CN210194970U - Building heat preservation integration template quick change mould system - Google Patents

Abstract

The utility model relates to an overcome building heat preservation module among the prior art still need lay wall face concrete after pouring the completion, influence the weak point of construction quality and efficiency, provide one kind can accomplish the wall simultaneously and pour at the concrete placement in-process of building heat preservation module, need not to accomplish laying wall face concrete pouring to improve the building heat preservation integration template quick change die system of construction quality and efficiency. Its structure includes a plurality of building modules of concatenation each other, characterized by, the building module includes heat preservation module, wall body template and linking bridge, the wall body template is arranged in heat preservation module inside and outside, through linking bridge interconnect between heat preservation module and the wall body template, linking bridge and wall body template can be dismantled the connection, and the space between wall body template and the heat preservation module constitutes the wall body and pours the space.

Description

Building heat preservation integration template quick change mould system

Technical Field

The utility model relates to a building material engineering field especially relates to foam material building module field.

Background

At present, the building heat insulation module is more and more popular in the building field because of the environmental protection, low cost and convenient construction, and can replace the performance advantage of the heat insulation wallboard. The building heat preservation modular structure among the prior art mainly includes the heated board of expanded material preparation such as two parallel arrangement's EPS and installs the steel structure support between two heated boards. In the building construction, constitute the wall body through the mutual concatenation of heated board, erect the reinforcing bar on steel structure support, then the space pouring concrete between two heated boards, both can accomplish the preliminary work of putting up and pouring of wall body.

However, the building heat-insulating module and the construction method in the prior art still have certain disadvantages: because the wall construction that the current building insulation module in heated board surface found is accomplished the back, still need lay one deck wall face concrete in the outside of both sides heated board (being interior wall face) to in order to guarantee construction quality, preceding concrete and wall face concrete can restrict the efficiency of construction so greatly, and the concrete is difficult to apply paint with a brush on the heated board surface, has also increased the construction degree of difficulty.

SUMMERY OF THE UTILITY MODEL

The utility model relates to an overcome building heat preservation module among the prior art still need lay wall face concrete after pouring the completion, influence the weak point of construction quality and efficiency, provide one kind can accomplish the wall simultaneously and pour at the concrete placement in-process of building heat preservation module, need not to accomplish laying wall face concrete pouring to improve the building heat preservation integration template quick change die system of construction quality and efficiency.

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

the utility model discloses a building heat preservation integration template quick change die system, including a plurality of building modules of splicing each other, characterized by, the building module includes heat preservation module, wall form and linking bridge, the wall form arranges in heat preservation module inside and outside, through linking bridge interconnect between heat preservation module and the wall form, linking bridge and wall form can dismantle the connection, and the space constitutes the wall body and pours the space between wall form and the heat preservation module.

This scheme is when the construction, according to the actual demand, constitutes the wall body through the first concatenation of a plurality of building module and concatenation from top to bottom and pours the template, pours the concrete in the wall body pouring space between heat preservation module both sides and wall body template, treats the concrete setting back, dismantles the wall body template of both sides, can obtain building wall. The wall body is a sandwich structure formed by concrete layers on two sides and a heat preservation module layer in the middle. Because the concrete layer surface has the wall form laminating when solidifying, consequently the structure is level and smooth can directly carry out further construction such as fitment, need not additionally to lay concrete layer again, has effectively improved construction quality and efficiency. And the disassembled wall template can be reused, so that the cost is reduced, the construction waste is reduced, and the wall template is more environment-friendly.

Preferably, the connecting support comprises a connecting bridge, an embedded part and connecting parts, the embedded part is arranged on one side of the connecting bridge, the connecting parts are arranged on the other side of the connecting bridge, the connecting parts are arranged on one side, away from the connecting bridge, of the embedded part, the embedded part is embedded into the heat-insulating module, and the connecting parts are detachably connected with the wall formwork.

The connecting bridge is used for connecting the wall formwork and the heat preservation module, can stably support the wall pouring space, enables concrete pouring to be smooth and convenient, plays a role of reinforcing steel bars in the reinforced concrete wall and enhances the structural strength of the wall body after pouring is completed.

Preferably, the connecting supports are arranged in parallel at intervals along the length direction of two side surfaces of the heat preservation module.

As preferred, a side edge that connecting bridge and built-in fitting kept away from each other respectively sets up three at least connecting pieces, the connecting piece end sets up the threaded rod, and wall template rectangular array has arranged a plurality of connecting holes, every row quantity and connecting piece quantity on the connecting hole along wall template width direction correspond, the threaded rod at connecting rod end is pegged graft the connecting hole, the threaded rod passes the connecting hole is provided with the screw thread setting element at the end.

The connecting piece realizes the detachable connection with the wall body template through the threaded rod at the tail end, and the wall body template is easily detached after the concrete is solidified. And can finely tune the feeding degree of depth of every threaded rod grafting wall form through the screw thread setting element to finely tune the spacing distance between wall form and the heat preservation module, perhaps finely tune the angle between wall form and the heat preservation module, thereby can guarantee that all wall forms of splicing in the building module together can level and smooth the concatenation, thereby make the concrete wall after the shaping more level and more smooth, easily subsequent construction.

Preferably, the connecting bracket further comprises a reinforcing bar positioning member which is shaped as a hook.

Preferably, the top and the bottom of connecting the bridge set up a plurality of reinforcing bar location spare respectively, and the connecting piece that is located topmost and bottommost sets up the reinforcing bar location spare.

The reinforcing steel bar positioning piece can position the reinforcing steel bar through the hook-shaped structure. Therefore, the reinforcing steel bars can be erected in the wall body pouring space according to the construction requirements before concrete is poured, the poured concrete wall body is the reinforced concrete wall body, and the structural strength of the reinforced concrete wall body is obviously improved.

Preferably, the top end surface and the bottom end surface of the heat preservation module are provided with inserting protrusions and inserting grooves at intervals, and the inserting protrusions and the inserting grooves on the top end surface and the bottom end surface are arranged in a staggered mode.

The heat preservation module in the building module that the wall direction of height spliced stack from top to bottom passes through grafting arch and grafting recess peg graft each other, helps building module stack concatenation in height. And the connection stability and the structure uniformity between adjacent building modules can be improved, and the quality of the poured wall body is improved.

Preferably, a plurality of strip-shaped grooves are formed in the side face of the heat preservation module and extend along the width direction of the side face of the heat preservation module.

In the concrete pouring process, partial concrete can enter the strip-shaped groove, so that the connection strength between the poured concrete wall and the heat preservation module is higher, and the concrete wall is not easy to peel off.

Preferably, the building modules comprise any one or a combination of a plurality of straight line building modules, corner building modules or T-shaped building modules.

Preferably, the heat-insulating module in the linear building module is in a cube shape, the wall formwork is in a rectangular plate shape corresponding to the shape of the side face of the heat-insulating module, and the wall formwork is arranged in parallel with the heat-insulating module; the shape of the heat insulation module in the corner building module is an L-shaped cube, and the shape of the wall body template is an L-shaped plate shape corresponding to the shape of the heat insulation module corresponding to the heat insulation module; the T-shaped building module is characterized in that the heat insulation module is in a cube shape, the wall body template on one side of the heat insulation module is in a rectangular plate shape corresponding to the shape of the side face of the heat insulation module, and the other side of the heat insulation module is provided with two L-shaped wall body templates.

In order to adapt to different wall cross section structures, the scheme comprises a straight line building module, a corner building module, a T-shaped building module and the like. The straight line building modules are used for construction of large-area plane wall surfaces, the corner building modules are used for construction of wall surfaces at corners, and the T-shaped building modules can be applied to construction of intercrossed wall surfaces. Therefore, the scheme can meet the working conditions of all wall construction in building construction.

Therefore, the utility model has the advantages of it is following: (1) the wall surface pouring is completed simultaneously in the concrete pouring process, and the wall surface concrete does not need to be laid after the pouring is completed, so that the construction quality and the construction efficiency are improved; (2) the pouring work of the wall body and the wall surface is finished at one time, and the finished concrete wall surface is smooth and easy for subsequent construction; (3) the heat insulation module has low cost, environmental protection, easy production and good heat insulation performance, and the construction wall body does not need to be added with a heat insulation board, thereby improving the efficiency and reducing the cost; (4) the wall template can be disassembled for reuse, the operation is convenient, and the cost is low; (5) the steel bars can be erected for pouring, and the structural strength of the wall body can be guaranteed; (6) is suitable for the forming construction of wall bodies with various shapes.

Drawings

Fig. 1 is a schematic structural diagram of a building module according to an embodiment of the present invention.

Fig. 2 is a side view schematic diagram of a building module according to an embodiment of the present invention.

Fig. 3 is a schematic top view of a building module according to an embodiment of the present invention.

Fig. 4 is a schematic structural diagram of a connecting bracket according to an embodiment of the present invention.

Fig. 5 is a schematic structural view of a wall form according to an embodiment of the present invention.

Fig. 6 is a schematic structural diagram of a linear building module according to an embodiment of the present invention.

Fig. 7 is a schematic structural view of a corner building module according to an embodiment of the present invention.

Fig. 8 is a schematic structural diagram of a t-shaped building module according to an embodiment of the present invention.

In the figure: 1, a heat preservation module; 101, inserting a bulge; 102 inserting and connecting a groove; 103 a strip-shaped groove; 2, wall formworks; 201 connecting holes; 3 connecting the bracket; 301 connecting the bridges; 302 an embedded part; 303 a connecting piece; 304 a threaded rod; 305 locking a positioning nut; 306 a rebar positioning element.

Detailed Description

The invention is further described with reference to the drawings and the detailed description.

As shown in fig. 1 and 2, the utility model discloses a building heat preservation integration template quick change die system, including a plurality of building modules of splicing each other, building module includes heat preservation module 1, wall form 2 and linking bridge 3, wall form 2 arranges in heat preservation module 1 inside and outside, through linking bridge 3 interconnect between heat preservation module 1 and the wall form 2, linking bridge 3 and wall form 2 can dismantle the connection, and the space constitutes the wall body and pours the space between wall form 2 and the heat preservation module 1.

This scheme is when the construction, according to the actual demand, constitutes the wall body through the first concatenation of a plurality of building module and concatenation from top to bottom and pours the template, pours the concrete in the wall body pouring space between 1 both sides of thermal module and wall body template 2, treats the concrete setting back, dismantles the wall body template 2 of both sides, can obtain building wall. The wall body is a sandwich structure formed by concrete layers on two sides and a heat preservation module 1 layer in the middle.

As shown in fig. 2 and 4, the connecting brackets 3 are arranged in parallel at intervals along the length direction of the two side surfaces of the thermal insulation module 1. The connecting support 3 comprises a connecting bridge 301, an embedded part 302 and connecting pieces 303, wherein the embedded part 302 is arranged on one side of the connecting bridge 301, the connecting pieces 303 are arranged on the other side of the connecting bridge 301, the connecting pieces 303 are arranged on one side, far away from the connecting bridge 301, of the embedded part 302, the embedded part 302 is embedded into the heat preservation module 1, and the connecting pieces 303 are detachably connected with the wall formwork 2. In this embodiment, the connecting bridge 301 and the embedded part 302 are a field-shaped structure formed by connecting a plurality of vertically connected steel beams, and may be other planar frame structures.

Connecting bridge 301 is used for connecting wall template and heat preservation module 1, can stabilize and support the wall body and pour the space, makes concrete placement more convenient smoothly to play the effect of reinforcing bar in the reinforced concrete wall, the reinforcing is pour the structural strength of accomplishing back wall body. The embedded part 302 can be embedded in the heat insulation module 1 in the foaming molding of the heat insulation module 1, so that the whole connecting bracket 3 and the heat insulation module 1 can be integrally molded and produced, the connecting strength is high, and the processing efficiency is high.

Three connecting pieces 303 are respectively arranged at the edges of one side of the connecting bridge 301 and the embedded part 302 far away from each other, and a threaded rod 304 is arranged at the tail end of each connecting piece 303. The connecting bracket 3 is of an integrally formed structure.

As shown in fig. 5, a plurality of connecting holes 201 are arranged in a rectangular array of the wall form, the number of each row of the connecting holes 201 in the width direction of the wall form is three, the number of the connecting holes is corresponding to the number of the connecting pieces 303, a threaded rod 304 at the tail end of the connecting rod is inserted into the connecting holes 201, and the threaded rod 304 penetrates through the connecting holes 201 and is provided with a threaded positioning piece at the tail end. The threaded positioning element may be a nut or the like that is screwed to achieve locking and positioning, and the locking and positioning nut 305 is adopted in this embodiment.

The connecting piece 303 is detachably connected with the wall form 2 through a threaded rod 304 at the tail end, and the wall form 2 is easy to detach after the concrete is solidified. And can finely tune the feeding degree of depth that every threaded rod 304 pegs graft wall form 2 through the screw thread setting element to finely tune the interval distance between wall form 2 and the heat preservation module 1, perhaps finely tune the angle between wall form 2 and the heat preservation module 1, thereby can guarantee that all wall forms 2 of splicing in the building module together can level and smooth the concatenation, thereby make the concrete wall after the shaping more level and more smooth, easily subsequent construction.

The connecting bracket 3 further comprises a reinforcement positioning member 306, and the reinforcement positioning member 306 is shaped as a hook. The top and bottom of the connecting bridge 301 are respectively provided with a plurality of reinforcing steel bar positioning members 306, and the connecting members 303 at the top and bottom are provided with reinforcing steel bar positioning members 306.

The reinforcing bar positioning member 306 may position the reinforcing bars by means of its hook-shaped structure. Therefore, the reinforcing steel bars can be erected in the wall body pouring space according to the construction requirements before concrete is poured, the poured concrete wall body is the reinforced concrete wall body, and the structural strength of the reinforced concrete wall body is obviously improved.

As shown in fig. 1 and fig. 3, the top end surface and the bottom end surface of the thermal insulation module 1 are provided with insertion protrusions 101 and insertion grooves 102 at intervals, and the insertion protrusions 101 and the insertion grooves 102 on the top end surface and the bottom end surface are arranged in a staggered manner. A plurality of strip-shaped grooves 103 are arranged along the side surface of the heat preservation module 1, and the strip-shaped grooves 103 extend along the width direction of the side surface of the heat preservation module 1.

The heat preservation module 1 in the building modules spliced and overlapped up and down in the height direction of the wall surface is mutually spliced through the splicing protrusions 101 and the splicing grooves 102, and the building modules are spliced and overlapped in height. And the connection stability and the structure uniformity between adjacent building modules can be improved, and the quality of the poured wall body is improved.

In the concrete pouring process, partial concrete can enter the strip-shaped groove 103, so that the connection strength between the poured concrete wall and the heat preservation module 1 is higher and the concrete wall is not easy to peel off.

The heat-insulating module 1 is made of expanded plastic materials such as EPS (expandable polystyrene), and the wallboard template can be made of materials such as plastics or wood which are not bonded with concrete. The heat preservation module 1 layer that constitutes by the concatenation of heat preservation module 1 that is located the centre has good heat preservation heat-proof quality, need not additionally to process insulation construction after the construction, can realize the heat retaining performance requirement of wall body, reduces the construction degree of difficulty and cost, improves the efficiency of construction. And the heat preservation module 1 made of EPS and other plastic foaming materials has high strength, light weight, convenient processing and transportation, environmental protection and no pollution. The concrete layers on both sides provide structural strength for the support. Because the concrete layer surface has the laminating of wall form 2 when solidifying, consequently the structure is leveled and further construction such as fitment can be directly carried out, need not additionally to lay concrete layer again, has effectively improved construction quality and efficiency. And the disassembled wall form 2 can be reused, so that the cost is reduced, the construction waste is reduced, and the wall form is more environment-friendly. This scheme adopts the construction of modular building module to carry out building wall, and is with low costs, and construction speed possesses obvious advantage than traditional technology, easily popularizes, especially the lower area of temperature throughout the year, has effectively practiced thrift the purchase and the construction cost of heated board.

Furthermore, the embodiment of the utility model provides an in a building module that points out among building heat preservation integration template quick change mould system is according to its construction requirement that adapts to different wall structures, and adjusts the structural shape of heat preservation module 1 and wall form 2 to constitute the building module of different shape types, thereby splice these building modules according to the construction demand and constitute one set of complete wall molding system. The building modules can comprise any one or combination of a plurality of straight line building modules, corner building modules or T-shaped building modules.

As shown in fig. 6, the heat preservation module 1 in the linear building module is cube-shaped, the wall form 2 is rectangular plate-shaped corresponding to the shape of the side surface of the heat preservation module 1, and the wall form 2 is arranged parallel to the heat preservation module 1.

As shown in fig. 7, the heat preservation module 1 in the corner building module is in an L-shaped cube, and the wall form 2 is in an L-shaped plate shape corresponding to the heat preservation module 1 and corresponding to the heat preservation module 1.

As shown in fig. 8, the heat preservation module 1 in the t-shaped building module is cube-shaped, the wall form 2 on one side of the heat preservation module 1 is rectangular plate-shaped corresponding to the shape of the side face of the heat preservation module 1, and two L-shaped wall forms 2 are arranged on the other side of the heat preservation module 1.

In order to adapt to different wall cross section structures, the scheme comprises a straight line building module, a corner building module, a T-shaped building module and the like. The straight line building modules are used for construction of large-area plane wall surfaces, the corner building modules are used for construction of wall surfaces at corners, and the T-shaped building modules can be applied to construction of intercrossed wall surfaces. Therefore, the scheme can meet the working conditions of all wall construction in building construction.

Claims (9)

1. The utility model provides a building heat preservation integration template quick change die system, includes a plurality of building modules of splicing each other, characterized by, the building module includes heat preservation module, wall form and linking bridge, the wall form arranges in heat preservation module inside and outside, through linking bridge interconnect between heat preservation module and the wall form, linking bridge and wall form can dismantle the connection, and the space is pour to the interval space constitution wall body between wall form and the heat preservation module.

2. The building heat preservation integrated formwork quick-change mold system as claimed in claim 1, wherein the connecting bracket comprises a connecting bridge, an embedded part and a connecting part, wherein the embedded part is arranged on one side of the connecting bridge, the connecting parts are arranged on the other side of the connecting bridge, the connecting parts are arranged on one side of the embedded part away from the connecting bridge, the embedded part is embedded in the heat preservation module, and the connecting part is detachably connected with the wall formwork.

3. The building insulation integrated formwork quick-change system as claimed in claim 1, wherein the connecting brackets are arranged in parallel at intervals along the length direction of the two side surfaces of the insulation module.

4. The building insulation integrated formwork quick-change system as claimed in claim 2, wherein the connecting bracket further comprises a reinforcement positioning member, and the reinforcement positioning member is configured in a hook shape.

5. The building heat preservation integrated formwork quick-change system as claimed in claim 4, wherein the top end and the bottom end of the connecting bridge are respectively provided with a plurality of steel bar positioning members, and the connecting members positioned at the topmost end and the bottommost end are provided with steel bar positioning members.

6. The building heat preservation integrated template quick-change mold system as claimed in claim 1, wherein the heat preservation module is provided with insertion protrusions and insertion grooves at intervals on the top end face and the bottom end face, and the insertion protrusions and the insertion grooves on the top end face and the bottom end face are arranged in a staggered manner.

7. The building insulation integrated formwork quick-change system as claimed in claim 1, wherein a plurality of strip-shaped grooves are arranged along the side surface of the insulation module, and the strip-shaped grooves extend along the width direction of the side surface of the insulation module.

8. The building heat preservation integrated template quick-change mold system as claimed in claim 1, wherein the building modules comprise any one or a combination of a plurality of straight line building modules, corner building modules or T-shaped building modules.

9. The building heat preservation integrated formwork quick-change system as claimed in claim 8, wherein the heat preservation module in the straight line building module is cube-shaped, the wall formwork is rectangular plate-shaped corresponding to the shape of the side face of the heat preservation module, and the wall formwork is arranged in parallel with the heat preservation module; the shape of the heat insulation module in the corner building module is an L-shaped cube, and the shape of the wall body template is an L-shaped plate shape corresponding to the shape of the heat insulation module corresponding to the heat insulation module; the T-shaped building module is characterized in that the heat insulation module is in a cube shape, the wall body template on one side of the heat insulation module is in a rectangular plate shape corresponding to the shape of the side face of the heat insulation module, and the other side of the heat insulation module is provided with two L-shaped wall body templates.

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