CN215759787U - Assembled pouring type polyphenyl particle concrete composite wall - Google Patents

Abstract

The utility model relates to an assembly formula polyphenyl granule concrete composite wall that fills, it includes a plurality of concrete block, concrete block is the cuboid form, two upper and lower faces of concrete block are respectively for going up the accumulation face and the accumulation face down, upward set firmly the lug on the accumulation face, seted up the low groove on the accumulation face down, two faces are left side connection face and right side connection face respectively about concrete block, left side connection face is last to set firmly left lug, right side connection face is last to have seted up right recess. The operator is through going up lug and the mutual joint of low groove, realizes injecing the position of upper and lower adjacent concrete block, further improves and piles up the connection stability between the concrete block of placing from top to bottom, and through the mutual joint with left lug and right recess again, the realization is injecing the position of controlling continuous concrete block, further improves to connect the connection stability between the concrete block of placing about, and then guarantees to pile up the holistic stability of back composite wall body.

Description

Assembled pouring type polyphenyl particle concrete composite wall

Technical Field

The application relates to the field of composite wall bodies, in particular to an assembled pouring type polyphenyl particle concrete composite wall body.

Background

The composite wall body is composed of a plurality of concrete blocks, and the concrete blocks are made into an internal and external integrated structure by adding materials such as cement, sand and stone and the like into concrete synthetic raw materials. The polystyrene particles are all called expanded polystyrene foam particles, are also called expanded polystyrene particles, are prepared by expanding and foaming expandable polystyrene resin beads serving as basic raw materials, are also main aggregates of polystyrene particle thermal mortar, and have good thermal insulation effect.

The prior Chinese patent with the publication number of CN201843247U discloses an energy-saving heat-insulating cold-bridge-free reinforcement-pouring type concrete composite block, which mainly comprises pouring grooves, wherein two pouring grooves distributed at intervals are arranged on four connecting surfaces of the concrete composite block, the concrete composite block is separated along the middle parts of the two pouring grooves, dovetail grooves for clamping and fixing a heat-insulating material layer are arranged on the separating surfaces of the concrete composite block, and two side surfaces of the heat-insulating material layer are clamped and fixed in the dovetail grooves and fixedly connected with the separated concrete composite block into an integral structure; or the concrete composite block is composed of two block bodies with the same separated shape, the middle parts of four connecting surfaces of each block body are provided with a pouring groove, pouring holes are arranged in the upper pouring groove and the lower pouring groove, and two side surfaces of the heat insulation material layer are clamped in the dovetail groove and fixedly connected with the two separated block bodies into an integral structure.

In view of the above-mentioned related technologies, the inventor thinks that the energy-saving and heat-preserving cold-bridge-free reinforcement-pouring type concrete composite building block can solve the advantage of the "cold bridge" effect, but in the process of stacking the energy-saving and heat-preserving cold-bridge-free reinforcement-pouring type concrete composite building block by an operator, because the connecting surface of the energy-saving and heat-preserving cold-bridge-free reinforcement-pouring type concrete composite building block has no connecting structure with limited direction, the connecting stability of the energy-saving and heat-preserving cold-bridge-free reinforcement-pouring type concrete composite building block in the stacking process is poor.

SUMMERY OF THE UTILITY MODEL

In order to improve the connection stability of concrete block, and then guarantee to pile the holistic stability of back composite wall, this application provides a formula polyphenyl granule concrete composite wall is filled in assembly.

The application provides a pair of assembled formula of pouring polyphenyl granule concrete composite wall adopts following technical scheme:

the utility model provides an assembly formula polyphenyl granule concrete composite wall that pours into, including a plurality of concrete block, concrete block is the cuboid form, a plurality of concrete block pile up jointly and are composite wall, two faces are the surface course around the concrete block, the surface course is level and smooth form, two upper and lower faces of concrete block are respectively for going up the face of depositing and deposit the face down, it has set firmly the lug on the face to go up the face of depositing, the lower groove has been seted up on the face of depositing down, go up the mutual adaptation of lug and lower groove, two faces are the left side respectively and are connected face and right side connection face about the concrete block, the left side is connected and has set firmly left lug on the face, the right side is connected and has been seted up right recess on the face, left side lug and the mutual adaptation of right recess.

Through adopting above-mentioned technical scheme, at the in-process of operator piling concrete block, the operator is through going up lug and the mutual joint of low groove, the realization is injectd the position of upper and lower adjacent concrete block, further improve and pile up the connection stability between the concrete block of placing from top to bottom, again through with left lug and the mutual joint of right groove, the realization is injectd the position of the concrete block that links to each other about to, connect the connection stability between the concrete block of placing about further improving, and then guarantee to pile up the holistic stability of back composite wall body.

Optionally, a plurality of filling holes are formed in the concrete block, the filling holes penetrate through the concrete block, and two ends of each filling hole are respectively communicated with the upper accumulation surface and the lower accumulation surface.

Through adopting above-mentioned technical scheme, after the operator piles up a plurality of concrete block together, pour into the concrete through the filling hole, through the concrete block of fixed piling up of concrete, the stability of the concrete block in the further piling up of guaranteeing from top to bottom.

Optionally, a pouring groove is formed in the side face of the concrete block, and the pouring groove is respectively arranged on the left connecting face and the right connecting face.

Through adopting above-mentioned technical scheme, when piling up together about operator with a plurality of concrete block, through the cooperation of being connected between filling groove and the filling groove, a pore structure is constituteed jointly to two filling grooves, and the operator pours concrete between two filling grooves this moment, through concrete fixed about adjacent concrete block, further guarantees to control the stability of the concrete block in the heap.

Optionally, a heat insulation material groove is formed in the side face of the concrete block, and the heat insulation material groove is respectively arranged on the left connecting face and the right connecting face.

Through adopting above-mentioned technical scheme, the concrete block passes through the insulation material groove and realizes controlling interconnect, and further convenience of operation person places insulation material in the insulation material groove simultaneously.

Optionally, a heat insulating material strip is arranged in the heat insulating material groove, and the heat insulating material strip is connected with two adjacent concrete blocks.

Through adopting above-mentioned technical scheme, connect through the heat preservation between the insulating material strip, further improve the heat insulating ability between the concrete block, and then improve the heat preservation effect of concrete block.

Optionally, the two inner side surfaces of the heat insulation material groove are respectively and fixedly provided with an anti-skid block, and the heat insulation material strip is arranged between the two anti-skid blocks.

Through adopting above-mentioned technical scheme, when the operator placed the insulating material silo with the insulating material strip inside, increased through anti-skidding lug this moment and insulating material strip between frictional resistance, improve the insulating material strip and arrange the stability between the insulating material silo in.

Optionally, a heat insulation material layer is arranged on the side surface of the concrete block, and the heat insulation material layer is respectively arranged on the upper accumulation surface and the lower accumulation surface.

Through adopting above-mentioned technical scheme, concrete block passes through the insulation material layer and realizes interconnect between from top to bottom, and further convenience of operation person places insulation material in the insulation material layer simultaneously.

Optionally, a heat insulation material block is arranged in the heat insulation material layer, and the heat insulation material block is connected with two adjacent concrete blocks.

Through adopting above-mentioned technical scheme, through the heat preservation connection between the insulation material piece, further improve the heat insulating ability between the concrete block, and then improve the heat preservation effect of concrete block.

Optionally, the two inner side surfaces of the heat insulating material layer are respectively and fixedly provided with anti-skidding convex points, and the heat insulating material block is arranged between the two anti-skidding convex points.

Through adopting above-mentioned technical scheme, when the operator placed the insulating material piece inside the insulating material layer, increased through anti-skidding bump this moment with the insulating material piece between frictional resistance, improve the insulating material piece and arrange the stability between the insulating material layer in.

In summary, the present application includes at least one of the following beneficial technical effects:

1. in the process of stacking concrete blocks by an operator, the operator clamps the upper lug and the lower groove to limit the positions of the concrete blocks adjacent up and down, so that the connection stability between the concrete blocks stacked up and down is further improved, and then the left lug and the right groove are clamped to limit the positions of the concrete blocks connected left and right, so that the connection stability between the concrete blocks connected left and right is further improved, and the overall stability of the stacked composite wall is further ensured;

2. after an operator piles a plurality of concrete blocks together, concrete is poured in through the pouring holes, the concrete blocks piled up and down are fixed through the concrete, and the stability of the concrete blocks piled up and down is further ensured;

3. pile up when being in the same place about operator with a plurality of concrete block, through the cooperation of being connected between filling groove and the filling groove, a pore structure is constituteed jointly to two filling grooves, and the operator pours concrete this moment between two filling grooves, through concrete fixed about adjacent concrete block, further guarantees to control the stability of piling the concrete block in the step.

Drawings

Fig. 1 is a schematic diagram of the overall structure of an assembled pouring type polyphenyl particle concrete composite wall body.

Fig. 2 is a schematic view of a top view structure of a concrete block in an assembled pouring type polyphenyl particle concrete composite wall body according to the application.

Fig. 3 is a schematic view of a bottom view of a concrete block in an assembled cast-in-place polyphenyl granule concrete composite wall according to the present invention.

Fig. 4 is a schematic structural diagram of an insulating material strip and an insulating material block in an assembled pouring type polyphenyl particle concrete composite wall body.

Description of reference numerals: 1. concrete building blocks; 11. a surface layer; 12. an upper accumulation surface; 121. an upper bump; 13. a lower accumulation surface; 131. a lower groove; 14. a left connection face; 141. a left bump; 15. a right connection face; 151. a right groove; 16. a perfusion hole; 17. pouring a tank; 18. a thermal insulation material groove; 181. a strip of insulating material; 182. an anti-slip bump; 19. a thermal insulation material layer; 191. a block of insulation material; 192. and anti-skid salient points.

Detailed Description

The present application is described in further detail below with reference to the accompanying drawings.

The embodiment of the application discloses an assembled pouring type polyphenyl particle concrete composite wall.

Referring to fig. 1, the assembled and poured polyphenyl particle concrete composite wall comprises a plurality of concrete blocks 1, wherein the concrete blocks 1 are rectangular, and the plurality of concrete blocks 1 are jointly stacked in a left-right stacking mode and an upper-lower stacking mode to form the composite wall.

Referring to fig. 2, the front and back surfaces of the concrete block 1 are referred to as surface layers 11, and the surface layers 11 are flat, so that the flatness of the front and back surfaces of the built composite wall is guaranteed.

Referring to fig. 2 and 3, the upper and lower surfaces of the concrete block 1 are respectively referred to as an upper accumulation surface 12 and a lower accumulation surface 13, six kidney-shaped hole-shaped pouring holes 16 are formed in the concrete block 1, three pouring holes 16 form a group, and two groups of pouring holes 16 are respectively close to the two surface layers 11. Meanwhile, the pouring hole 16 is vertical and penetrates through the concrete block 1, and two ends of the pouring hole 16 are respectively communicated with the upper accumulation surface 12 and the lower accumulation surface 13. When an operator stacks the concrete blocks 1, concrete is poured into the concrete blocks 1 from the pouring holes 16, so that the concrete blocks 1 are connected up and down.

Referring to fig. 2 and 3, two horizontal upper bumps 121 are fixedly disposed on the upper stacking surface 12, the upper bumps 121 are strip-shaped, and the two upper bumps 121 are respectively disposed at positions close to two sides of the surface layer 11. Two horizontal lower grooves 131 are formed in the lower accumulation surface 13, the lower grooves 131 are long, the two lower grooves 131 are respectively arranged at positions close to two sides of the surface layer 11, and the upper protrusions 121 are matched with the lower grooves 131 in size and position. When a operator piles up the upper and lower concrete blocks 1, the upper convex block 121 of one concrete block 1 is clamped and matched with the lower concave groove 131 of the other concrete block 1, so that the stability of the concrete blocks 1 during vertical piling is further improved.

Referring to fig. 2 and 3, a horizontal heat insulation material layer 19 is formed on the side surface of the concrete block 1, the heat insulation material layer 19 is respectively arranged on the upper accumulation surface 12 and the lower accumulation surface 13, the heat insulation material layer 19 is arranged in the middle positions of the two upper convex blocks 121 or the two lower concave grooves 131, an operator can install heat insulation materials between the stacked concrete blocks 1 conveniently, and the heat insulation performance of the concrete block 1 is improved.

Referring to fig. 3 and 4, a heat insulation material block 191 is installed in the heat insulation material layer 19, the shape and size of the heat insulation material block 191 are matched with those of the upper heat insulation material layer 19 and the lower heat insulation material layer 19, and meanwhile, the heat insulation material block 191 connects two upper and lower adjacent concrete blocks 1. The insulation material block 191 can be made of EPS boards or polystyrene foam insulation boards or other insulation materials, and the insulation property of the concrete block 1 is further ensured through the material characteristics of the insulation material block 191.

Referring to fig. 3 and 4, anti-slip bumps 192 are respectively and fixedly arranged on two inner side surfaces of the thermal insulation material layer 19, the thermal insulation material block 191 is arranged between the two anti-slip bumps 192, when the thermal insulation material block 191 and the anti-slip bumps 192 are in mutual contact, frictional resistance between the thermal insulation material block 191 and the anti-slip bumps 192 is increased, and stability of the thermal insulation material block 191 arranged in the thermal insulation material layer 19 is further improved.

Referring to fig. 2 and 3, the left and right surfaces of the concrete block 1 are respectively referred to as a left connecting surface 14 and a right connecting surface 15, two vertical pouring grooves 17 are formed in the side surface of the concrete block 1, and the two pouring grooves 17 are a group and are respectively arranged on the left connecting surface 14 and the right connecting surface 15. When an operator stacks the concrete blocks 1, concrete is poured into the left and right adjacent concrete blocks 1 from the pouring groove 17, so that left and right connection between the concrete blocks 1 is realized.

Referring to fig. 2 and 3, two vertical left bumps 141 are fixedly disposed on the left connecting surface 14, the left bump 141 is in a long strip shape, and the two left bumps 141 are disposed at two sides of the surface layer 11 respectively. Two vertical right grooves 151 are formed in the right connecting surface 15, the right grooves 151 are long, the two right grooves 151 are respectively arranged at the positions of two sides close to the surface layer 11, and the left convex block 141 and the right grooves 151 are matched with each other in size and position. When a user stacks the left and right concrete blocks 1, the left projection 141 of one concrete block 1 is clamped and matched with the right groove 151 of the other concrete block 1, so that the stability of the left and right stacking between the concrete blocks 1 is further improved.

Referring to fig. 2 and 3, vertical heat preservation material groove 18 is opened on the side of concrete block 1, heat preservation material groove 18 is arranged on left connecting surface 14 and right connecting surface 15 respectively, heat preservation material groove 18 is arranged in the middle position of two left lugs 141 or two right grooves 151, and the operator can install heat preservation material between the concrete block 1 of piling conveniently, and the heat preservation performance of concrete block 1 is improved.

Referring to fig. 3 and 4, a heat insulating material strip 181 is installed in the heat insulating material groove 18, the shape and size of the heat insulating material strip 181 are matched with the shape and size of the upper heat insulating material groove 18 and the lower heat insulating material groove 18, and the heat insulating material strip 181 connects two left and right adjacent concrete blocks 1. The insulation material strip 181 can be made of an EPS board or a polystyrene foam insulation board or other insulation materials, and the insulation property of the concrete block 1 is further ensured by the material characteristics of the insulation material strip 181.

Referring to fig. 3 and 4, anti-slip bumps 182 are respectively and fixedly arranged on two inner side surfaces of the thermal insulation material groove 18, the thermal insulation material strip 181 is arranged between the two anti-slip bumps 182, when the thermal insulation material strip 181 is in contact with the anti-slip bumps 182, the frictional resistance between the thermal insulation material strip 181 and the anti-slip bumps 182 is increased, and the stability of the thermal insulation material strip 181 arranged in the thermal insulation material groove 18 is further improved.

The implementation principle of the assembly pouring type polyphenyl particle concrete composite wall body in the embodiment of the application is as follows: in the process of stacking the concrete blocks 1, an operator faces the upper bump 121 and the lower groove 131 to each other, faces the left bump 141 and the right groove 151 to each other, installs the insulating material strip 181 into the insulating material groove 18, installs the insulating material block 191 into the insulating material layer 19, and finally pours the concrete into the pouring hole 16 and the pouring groove 17, so that the stacking of the assembly pouring type composite wall is realized.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (9)

1. The utility model provides an assembly formula polyphenyl granule concrete composite wall that pours into which characterized in that: including a plurality of concrete block (1), concrete block (1) is the cuboid form, a plurality of concrete block (1) are piled up jointly and are composite wall, two faces are surface course (11) around concrete block (1), surface course (11) are level and smooth form, two upper and lower faces of concrete block (1) are respectively for going up accumulation face (12) and accumulation face (13) down, it has set firmly lug (121) on accumulation face (12) to go up, lower recess (131) have been seted up on accumulation face (13) down, go up lug (121) and lower recess (131) mutual adaptation, two faces are respectively for left side connection face (14) and right side connection face (15) about concrete block (1), left lug (141) have set firmly on the left side connection face (14), right side connection face (15) has seted up right recess (151), left lug (141) and right recess (151) mutual adaptation.

2. The assembled poured polyphenyl particle concrete composite wall body as claimed in claim 1, wherein: a plurality of pouring holes (16) are formed in the concrete building block (1), the pouring holes (16) penetrate through the concrete building block (1), and two ends of each pouring hole (16) are communicated with the upper accumulation surface (12) and the lower accumulation surface (13) respectively.

3. The assembled poured polyphenyl particle concrete composite wall body as claimed in claim 1, wherein: and the side surface of the concrete block (1) is provided with a pouring groove (17), and the pouring groove (17) is respectively arranged on the left connecting surface (14) and the right connecting surface (15).

4. The assembled poured polyphenyl particle concrete composite wall body as claimed in claim 1, wherein: and a heat insulation material groove (18) is formed in the side face of the concrete block (1), and the heat insulation material groove (18) is respectively arranged on the left connecting face (14) and the right connecting face (15).

5. The assembled poured polyphenyl particle concrete composite wall according to claim 4, wherein: a heat insulation material strip (181) is arranged in the heat insulation material groove (18), and the heat insulation material strip (181) is connected with two adjacent concrete blocks (1).

6. The assembled poured polyphenyl particle concrete composite wall body as claimed in claim 5, wherein: anti-skid lugs (182) are fixedly arranged on two inner side surfaces of the heat insulation material groove (18) respectively, and the heat insulation material strip (181) is arranged between the two anti-skid lugs (182).

7. The assembled poured polyphenyl particle concrete composite wall body as claimed in claim 1, wherein: the side surface of the concrete block (1) is provided with a heat insulation material layer (19), and the heat insulation material layer (19) is respectively arranged on the upper accumulation surface (12) and the lower accumulation surface (13).

8. The assembled poured polyphenyl particle concrete composite wall according to claim 7, wherein: a heat insulation material block (191) is arranged in the heat insulation material layer (19), and the heat insulation material block (191) is connected with two adjacent concrete blocks (1).

9. The assembled poured polyphenyl particle concrete composite wall according to claim 8, wherein: anti-skidding convex points (192) are fixedly arranged on two inner side surfaces of the heat insulation material layer (19) respectively, and the heat insulation material block (191) is arranged between the two anti-skidding convex points (192).

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