CN204225304U - A kind of composite fireproof isolation strip for skin heat-insulation system constructs - Google Patents

Abstract

The utility model discloses a kind of composite fireproof isolation strip for skin heat-insulation system to construct, comprise organic warming plate and fire barrier, its structure is: between upper and lower two pieces of organic warming plates, be provided with fire barrier, fire barrier adopts the special-shaped groove of non-flat mouth to dock with the contact surface of upper and lower organic warming plate.The utility model adopts said structure, between fire barrier with warming plate, adopt the special-shaped groove of non-flat mouth to dock, position, fire barrier and external thermal insulation planeness is made to reach consistent completely, while reaching the building heat preservation effect of regulation, thoroughly solve directly through between original fire barrier and upper and lower adjacent insulating layer and easily occur ftractureing, heat bridge, infiltration, the phenomenon such as condensation technical problem.

Description

A Composite Fireproof Isolation Belt Structure for Building External Wall Thermal Insulation System

technical field

The utility model relates to a fireproof isolation belt structure, in particular to a composite fireproof isolation belt structure used for the heat preservation system of the outer wall of a building.

Background technique

The existing composite fire isolation structure used for building exterior wall insulation system is to add a fire isolation belt between the insulation boards. The organic thermal insulation material of the adjacent main body is also flat-butted. Because the fireproof isolation belt and the organic thermal insulation material are two types of materials, there is a big difference in performance. After the winter and summer temperature freeze-thaw cycles, the shrinkage coefficients of the two types of materials are different. Cracks often appear at adjacent joints, which reduces the building insulation effect. Over time, the protective layer and finish layer will fall off, which not only affects the quality of the project, but also affects the appearance of the building.

Contents of the invention

In order to solve the above-mentioned technical problems, the utility model provides a composite fireproof isolation belt structure for building exterior wall insulation system, the fireproof isolation belt and the insulation board are connected by a non-flat special-shaped groove, so that the fireproof isolation belt and the insulation board are connected to each other. The external insulation layer is consistent, and while achieving the specified building insulation effect, it completely solves the problems of cracking, thermal bridge, water seepage, condensation, etc. question.

In order to achieve the above purpose, the technical solution adopted by the utility model is: a composite fireproof isolation belt structure for building exterior wall insulation system, including organic insulation board 1 and fireproof isolation belt 2, its structure is: A fire-proof isolation belt 2 is arranged between the organic insulation boards 1, and the contact surfaces of the fire-proof isolation belt 2 and the upper and lower organic insulation boards 1 are connected by non-flat special-shaped grooves.

The special-shaped grooves are corresponding concave-convex grooves 4 .

The special-shaped groove is the corresponding stepped groove 5 .

The special-shaped grooves are corresponding dovetail grooves 6 .

The beneficial effect of the utility model is that: the utility model adopts the above-mentioned structure, and adopts a non-flat special-shaped groove for docking between the fireproof isolation belt and the heat preservation board, so that the position of the fireproof isolation belt is completely consistent with the outer insulation layer, and when the specified While improving the thermal insulation effect of the building, it completely solves the technical problems of cracking, thermal bridges, water seepage, condensation, etc. caused by the direct penetration between the original fire isolation belt and the upper and lower adjacent insulation layers.

Description of drawings

Figure 1: It is a schematic diagram of the structure of the special-shaped groove of the utility model as a concave-convex groove.

Figure 2: It is a structural schematic diagram of the utility model special-shaped groove as a stepped groove.

Figure 3: Schematic diagram of the structure of the special-shaped groove of the utility model as a dovetail groove.

Detailed ways

Below in conjunction with accompanying drawing, the utility model is described in detail.

As shown in Figure 1-3, a composite fire insulation belt structure for building exterior wall insulation system, including organic insulation board 1 and fire insulation belt 2, its structure is: two organic insulation boards 1 on the upper and lower A fireproof isolation belt 2 is arranged between them, and the contact surfaces of the fireproof isolation belt 2 and the upper and lower organic insulation boards 1 are connected by non-flat special-shaped grooves.

As shown in Figure 1, it is a schematic diagram of the utility model structure when the special-shaped groove is the corresponding concave-convex groove 4, and the upper and lower surfaces of the fireproof isolation belt 2 are provided with convex grooves, and the lower surface of the organic insulation board 1 above the fireproof isolation belt 2 The upper surface of the organic insulation board 1 below the fireproof isolation belt 2 is provided with grooves corresponding to the convex grooves of the fireproof isolation belt 2. The organic insulation board 1 of the groove is stuck on the wall base 7, and then the fireproof isolation belt 2 with the convex groove is inserted into its groove, and the fireproof isolation belt 2 is stuck on the wall base 7 with the adhesive 3. Then insert the grooved organic insulation board 1 on the upper surface into the corresponding part of the convex groove of the fireproof isolation belt 2, and paste it on the wall base 7 with an adhesive 3.

As shown in Figure 2, it is a schematic diagram of the utility model structure when the special-shaped groove is a corresponding stepped groove 5. The upper and lower surfaces of the fireproof isolation belt 2 are provided with a stepped groove 5, and the lower surface of the organic insulation board 1 above the fireproof isolation belt 2 The upper surface of the organic insulation board 1 below the surface and the fireproof isolation belt 2 is provided with a stepped groove corresponding to the stepped groove 5 of the fireproof isolation belt 2. The organic thermal insulation board 1 with the stepped groove 5 is glued on the base layer 7 of the wall, and then the fireproof isolation belt 2 with the corresponding stepped groove 5 is inserted into the organic thermal insulation board 1 that has been fixed above, and the adhesive 3 is used to seal the The fireproof isolation belt 2 is stuck on the base layer of the wall body 7, and then the organic insulation board 1 with the stepped groove 5 on the upper surface is inserted into the corresponding part of the stepped groove 5 of the fireproof isolation belt 2, and pasted on the base layer of the wall body with an adhesive 3 7 on.

As shown in Figure 3, it is a schematic diagram of the utility model when the special-shaped groove is a corresponding dovetail groove 6, the upper and lower surfaces of the fireproof isolation belt 2 are provided with a dovetail groove 6, and the organic insulation board 1 on the top of the fireproof isolation belt 2 The lower surface and the upper surface of the organic insulation board 1 below the fireproof isolation belt 2 are provided with a dovetail groove corresponding to the dovetail groove 6 of the fireproof isolation belt 2. The organic insulation board 1 with the dovetail groove 6 on the surface is glued to the base layer 7 of the wall, and then the fireproof isolation belt 2 with the corresponding dovetail groove 6 is inserted into the fixed organic insulation board 1 above, and the adhesive 3 Stick the fireproof isolation belt 2 on the base layer 7 of the wall, and then insert the organic insulation board 1 with the dovetail groove 6 on the upper surface into the corresponding part of the dovetail groove 6 of the fireproof isolation belt 2, and paste it on the wall with the adhesive 3 Base 7 on.

The utility model adopts the above-mentioned structure, and a non-flat special-shaped groove is used for butt joint between the fireproof isolation belt and the insulation board, so that the position of the fireproof isolation belt is completely consistent with the outer insulation layer, and while achieving the specified building insulation effect, it completely solves the problem. There are technical problems that cracks, thermal bridges, water seepage, condensation, etc. are prone to occur due to the direct penetration between the fire isolation belt and the upper and lower adjacent insulation layers.

Claims (4)

1. A composite fire insulation belt structure for building exterior wall insulation system, including organic insulation board (1) and fire insulation belt (2), characterized in that: two organic insulation boards (1) A fireproof isolation belt (2) is arranged between them, and the contact surfaces of the fireproof isolation belt (2) and the upper and lower organic insulation boards (1) are connected by non-flat special-shaped grooves. 2. The structure of a composite fireproof isolation belt used for building exterior wall insulation systems according to claim 1, characterized in that: the special-shaped grooves are corresponding concave-convex grooves (4). 3. The structure of a composite fireproof isolation belt used for building exterior wall insulation systems according to claim 1, characterized in that: the special-shaped grooves are corresponding stepped grooves (5). 4. The structure of a composite fireproof isolation belt used for building exterior wall insulation systems according to claim 1, characterized in that: the special-shaped grooves are corresponding dovetail grooves (6).