CN210562806U - Building module splicing wall - Google Patents

Abstract

The embodiment of the utility model discloses a building module splicing wall body, which relates to the technical field of building wall structures, and the key points of the technical proposal of the utility model comprise a first heat-insulating wallboard and a second heat-insulating wallboard which are parallel, a casting cavity is formed between the first heat-insulating wallboard and the second heat-insulating wallboard, a structural column is vertically arranged in the casting cavity, and a concrete block is cast in the casting cavity; the first heat-insulation wallboard and/or the second heat-insulation wallboard are formed by sequentially splicing a plurality of heat-insulation boards respectively; on first heat preservation wallboard and the second heat preservation wallboard and be located and can dismantle between two relative heated boards and be connected with the connecting elements. The problem of thereby receive destruction easily because EPS module intermediate junction bridge can not dismantle among the prior art is solved in order to solve.

Description

Building module splicing wall

Technical Field

The embodiment of the utility model provides a building wall technical field, concretely relates to building module concatenation wall body is related to.

Background

EPS building module, by fire-retardant type polystyrene foam module as template and heat preservation insulating layer, the concrete surface course is pour to the center core, plaster or radiate the novel composite wall body that panel and formed, EPS module application face is very wide, can extensively be used for civil residential building, public building, cities and towns and rural house transformation and industrial heat preservation factory building and agricultural greenhouse, high-rise and low-rise high-grade villa etc. in addition, EPS building module has good thermal insulation performance and heat-proof quality, be applicable to chilly north and hot south.

The existing EPS building template is connected by adopting the foam made of the same material when the insulation boards on the two sides are connected, so that the insulation boards on the two sides are fixed.

1. When the EPS building module is transported, the EPS building module occupies a large volume, is high in transportation cost and is easy to damage in the transportation/use process.

2. The EPS module among the prior art is because to the foam board of both sides heated board connecting piece as integrated into one piece, when building, the whole shock resistance of wall body is lower, and simultaneously, the mouse probably gets into indoor destruction wall body from the connecting piece position.

3. The foam connecting piece has low lateral pressure resistance and is often cracked and damaged during construction.

SUMMERY OF THE UTILITY MODEL

Therefore, the embodiment of the utility model provides a building module concatenation wall body to thereby solve among the prior art because EPS module intermediate junction bridge can not dismantle the problem that suffers destruction easily.

In order to achieve the above object, the embodiment of the present invention provides the following technical solutions:

according to the embodiment of the utility model, a building module splicing wall is provided, the key points of the technical proposal of the utility model comprise a first heat-insulating wallboard and a second heat-insulating wallboard which are parallel, a casting cavity is formed between the first heat-insulating wallboard and the second heat-insulating wallboard, a structural column is vertically arranged in the casting cavity, and a concrete block is cast in the casting cavity; the first heat-insulation wallboard and/or the second heat-insulation wallboard are formed by sequentially splicing a plurality of heat-insulation boards respectively; on first heat preservation wallboard and the second heat preservation wallboard and be located and can dismantle between two relative heated boards and be connected with the connecting elements.

Furthermore, the two opposite insulation boards on the first insulation wallboard and the second insulation wallboard are respectively a first insulation board and a second insulation board; inserting grooves are respectively formed in the first heat-insulating plate and the second heat-insulating plate, and the connecting member comprises a connecting plate and inserting plates, wherein the connecting plate is positioned in a cavity between the two first heat-insulating plates and the second heat-insulating plate, and the inserting plates are positioned at two ends of the connecting plate and detachably inserted in the inserting grooves; the connecting component is made of plastic.

Furthermore, the insertion groove is T-shaped, an opening for the insertion plate to penetrate out is formed on one side close to the casting cavity, the section of the insertion plate is T-shaped, and the insertion plate is inserted into the insertion groove.

Furthermore, rib plates perpendicular to the side faces of the connecting plates are arranged at two ends of each connecting plate, and the planes of the rib plates are perpendicular to the length direction of the connecting plates.

Furthermore, a plurality of first through holes are formed in the side wall of the connecting plate; the inserting plate comprises a linkage plate and a fixed plate, the linkage plate penetrates through the opening, the fixed plate is perpendicular to the linkage plate, and a plurality of second through holes are formed in the linkage plate.

Furthermore, two adjacent insulation boards on the first insulation wallboard and/or the second insulation wallboard are a third insulation board and a fourth insulation board, the third insulation board is positioned on the upper side of the fourth insulation board, an insertion block is arranged on one side of the third insulation board close to the fourth insulation board and in the length direction of the third insulation board, and an elongated slot for the insertion block to be inserted is formed in one side of the fourth insulation board close to the third insulation board; the vertical two sides of the heat-insulation plate are respectively provided with a clamping groove and a clamping block.

Furthermore, the insert blocks comprise square insert blocks and long insert blocks, and the square insert blocks and the long insert blocks are sequentially arranged in a crossed manner; the long slot comprises a square slot and a long slot which are arranged in a crossed manner; the connecting components are respectively fixed at the positions of the square insertion block and the square insertion groove.

Further, the structure post is the steel reinforcement cage of vertical setting, first heat preservation wallboard forms the structure chamber of rectangle to keeping away from the evagination of one side of second heat preservation wallboard, the structure post sets up the structure intracavity.

Furthermore, the vertical two sides of the first heat-insulating wallboard and the second heat-insulating wallboard are respectively provided with a bonding groove.

Furthermore, a plurality of reinforcing steel bars are inserted into the pouring cavity and at intervals on two sides of the structural column.

The embodiment of the utility model provides a have following advantage:

the embodiment of the utility model provides a detachable connecting elements through setting up connects two heated boards, when the transportation, can dismantle the separation to heated board, connecting elements, and the expense is saved in the space of practicing thrift during the transportation. Meanwhile, the overall anti-seismic effect of the wall body is better when the wall body is built through the arranged plastic connecting members. When the concrete is poured, the concrete cannot be aged, and a mortar layer cannot crack, run and seep water. Meanwhile, after the building is completed, the solid wall bodies are arranged between the heat insulation plates, the problem that the wall bodies are damaged due to gnawing of mice is avoided, and the practicability is higher.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It should be apparent that the drawings in the following description are merely exemplary, and that other embodiments can be derived from the drawings provided by those of ordinary skill in the art without inventive effort.

The structure, ratio, size and the like shown in the present specification are only used for matching with the content disclosed in the specification, so as to be known and read by people familiar with the technology, and are not used for limiting the limit conditions which can be implemented by the present invention, so that the present invention has no technical essential significance, and any structure modification, ratio relationship change or size adjustment should still fall within the scope which can be covered by the technical content disclosed by the present invention without affecting the efficacy and the achievable purpose of the present invention.

Fig. 1 is a top view of a building module splicing wall provided by an embodiment of the present invention;

fig. 2 is a side view of a building module splicing wall provided in embodiment 2 of the present invention;

fig. 3 is an explosion diagram of a building module splicing wall body provided in embodiment 3 of the present invention, in which a connection structure of a third insulation board and a fourth insulation board is protruded;

fig. 4 is a schematic view of a third insulation board protruding from a building module splicing wall body provided in embodiment 2 of the present invention;

fig. 5 is a schematic view of a protruding connection member in a building module splicing wall provided in embodiment 2 of the present invention;

fig. 6 is a structural diagram of a protruded connecting member in a building module splicing wall body provided in embodiment 2 of the present invention;

fig. 7 is a schematic view of a protruding structural cavity in a building module splicing wall body provided by the utility model embodiment 2.

In the figure: 1. a first heat-insulating wall panel; 11. a third insulation board; 111. inserting a block; 1111. a square insertion block; 1112. A long insert block; 12. a fourth insulation board; 121. a long groove; 1211. a square slot; 1212. a long slot; 122. A clamping groove; 123. a clamping block; 13. a first heat-insulating plate; 14. a second insulation board; 141. inserting grooves; 142. an opening; 15. a structural cavity; 2. a second thermal insulation wallboard; 21. a bonding groove; 3. pouring a cavity; 31. A structural column; 32. a concrete block; 33. a reinforcing bar rod; 4. a connecting member; 41. a connecting plate; 411. a first through hole; 412. a rib plate; 42. a plugboard; 421. a linkage plate; 4211. a second through hole; 422. and (7) fixing the plate.

Detailed Description

The present invention is described in terms of specific embodiments, and other advantages and benefits of the present invention will become apparent to those skilled in the art from the following disclosure. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

In the present specification, the terms "upper", "lower", "left", "right", "middle", and the like are used for the sake of clarity only, and are not intended to limit the scope of the present invention, and changes or adjustments of the relative relationship thereof are also considered to be the scope of the present invention without substantial changes in the technical content.

A building module splicing wall body is shown in figures 1-7 and comprises a first heat-insulation wall plate 1 and a second heat-insulation wall plate 2 which are arranged in parallel, a pouring cavity 3 is formed between the first heat-insulation wall plate 1 and the second heat-insulation wall plate 2, a structural column 31 is arranged in the pouring cavity 3, and meanwhile, a concrete block 32 is further poured in the pouring cavity 3. When in use, through the concrete block 32, its main bearing effect of structural column 31 that set up between first heat preservation wallboard 1 and second heat preservation wallboard 2, and the first heat preservation wallboard 1 and the second heat preservation wallboard 2 of both sides are used for keeping warm to concrete block 32.

Wherein, first heat preservation wallboard 1 and/or second heat preservation wallboard 2 include the polylith heated board respectively, and the polylith heated board adopts the form of concatenation. The splicing structure will now be further described by taking the first thermal insulation wallboard 1 as an example.

First heat preservation wallboard 1 includes the polylith heated board, and two adjacent heat preservation wallboards are third heated board 11 and fourth heated board 12 respectively, wherein, third heated board 11 sets up the upside at fourth heated board 12, and one side integrated into one piece that just is close to fourth heated board 12 on third heated board 11 has inserted block 111, and the elongated slot 121 that supplies inserted block 111 to peg graft is seted up on fourth heated board 12 and one side that is close to third heated board 11, thereby, can realize dismantling the connection between two adjacent third heated boards 11 of vertical direction and fourth heated board 12.

The insertion block 111 includes a square insertion block 1111 and a long insertion block 1112, the square insertion block 1111 and the long insertion block 1112 are sequentially crossed, the long groove 121 includes a square insertion groove 1211 and a long insertion groove 1212 which are sequentially crossed, when the insertion block is installed in a fitting manner, the square insertion block 1111 is inserted into the square insertion groove 1211, and the long insertion block 1112 is inserted into the long insertion groove 1212. Therefore, the third insulation board 11 and the fourth insulation board 12 in the vertical direction are fixed more stably.

The both sides of every heated board are provided with joint groove 122 and joint piece 123 respectively on the horizontal direction, and joint piece 123 at two adjacent heated boards of horizontal direction can the joint in joint groove 122. Therefore, the splicing installation of a plurality of insulation boards is realized. When transporting, can separately transport polylith heated board, take up an area of the space for a short time, when needs are built, can splice, install at the scene.

Further, in the construction process, in order to make the positions of the first heat-insulating wall panel 1 and the second heat-insulating wall panel 2 relatively stable, and simultaneously, after the construction is completed, the connection between the heat-insulating wall panels and the concrete block 32 is tight, a connecting member 4 for fixedly connecting the first heat-insulating wall panel 1 and the second heat-insulating wall panel 2 is arranged between the two.

Wherein, connecting elements 4 set up on two relative heated boards, and two relative heated boards are first heated board 13 and second heated board 14 respectively, and connecting elements 4 can dismantle with first heated board 13 and second heated board 14 respectively and be connected.

The connecting members 4 are respectively arranged on the upper and lower sides of the first heat-insulating plate 13 and the second heat-insulating plate 14, and a plurality of groups of connecting members 4 are respectively arranged on the upper side or the lower side of the first heat-insulating plate 13 and/or the second heat-insulating plate 14 at intervals. Thereby, when using, the fixed effect preferred of heated board.

Inserting grooves 141 are respectively formed in the thickness direction of the first heat-insulating plate 13 and the second heat-insulating plate 14 at intervals, the inserting grooves 141 are arranged in a T shape, and an opening 142 is formed at one side of the first heat-insulating plate 13, which is close to the second heat-insulating plate 14.

The connecting member 4 includes a connecting plate 41 located between the first heat-insulating plate 13 and the second heat-insulating plate 14, and a plugging plate 42 disposed at two ends of the connecting plate 41 and capable of being plugged in the plugging groove 141, and the connecting plate 41 and the plugging plate 42 are both made of plastic material, and are fixed to the first heat-insulating plate 13 and the second heat-insulating plate 14 through the plugging plate 42, and are connected to each other through the connecting plate 41 therebetween, so that the positions of the connecting member are kept stable.

The socket board 42 is also configured in a "T" shape, and includes a linking board 421 that penetrates through the opening 142 of the socket and is connected and fixed with the connecting board 41, and a fixing board 422 perpendicular to the linking board 421, and in design, both the fixing board 422 and the linking board 421 are located in the socket groove 141.

Seted up a plurality of first through-holes 411 on connecting plate 41, seted up second through-hole 4211 on linkage board 421, when using, connecting plate 41 is located first heated board 13, between the second heated board 14, thereby, at the in-process of pouring concrete, the concrete can pass first through-hole 411, second through-hole 4211, thereby it is fixed with first connecting plate 41, make its position stable, thereby make first heated board 13, second heated board 14 and between the concrete piece 32 bond inseparabler.

Furthermore, the two ends of the connecting plate 41 are provided with the rib plates 412 perpendicular to the connecting plate 41, and when the heat insulation plate is installed, the rib plates 412 abut against the inner side of the heat insulation plate, so that the heat insulation plate is protected to a certain extent.

The distance between the inserting groove 141 and the side surface of the first heat insulation plate 13 or the second heat insulation plate 14 far away from each other is kept between 8mm and 10 mm. Therefore, the internal plug board 42 is located inside the first heat insulation board 13 and the second heat insulation board 14 and is not communicated with the outside, the plastic part is completely in a sealing state and is not in contact with oxygen, and aging is not easy to occur in the using process. Meanwhile, when concrete is poured, the phenomena of slurry leakage, cracking and water seepage can not occur.

The structural column 31 in the pouring cavity 3 is made of a reinforcement cage, a plurality of reinforcement rods 33 are arranged on two sides of the reinforcement cage respectively, and the concrete block 32 is supported strongly through the arranged reinforcement cage, so that the bearing capacity of the concrete block 32 is improved.

In the use process, in order to prevent the structure of the structural column 31 from being overlarge, a rectangular structural cavity 15 is convexly formed on the side, away from the second heat-insulation wall plate 2, of the first heat-insulation wall plate 1, and the structural column 31 is arranged in the structural cavity 15.

Finally, the vertical two sides of the first heat-insulating wall plate 1 and the second heat-insulating wall plate 2 are respectively provided with a bonding groove 21 for enhancing the bonding strength between the first heat-insulating wall plate and the concrete block 32. .

Although the invention has been described in detail with respect to the general description and the specific embodiments, it will be apparent to those skilled in the art that modifications and improvements can be made based on the invention. Therefore, such modifications and improvements are intended to be within the scope of the invention as claimed.

Claims (9)

1. The utility model provides a building module concatenation wall body which characterized in that: the concrete pouring device comprises a first heat-insulation wallboard (1) and a second heat-insulation wallboard (2) which are parallel, a pouring cavity (3) is formed between the first heat-insulation wallboard (1) and the second heat-insulation wallboard (2), a structural column (31) and a concrete block (32) are vertically arranged in the pouring cavity (3);

the first heat-insulation wallboard (1) and/or the second heat-insulation wallboard (2) are formed by sequentially splicing a plurality of heat-insulation boards respectively;

a connecting component (4) is detachably connected between the two opposite insulation boards on the first insulation wallboard (1) and the second insulation wallboard (2);

and the vertical two sides of the first heat-insulating wallboard (1) and the second heat-insulating wallboard (2) are respectively provided with a bonding groove (21).

2. The building module splicing wall body as claimed in claim 1, wherein: the two opposite insulation boards on the first insulation wallboard (1) and the second insulation wallboard (2) are respectively a first insulation board (13) and a second insulation board (14);

inserting grooves (141) are respectively formed in the first heat-insulating plate (13) and the second heat-insulating plate (14), and the connecting member (4) comprises a connecting plate (41) positioned in a cavity between the two first heat-insulating plates (13) and the second heat-insulating plate (14) and inserting plates (42) which are positioned at two ends of the connecting plate (41) and are detachably inserted in the inserting grooves (141); the connecting component (4) is made of plastic.

3. The building module splicing wall body as claimed in claim 2, wherein: the insertion groove (141) is T-shaped, an opening (142) for the insertion plate (42) to penetrate out is formed on one side close to the pouring cavity (3), the section of the insertion plate (42) is T-shaped, and the insertion plate (42) is inserted into the insertion groove (141).

4. The building module splicing wall body as claimed in claim 3, wherein: and rib plates (412) vertical to the side surfaces of the connecting plates (41) are arranged at two ends of each connecting plate (41), and the planes of the rib plates (412) are vertical to the length direction of the connecting plates (41).

5. The building module splicing wall body as claimed in claim 4, wherein: a plurality of first through holes (411) are formed in the side wall of the connecting plate (41); the plug board (42) comprises a linkage board (421) which penetrates out of the opening (142) and a fixing board (422) which is vertical to the linkage board (421), and a plurality of second through holes (4211) are formed in the linkage board (421).

6. The building module splicing wall body as claimed in claim 1, wherein: the first heat-insulation wallboard (1) and/or the second heat-insulation wallboard (2) are provided with a third heat-insulation board (11) and a fourth heat-insulation board (12), the third heat-insulation board (11) is positioned at the upper side of the fourth heat-insulation board (12),

an inserting block (111) is arranged on one side, close to a fourth heat-insulation board (12), of the third heat-insulation board (11) in the length direction of the third heat-insulation board, and a long groove (121) for inserting the inserting block (111) is formed in one side, close to the third heat-insulation board (11), of the fourth heat-insulation board (12);

the vertical two sides of the heat insulation plate are respectively provided with a clamping groove (122) and a clamping block (123).

7. The building module splicing wall body as claimed in claim 6, wherein: the insert block (111) comprises a square insert block (1111) and a long insert block (1112), and the square insert block (1111) and the long insert block (1112) are sequentially arranged in a crossed manner; the long groove (121) comprises a square insertion groove (1211) and a long insertion groove (1212) which are arranged in a crossed mode; the connecting component (4) is respectively fixed at the position of the square insertion block (1111) and the position of the square insertion groove (1211).

8. The building module splicing wall body as claimed in claim 1, wherein: structural column (31) is the steel reinforcement cage of vertical setting, first heat preservation wallboard (1) is to keeping away from one side evagination formation rectangle's of second heat preservation wallboard (2) structural cavity (15), structural column (31) set up in structural cavity (15).

9. The building module splicing wall body as claimed in claim 1, wherein: and a plurality of reinforcing steel bar rods (33) are inserted into the pouring cavity (3) and at intervals at two sides of the structural column (31).

Images