction of the connecting framework or a concave positioning groove, and a reinforcing rib is arranged between the positioning part and the side plates; the screw-in type framework and the connecting framework are respectively embedded into the connecting surfaces of the first wall body and the second wall body, the raised lines are matched with the positioning grooves or the grooves are matched with the positioning raised lines to form transverse locking, and the buckling bulges extend into the sealing grooves and are attached to the side walls, close to the side panels, of the sealing grooves to form buckling structures; and sealing rubber strips are filled in the sealing grooves, and the sealing pressure plates extrude the sealing rubber strips to form sealing.

6. The wall splicing structure of claim 5, wherein the engaging portion and the attaching portion are engaged and attached to each other.

7. The wall splicing structure of claim 5, wherein the connecting framework further comprises a bottom plate, and the bottom plate of the connecting framework is connected with the side plate of the connecting framework, so that the section of the connecting framework forms a full-enclosure structure.

8. The wall splicing structure of claim 5, wherein the connecting framework is formed by extruding plastic resin or aluminum alloy.

9. A method of splicing wall splicing structures according to claim 5 or 6, comprising the steps of:

1) embedding the connecting framework into the first wall body and the second wall body respectively, vertically fixing the second wall body, and erecting the first wall body so that the splicing surfaces of the second wall body and the first wall body are opposite, and the first wall body and the second wall body are arranged at an angle;

2) the first wall body is close to the second wall body, so that the buckle bulge of the first wall body extends into the sealing groove;

3) rotating the first wall body to enable the convex strips of the first wall body to be attached to the positioning grooves or the grooves to be attached to the positioning convex strips, enabling the matching parts and the attaching parts to be matched and attached tightly, and enabling the buckling bulges to be attached to the side walls of the sealing grooves to form buckling structures;

and (3) filling a sealing rubber strip in the sealing groove before the step 2).

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