CN212153775U - Low-energy-consumption fireproof heat-insulation composite board for building exterior wall - Google Patents

Abstract

The low-energy-consumption fireproof heat-insulation composite board for the building exterior wall comprises an AGES board, wherein the AGES board is an MPR or GPIR heat-insulation board coated with heat-insulation mortar; the two sides of the AGES plate are both provided with a clamping block, a gap is arranged between the clamping block and the AGES plate, and the gap can accommodate another clamping block to be inserted and clamped in the gap. The adopted fireproof performance is high, the material that coefficient of heat conductivity is low, and for preventing to have the gap of direct outer wall body between the AGES board, through the strip fixture block of AGES board both sides, the joint is assembled each other to transition bellying and dog, reduces the gap that has direct outer wall body between the AGES board by a large scale, has optimized the heat preservation effect to outer wall body for the energy consumption of outer wall body reduces, and the fixture block medial surface is the slope form simultaneously, forms a spigot surface that can connect each other, improves the installation effectiveness. The cement groove with the dovetail-shaped section improves the firmness of the AGES board attached to the outer wall body.

Description

Low-energy-consumption fireproof heat-insulation composite board for building exterior wall

Technical Field

The utility model relates to an heated board technical field especially relates to a low energy consumption building outer wall fire prevention thermal protection composite panel.

Background

The heat insulation board is a board for heat insulation of a building. The heat-insulating board is a hard foam plastic board which is made by adopting polystyrene resin, heating, mixing, injecting a catalyst and then extruding and molding, has the moisture-proof, waterproof and fireproof performances, and can reduce the thickness of an outer enclosure structure of a building so as to increase the indoor use area. But the fire-retardant property may be lowered after a long time use.

The heated board that uses at present is on the wall through the mortar adhesion after directly docking mostly, because the gap between the heated board is just leading to the relatively poor leading reason of heat preservation effect, reduces the heat insulating ability that the gap can improve the outer wall, but the fine processing of seam crossing can reduce the efficiency of construction of installation.

SUMMERY OF THE UTILITY MODEL

Have the gap of direct outer wall body when solving the heated board concatenation, and the influence is to the heat preservation effect of outer wall body to and when reducing the concatenation gap as far as possible, can the extension time limit for a project's the condition, further promote fire behavior, reduce coefficient of heat conductivity, the utility model provides a low energy consumption building outer wall fire prevention thermal protection composite panel.

The utility model discloses a realize through following technical scheme.

The low-energy-consumption fireproof heat-insulation composite board for the building exterior wall comprises an AGES board, wherein the AGES board is formed by bonding a plurality of heat-insulation layers through a bonding agent, and heat-insulation mortar is coated on the surface of the AGES board; the two sides of the AGES plate are both provided with a clamping block, a gap is arranged between the clamping block and the AGES plate, and the gap can accommodate another clamping block to be inserted and clamped in the gap. The AGES boards are connected in a clamping mode, so that the AGES boards are better in integrity after being connected.

The utility model discloses a further improvement still, above-mentioned fixture block with be equipped with the transition bellying between the AGES board. The transition convex part is directly contacted with the clamping block, so that the connection between the AGES plate and the clamping block is firmer.

The utility model discloses a further improvement still, above-mentioned fixture block thickness is less than AGES board thickness, and it is one to differ thickness the thickness of transition bellying. When the two AGES plates are clamped by the clamping block, the two AGES plates are positioned on the same plane up and down.

The utility model is further improved by that a baffle is arranged in the middle of the gap between the fixture block and the AGES plate, and the baffle is higher than the top surface of the fixture block by the thickness of one transition bulge; the horizontal plane of the baffle exposed outside and the horizontal plane of the AGES plate are positioned on the same plane. The stopper limits the clamping mode between the AGES plates, and further fills up the contact tightness between the AGES plates.

The utility model discloses a further improvement still, the fixture block extending direction of above-mentioned AGES board both sides is opposite. Facilitating the snap-fit splicing between the AGES boards.

The utility model discloses a further improvement still, the medial surface of above-mentioned fixture block is the inclined plane. The inclined surface provides guidance for the clamping of the other clamping block.

The utility model is further improved in that the front-back length of the fixture block is smaller than the front-back length of the side surface of the AGES plate, and the difference distance is equal to the thickness of the baffle plate; the fixture block is arranged in the middle of the side surface of the AGES plate. The gap formed between the clamping blocks is convenient for the baffle on the other AGES plate to be clamped.

The utility model discloses a further improvement still, above-mentioned heat preservation includes first heat preservation and second heat preservation, first heat preservation and second heat preservation are MPR or GPIR material insulation material, and coating heat preservation mortar and inside AGES board that is equipped with MPR or GPIR material insulation material promote fire behavior, and the coefficient of heat conductivity reduces. And an anti-stretching layer is arranged between the first heat-insulating layer and the second heat-insulating layer. The stretch resistant layer increases the flexibility of the AGES sheet.

The utility model discloses a further improvement still, the bottom surface of above-mentioned AGES board is equipped with the cement entry, the cement groove of cement entry linkage inside extension, the cement groove cross-section is the dovetail type. And cement is poured into the cement tank, and after the cement tank is dried, the connection between the AGES board and the outer wall body is firmer.

The utility model discloses a further improvement still, above-mentioned cement entry set up in four angles and the intermediate position of heat preservation bottom surface. Evenly distributed cement inlets, after the cement is poured and set dry, form evenly distributed support forces against the AGES board.

The utility model has the advantages that: in order to prevent gaps between the AGES boards, the gaps between the transversely arranged AGES boards with the through outer wall bodies are avoided by the mutual clamping of the strip-shaped clamping blocks, the transition protruding parts and the clamping blocks on the two sides of the AGES boards, so that the heat insulation effect of the outer wall body is improved, the energy consumption of the outer wall body is reduced, meanwhile, the inner side surfaces of the clamping blocks are inclined, a guide surface which can be connected with each other is formed, and the installation efficiency is improved. The cement groove with the dovetail-shaped section improves the firmness of the AGES board attached to the outer wall body.

Drawings

Fig. 1 is a perspective view of an embodiment of the present invention.

Fig. 2 is a bottom schematic view of an embodiment of the present invention.

Fig. 3 is a trough schematic diagram of the embodiment of the present invention.

Fig. 4 is a schematic diagram of a combination of the embodiment of the present invention.

Fig. 5 is a schematic structural diagram of an embodiment of the present invention.

1. The composite insulation board comprises an AGES board, 2 a baffle, 3 a fixture block, 4 a transition bulge, 5 a cement inlet, 6 a cement groove, 7 composite insulation mortar, 8 a first insulation layer, 9 a tensile layer, 10 a second insulation layer.

Detailed Description

The following describes the embodiments of the present invention with reference to the accompanying drawings.

As shown in the attached drawing, the low-energy-consumption fireproof and heat-insulating composite board for the building outer wall comprises an AGES board 1 and a heat-insulating layer, transition protruding parts 4 are arranged on two sides of the AGES board 1, strip-shaped clamping blocks 3 are arranged on the outer sides of the transition protruding parts 4, and the inner side surfaces of the clamping blocks 3 are inclined. The inclined surfaces of the inclined fixture blocks 3 form guide surfaces during assembly connection. A gap is arranged between the fixture block 3 and the AGES plate 1, and the gap can accommodate another fixture block 3 to be inserted and clamped in. The mutual assembly of the clamping blocks 3 reduces the gaps directly communicated with the outside of the wall body in a large area. The thickness of the strip-shaped fixture block 3 is smaller than that of the AGES plate 1 by the thickness of one transition bulge 4. The transition convex parts 4 on the two sides and the fixture block 3 are arranged oppositely. A baffle plate 2 is arranged in the middle of the gap between the fixture block 3 and the AGES plate 1, and the baffle plate 2 is higher than the top surface of the fixture block 3 by the thickness of one transition bulge 4. The baffle 2 is used for filling gaps between the clamping blocks 3 in the vertical direction. The AGES plate 1 is formed by bonding and synthesizing a plurality of insulating layers through adhesives, and insulating mortar 7 is coated on the surface; the bottom of the composite thermal insulation mortar 7 is provided with a thermal insulation layer, the thermal insulation layer comprises a first thermal insulation layer 8 and a second thermal insulation layer 10, and the first thermal insulation layer 8, the second thermal insulation layer 10, the transition boss 4, the fixture block 3 and the baffle 2 are made of MPR or GPIR thermal insulation materials, so that the overall fireproof performance is improved, and the heat conductivity coefficient is reduced. The first heat-insulating layer 8 and the second heat-insulating layer 10 are respectively wrapped with glass fiber grids. And a stretch-resistant layer 9 is arranged between the first heat-insulating layer 8 and the second heat-insulating layer 10, and quartz fiber cotton is arranged inside the stretch-resistant layer 9. Increasing the flexibility of the AGES sheet 1. The second heat preservation 10 bottom surface is equipped with cement entry 5, cement entry 5 set up in four angles and the intermediate position of second heat preservation 10 bottom surfaces, cement entry 5 to it is equipped with cement groove 6 to extend in the second heat preservation 10, 6 cross-sections in cement groove are the dovetail. After the cement is cured, a firm and even support is formed between the AGES board 1 and the outer wall body.

The use principle is as follows: the AGES plate 1 is provided with double-layer heat-insulating layers, and the stretching layer 9 is arranged between the two heat-insulating layers, so that the flexibility of the AGES plate 1 is improved while the AGES plate is fireproof and heat-insulating. When the cement-based wall is installed, cement is filled into the cement groove 6 on the bottom surface of the AGES board 1 and is attached to a wall body, so that after the cement is dried, a firm attachment is formed on the AGES board 1. Then, the AGES plates 1 are connected in an assembled clamping manner, firstly, the two AGES plates 1 are vertically attached to a wall body, the clamping blocks 3 extending outwards at the same side are aligned, a section of gap is reserved between the two clamping blocks 3, the clamping block 3 at one side of the other AGES plate 1 extending towards the wall body is clamped between the clamping blocks 3 which are already placed before, the clamping blocks are inserted into the gap between the two blocks before, seamless connection is formed between the transverse AGES plates 1, the reduction of the gap area between the AGES plates 1 enables the wall body to have better heat preservation performance, and therefore low energy consumption in the aspect of heat preservation is achieved.

The front body of the AGES plate 1 is a graphite extruded sheet, after the heat insulation layer is converted into an MPR composite heat insulation plate or a GPIR composite heat insulation plate, the fireproof performance of the AGES plate is integrally improved, and the heat conductivity coefficient is reduced.

A low energy consumption building outer wall fire prevention heat preservation composite sheet, it is high to have adopted fire behavior, the material that coefficient of heat conductivity is low, and for preventing to have the gap of direct wall body between the AGES board, strip fixture block through AGES board both sides, the joint is assembled each other to transition bellying and dog, the large tracts of land reduces the gap that has direct wall body between the AGES board, the heat preservation effect to outer wall body has been optimized, make the energy consumption of wall body reduce, the fixture block medial surface is the slope form simultaneously, form a spigot surface that can connect each other, improve the installation effectiveness. The cement groove with the dovetail-shaped section improves the firmness of the AGES board attached to the outer wall body.

The terms "upper", "lower", "outside", "inside" and the like in the description and claims of the present invention and the above drawings are used for distinguishing relative positions if any, and are not necessarily given qualitatively. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the invention described herein are capable of operation in sequences other than those illustrated or described herein. Furthermore, the terms "comprising" and "having," as well as any variations thereof, are intended to cover non-exclusive inclusions.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. The low-energy-consumption fireproof heat-insulation composite board for the building exterior wall comprises an AGES board (1), and is characterized in that the AGES board (1) is formed by bonding a plurality of heat-insulation layers through a bonding agent, and heat-insulation mortar is coated on the surface of the AGES board; the two sides of the AGES plate (1) are respectively provided with a clamping block (3), a gap is arranged between the clamping block (3) and the AGES plate (1), and the gap can accommodate another clamping block (3) to be inserted and clamped in the gap.

2. The fire-proof and heat-insulating composite board for the exterior wall of the low-energy-consumption building as claimed in claim 1, wherein a transition bulge (4) is arranged between the fixture block (3) and the AGES board (1).

3. The fire-proof and heat-insulating composite board for the exterior wall of the low-energy-consumption building as claimed in claim 2, wherein the thickness of the fixture block (3) is less than that of the AGES board (1), and the difference thickness is the thickness of one transition bulge (4).

4. The low-energy-consumption fireproof and heat-insulating composite board for the exterior wall of the building is characterized in that a baffle (2) is arranged in the middle of a gap between the fixture block (3) and the AGES board (1), and the thickness of the baffle (2) is higher than that of one transition protruding part (4) on the top surface of the fixture block (3); the horizontal plane of the baffle (2) exposed outside and the horizontal plane of the AGES plate (1) are in the same plane.

5. The fire-proof and heat-insulating composite board for the exterior wall of the low-energy-consumption building as claimed in claim 1, wherein the extension directions of the clamping blocks (3) on the two sides of the AGES board (1) are opposite.

6. The fire-proof and heat-insulation composite board for the exterior wall of the low-energy-consumption building as claimed in claim 1, wherein the inner side surface of the fixture block (3) is an inclined surface.

7. The fire-proof and heat-insulating composite board for the exterior wall of the low-energy-consumption building is characterized in that the front-back length of the fixture block (3) is smaller than the front-back length of the side surface of the AGES board (1), and the difference distance is equal to the thickness of the baffle (2); the fixture block (3) is arranged in the middle of the side surface of the AGES plate (1).

8. The fire-proof and heat-insulating composite board for the exterior wall of the low-energy-consumption building as claimed in claim 1, wherein the heat-insulating layer comprises a first heat-insulating layer (8) and a second heat-insulating layer (10), the first heat-insulating layer (8) and the second heat-insulating layer (10) are made of MPR or GPIR heat-insulating materials, and a tensile layer (9) is arranged between the first heat-insulating layer (8) and the second heat-insulating layer (10).

9. The low-energy-consumption fireproof and heat-insulating composite board for the exterior wall of the building is characterized in that a cement inlet (5) is formed in the bottom surface of the AGES board (1), the cement inlet (5) is connected with an inwardly extending cement groove (6), and the cross section of the cement groove (6) is dovetail-shaped.

10. The fire-proof and heat-insulating composite board for the exterior wall of the low-energy-consumption building as claimed in claim 9, wherein the cement inlets (5) are arranged at four corners and in the middle of the bottom surface of the heat-insulating layer.

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