CN206256611U - A sintered anti-shock insulation block - Google Patents

Abstract

The utility model discloses a sintering anti-seismic heat-preservation building block, which comprises a building block body, wherein the building block body is arranged in a T shape, the building block body comprises an end part and a rod part, the end part and the rod part are both arranged in a cuboid shape, a reinforcing steel bar hole is arranged in the middle of the side surface of the end part, the reinforcing steel bar hole is a through hole, and a rectangular hole is arranged in the middle of the top surface of the rod part; the sintered anti-seismic heat-insulation building block is stable in masonry and has good anti-seismic performance.

Description

A sintered anti-shock insulation block

technical field

The utility model relates to the technical field of building materials, in particular to a sintered anti-seismic thermal insulation block.

Background technique

Blocks are artificial blocks used for building walls. They are a new type of wall material, and their shapes are mostly rectangular hexahedrons. Blocks are artificial blocks made of concrete, industrial waste (slag, coal fly ash, etc.) or local materials. They have relatively large dimensions, simple equipment, and fast masonry speed. demand for reform.

The existing blocks have the disadvantage of not having good anti-seismic performance.

Utility model content

The technical problem to be solved by the utility model is to provide a sintered anti-seismic thermal insulation block with stable masonry and good anti-seismic performance.

In order to solve the above problems, the utility model adopts the following technical solutions:

A sintered anti-seismic thermal insulation block, comprising a block body, the block body is arranged in a T-shape, the block body includes an end portion and a rod portion, and the end portion and the rod portion are both arranged in a cuboid shape, the A reinforcement hole is provided in the middle of the side of the end, and the reinforcement hole is a through hole, and a rectangular hole is provided in the middle of the top surface of the rod.

During masonry, the two blocks are placed opposite to each other, so that the side of the stem of one block fits the side of the stem of the other block, and the masonry is carried out in a cycle.

Preferably, the end part and the rod part are integrally provided, and the structure is stable and reliable.

Preferably, the steel bar holes are arranged in a circular shape.

Preferably, a thermal insulation block is arranged in the rectangular hole, and the thermal insulation block prevents heat transfer, so that the block has a good thermal insulation effect.

Preferably, more than one circular through hole is provided on the top surface of the thermal insulation block, and the circular through holes are arranged in a rectangular array to reduce the weight of the thermal insulation block, thereby reducing the overall weight of the wall and saving materials.

As a preference, slopes are provided on both sides of the back of the end, so that the connecting seam of the two blocks forms a triangular opening, and the triangular opening is filled with thermal insulation mortar, which can block the gap cold bridge and achieve a good thermal insulation effect .

Preferably, the angle between the slope and the back of the end is 45 degrees, and the width of the slope is greater than 5mm.

The beneficial effects of the utility model are: the sintered anti-seismic thermal insulation block is arranged in a T-shape through the block body, the blocks are alternately built, the contact area between adjacent blocks becomes larger, and the combination is firm, so that the wall formed by the masonry It is more stable, through the middle part of the side of the end part, a steel bar hole is set, and the steel bar is penetrated into the steel bar hole, thereby improving the toughness of the wall and greatly improving the earthquake resistance of the wall. Reduce the material and reduce the weight of the block, thereby reducing the weight of the wall and improving the earthquake resistance.

Description of drawings

Below in conjunction with accompanying drawing, the specific embodiment of the present utility model is described in further detail, wherein:

Fig. 1 is a three-dimensional structural schematic diagram of a sintered anti-seismic thermal insulation block of the present invention.

Fig. 2 is a schematic diagram of the structure of a wall built with sintered anti-seismic thermal insulation blocks of the present invention.

detailed description

Example 1

As shown in Figure 1 and Figure 2, a sintered anti-seismic thermal insulation block includes a block body 1, the block body 1 is arranged in a T shape, and the block body 1 includes an end portion 11 and a rod portion 12, so that Both the end portion 11 and the rod portion 12 are arranged in a cuboid shape, the middle part of the side of the end portion 11 is provided with a reinforcement hole 111, and the reinforcement hole 111 is a through hole, and the middle part of the top surface of the rod portion 12 is provided with a rectangular hole 121.

During masonry, the two blocks are placed opposite to each other, so that the side of the rod 12 of one block fits the side of the rod 12 of the other block, so that the masonry is carried out in a cycle.

The beneficial effects of this embodiment are: the sintered anti-seismic thermal insulation block is arranged in a T-shape through the block body, the blocks are alternately built, the contact area between adjacent blocks becomes larger, and the combination is firm, so that the wall formed by the masonry It is more stable, through the middle part of the side of the end part, a steel bar hole is set, and the steel bar is penetrated into the steel bar hole, thereby improving the toughness of the wall and greatly improving the earthquake resistance of the wall. Reduce the material and reduce the weight of the block, thereby reducing the weight of the wall and improving the earthquake resistance.

Example 2

As shown in Figure 1 and Figure 2, a sintered anti-seismic thermal insulation block includes a block body 1, the block body 1 is arranged in a T shape, the block body 1 includes an end portion 11 and a rod portion 12, the Both the end portion 11 and the rod portion 12 are arranged in a cuboid shape, the middle part of the side of the end portion 11 is provided with a reinforcement hole 111, and the reinforcement hole 111 is a through hole, and the middle part of the top surface of the rod portion 12 is provided with a rectangular hole 121.

During masonry, the two blocks are placed opposite to each other, so that the side of the rod 12 of one block fits the side of the rod 12 of the other block, so that the masonry is carried out in a cycle. Preferably, the end part and the rod part are integrally provided, and the structure is stable and reliable.

The steel bar hole 111 is arranged in a circular shape, and an insulating block 122 is arranged in the rectangular hole 121. The insulating block 122 plays a role in preventing heat transfer, so that the block has a good thermal insulation effect. The top surface of the insulating block 122 is More than one circular through hole 123 is provided, and the circular through hole 123 is arranged in a rectangular array to reduce the weight of the insulation block 122, thereby reducing the overall weight of the wall and saving materials. An inclined surface 112 is provided to form a triangular opening between the joints of the two blocks, and the insulating mortar is filled into the triangular opening, which can block the gap cold bridge and achieve a good thermal insulation effect. The inclined surface 112 and the end 11 The included angle at the back is 45 degrees, and the width of the slope 112 is greater than 5mm.

The beneficial effects of this embodiment are: the sintered anti-seismic thermal insulation block is arranged in a T-shape through the block body, the blocks are alternately built, the contact area between adjacent blocks becomes larger, and the combination is firm, so that the wall formed by the masonry It is more stable, through the middle part of the side of the end part, a steel bar hole is set, and the steel bar is penetrated into the steel bar hole, thereby improving the toughness of the wall and greatly improving the earthquake resistance of the wall. Reduce the material and reduce the weight of the block, thereby reducing the weight of the wall and improving the earthquake resistance.

The above is only a specific embodiment of the utility model, but the scope of protection of the utility model is not limited thereto, and any change or replacement that is not thought of through creative work should be covered within the scope of protection of the utility model .

Claims (7)

1. A sintered anti-seismic thermal insulation block, comprising a block body, characterized in that: the block body is T-shaped, and the block body includes an end and a rod, and the end and the rod are all in the shape of It is arranged in a cuboid shape, and the middle part of the side of the end part is provided with a reinforcement hole, and the reinforcement hole is a through hole, and the middle part of the top surface of the rod part is provided with a rectangular hole. 2. The sintered anti-seismic thermal insulation block according to claim 1, characterized in that: the end part and the rod part are integrally arranged. 3. The sintered anti-seismic thermal insulation block according to claim 1, characterized in that: the reinforcement holes are arranged in a circular shape. 4. The sintered anti-seismic thermal insulation block according to claim 1, characterized in that: thermal insulation blocks are arranged in the rectangular holes. 5. The sintered anti-seismic thermal insulation block according to claim 4, characterized in that: more than one circular through-hole is arranged on the top surface of the thermal insulation block, and the circular through-holes are arranged in a rectangular array. 6. The sintered anti-seismic thermal insulation block according to claim 1, characterized in that slopes are provided on both sides behind the end. 7. The sintered anti-seismic thermal insulation block according to claim 6, characterized in that: the angle between the slope and the back of the end is 45 degrees, and the width of the slope is greater than 5 mm.