CN220889031U - Ultralow energy consumption heat preservation system structure - Google Patents

Abstract

The utility model discloses an ultralow-energy-consumption heat preservation system structure, which comprises heat preservation plates arranged on the same side of a beam, a floor slab and an upright post, wherein each heat preservation plate comprises a B-shaped plate and a combination plate assembled and connected with the B-shaped plate; alkali-resistant glass fiber reinforced nets with reinforcing effect are respectively arranged at joints and internal and external corners of the heat-insulating boards, and anti-cracking mortar layers are arranged at the outer sides of the alkali-resistant glass fiber reinforced nets and the heat-insulating boards; an integral alkali-resistant glass fiber net for preventing cracking is laid in the anti-cracking mortar layer; the utility model can be suitable for various construction environments by updating the installation mode, simplifies the operation procedure, reduces the operation difficulty, improves the applicability and reduces the comprehensive production cost.

Description

Ultralow energy consumption heat preservation system structure

Technical Field

The utility model relates to the technical field of heat preservation structures, in particular to an ultralow-energy-consumption heat preservation system structure.

Background

The cast-in-place concrete built-in heat preservation system is characterized in that a cast-in-place concrete structure layer and a protective layer are generally reliably connected through a stainless steel web welding net frame or a metal connecting piece, a heat preservation layer is arranged in the middle, a concrete cantilever plate is arranged between the layers, concrete is poured on the structure layers and the protective layer on two sides of the heat preservation layer at the same time, and an outer wall heat preservation system with an integrated heat preservation and outer wall structure is formed.

However, the existing steel wire grid system insulation board needs to be sprayed with mortar and plastered again after being installed, the working procedure is complex, the operation difficulty is high, the installation cost of the cast-in-place concrete built-in insulation ultralow energy consumption system is high, the construction process is complex, the field wet operation engineering quantity is large, especially in the north, the influence of seasonal temperature is large, and the labor cost is relatively high.

Disclosure of utility model

The utility model aims to solve the technical problem of providing an ultralow-energy-consumption heat preservation system structure which can be better adapted to various construction environments, simplify operation procedures and reduce operation difficulty.

In order to solve the technical problems, the technical scheme adopted by the utility model is as follows.

The heat preservation system structure with ultralow energy consumption comprises heat preservation boards arranged on the same side of a beam, a floor slab and an upright post, wherein each heat preservation board comprises a B-shaped board and a combination board assembled and connected with the B-shaped board; alkali-resistant glass fiber reinforced nets with reinforcing effect are respectively arranged at joints and internal and external corners of the heat-insulating boards, and anti-cracking mortar layers are arranged at the outer sides of the alkali-resistant glass fiber reinforced nets and the heat-insulating boards; an integral alkali-resistant glass fiber net for preventing cracking is laid inside the anti-cracking mortar layer.

According to the ultralow-energy-consumption heat preservation system structure, the bottoms of the B-shaped plates are arranged on one side of a floor slab through the L-shaped connecting plates which are arranged in an inner-outer staggered mode; the combined plates are mounted on the cross beam or the upright post through expansion bolts and L-shaped connecting plates; the B-shaped plates are assembled and connected with the composition plates through vertically arranged connecting pieces.

The ultra-low energy consumption heat preservation system structure comprises a B-shaped plate and an A-shaped plate which is arranged on the B-shaped plate and is consistent with the height of the cross beam; one side of the A-shaped plate is aligned with one side of the B-shaped plate, and a notch assembled with the cross beam or the upright post is formed between the other side of the A-shaped plate and the other side of the B-shaped plate.

Above-mentioned ultralow energy consumption heat preservation system structure, A template is installed on crossbeam or stand through a plurality of expansion bolts, and the top of below B template is then connected with crossbeam or stand through the L type connecting plate of installing in combination board notch department.

Above-mentioned ultralow energy consumption heat preservation system structure, the A template includes the heat preservation and sets up the inoxidizing coating in heat preservation one side, and the inoxidizing coating is inside to be provided with the steel wire net piece.

Above-mentioned ultralow energy consumption heat preservation system structure, the B template includes the heat preservation and sets up the inoxidizing coating in the heat preservation both sides respectively, and the inoxidizing coating is inside to be provided with the steel wire net piece.

According to the ultralow-energy-consumption heat preservation system structure, the heat preservation layers at the adjacent positions of the upper layer and the lower layer are provided with the clamping grooves for installing the connecting pieces.

By adopting the technical scheme, the utility model has the following technical progress.

The utility model provides an ultralow-energy-consumption heat-preservation system structure, which can be suitable for various construction environments through updating of an installation mode, simplifies operation procedures, reduces operation difficulty, improves applicability and reduces comprehensive production cost.

Drawings

FIG. 1 is a schematic diagram of a specific structure of the present utility model;

FIG. 2 is a cross-sectional view of the present utility model;

FIG. 3 is an exploded view of FIG. 2;

FIG. 4 is a schematic view of the structure of the A-shaped board according to the present utility model;

fig. 5 is a schematic view showing a specific structure of the B-shaped board according to the present utility model.

Wherein: 1. the concrete floor comprises a cross beam, a floor slab, a vertical column, a heat insulation board, a 5.L connecting board, a 6. B-shaped board, a 7-combined board, a 8-connecting piece, a 9-expansion bolt, a 10-alkali-resistant glass fiber reinforced net, a 11-crack-resistant mortar layer, a 12-integral alkali-resistant glass fiber net, a 13. A-shaped board, a 14-heat insulation layer, a 15-protective layer and a 16-steel wire net.

Detailed Description

The utility model will be described in further detail with reference to the drawings and the detailed description.

An ultralow-energy-consumption heat preservation system structure is shown in fig. 1 to 5, and comprises heat preservation boards 4 arranged on the same side of a cross beam 1, a floor slab 2 and a stand column 3, wherein an alkali-resistant glass fiber reinforced net 10 is respectively arranged at a joint between the heat preservation boards 4 and at a yin-yang corner, an anti-cracking mortar layer 11 is arranged on the outer side of the alkali-resistant glass fiber reinforced net 10, and a layer of integral alkali-resistant glass fiber net 12 is further paved inside the anti-cracking mortar layer 11.

The insulation board 4 comprises a B-shaped board 6 and a combination board 7 assembled and connected with the B-shaped board 6, as shown in fig. 3, the combination board 7 comprises the B-shaped board 6 and an A-shaped board 13 arranged on the B-shaped board 6, the height of the A-shaped board 13 is consistent with that of the cross beam 1, one side of the A-shaped board 13 is aligned with one side of the B-shaped board 6, and a notch assembled with the cross beam 1 is formed between the other side of the A-shaped board 13 and the other side of the B-shaped board 6.

The A-shaped plate 13 is arranged on the cross beam 1 or the upright post 3 through a plurality of expansion bolts 9, and the top of the lower B-shaped plate 6 is connected with the bottom of the cross beam 1 through an L-shaped connecting plate 5 arranged at a notch on the combined plate 7.

The bottom of the B-shaped plate 6 is arranged on one side of the floor slab 2 through L-shaped connecting plates 5 which are arranged in an inner-outer staggered manner, and as shown in fig. 2, the B-shaped plate 6 is connected with the combined plate 7 through a connecting piece 8 which is arranged vertically.

The A-shaped plate 13 comprises an insulation layer 14 and a protective layer 15 arranged on one side of the insulation layer 14, and as shown in fig. 4, a steel wire mesh 16 is further arranged inside the protective layer 15.

The B-shaped plate 6 comprises a heat preservation layer 14 and protective layers 15 respectively arranged on two sides of the heat preservation layer 14, and as shown in fig. 5, steel wire meshes 16 are arranged inside the protective layers 15.

The heat preservation layer 14 of the upper and lower adjacent parts is provided with a clamping groove for installing the connecting piece 8, the size of the clamping groove is 100mm x 5mm, and the heat preservation layer 14 can also adopt various heat preservation materials such as a graphite extruded sheet, a polystyrene sheet, a graphite polystyrene sheet and the like according to design requirements.

The protective layer 15 on the outer side of the heat insulation board 4 is a class-A fireproof composite polyphenyl foam heat insulation board with the thickness of 50mm, and the size of the built-in steel wire mesh 16 is 10mm x 0.7mm.

During installation, the B-shaped plate 6 is firstly installed on the floor slab 2 through the L-shaped connecting plate 5, the vertical part of the L-shaped connecting plate 5 is connected with the protective layer 15, and the horizontal part of the L-shaped connecting plate 5 is installed on the floor slab 2 through the bolt assembly.

Then, the composite board 7 and the B-shaped board 6 are connected together through the connecting piece 8, and the composite board 7 is installed on the cross beam 1 or the upright post 3 by the expansion bolts 9, so that the installation of the heat-insulating board 4 is completed.

Then, alkali-resistant glass fiber reinforced nets 10 are respectively installed at the joints and the inner and outer corners between the heat insulation boards 4.

Finally, anti-cracking mortar is poured outside the alkali-resistant glass fiber reinforced net 10 and the heat insulation board 4 to form an anti-cracking mortar layer 11, and meanwhile, in the grouting process, a layer of integral alkali-resistant glass fiber reinforced net 12 is pressed into the anti-cracking mortar layer 11, so that cracking phenomena of procedures such as exterior putty, paint and the like are prevented.

The utility model provides an ultralow-energy-consumption heat-preservation system structure, which can be suitable for various construction environments through updating of an installation mode, simplifies operation procedures, reduces operation difficulty, improves applicability and reduces comprehensive production cost.

Claims (7)

1. An ultralow energy consumption heat preservation system structure is characterized in that: the heat insulation board (4) is arranged on the same side of the cross beam (1), the floor slab (2) and the upright post (3), and the heat insulation board (4) comprises a B-shaped board (6) and a combined board (7) assembled and connected with the B-shaped board (6); alkali-resistant glass fiber reinforced nets (10) with reinforcing effect are respectively arranged at joints and yin and yang corners between the heat insulation boards (4), and anti-cracking mortar layers (11) are arranged at the outer sides of the alkali-resistant glass fiber reinforced nets (10) and the heat insulation boards (4); an integral alkali-resistant glass fiber net (12) for preventing cracking is laid in the anti-cracking mortar layer (11).

2. An ultra low energy consumption insulation architecture according to claim 1, wherein: the bottom of the B-shaped plate (6) is arranged at one side of the floor slab (2) through L-shaped connecting plates (5) which are arranged in an inner-outer staggered way; the combined plate (7) is arranged on the cross beam (1) or the upright post (3) through an expansion bolt (9) and an L-shaped connecting plate (5); the B-shaped plate (6) is assembled and connected with the combined plate (7) through a vertically arranged connecting piece (8).

3. An ultra low energy consumption insulation architecture according to claim 1, wherein: the combined plate (7) comprises a B-shaped plate (6) and an A-shaped plate (13) which is arranged on the B-shaped plate (6) and is consistent with the cross beam (1) in height; one side of the A-shaped plate (13) is aligned with one side of the B-shaped plate (6), and a notch assembled with the cross beam (1) or the upright post (3) is formed between the other side of the A-shaped plate (13) and the other side of the B-shaped plate (6).

4. An ultra low energy consumption insulation architecture according to claim 3, wherein: the A-shaped plate (13) is arranged on the cross beam (1) or the upright post (3) through a plurality of expansion bolts (9), and the top of the lower B-shaped plate (6) is connected with the cross beam (1) or the upright post (3) through an L-shaped connecting plate (5) arranged at the notch of the combined plate (7).

5. An ultra low energy consumption insulation architecture according to claim 3, wherein: the A-shaped plate (13) comprises an insulation layer (14) and a protective layer (15) arranged on one side of the insulation layer (14), and a steel wire mesh (16) is arranged in the protective layer (15).

6. An ultra low energy consumption insulation architecture according to claim 1, wherein: the B-shaped plate (6) comprises a heat preservation layer (14) and protective layers (15) respectively arranged on two sides of the heat preservation layer (14), and steel wire meshes (16) are arranged in the protective layers (15).

7. An ultra-low energy consumption insulation architecture according to claim 5, wherein: the heat preservation layers (14) of the adjacent parts of the upper layer and the lower layer are provided with clamping grooves for installing the connecting piece (8).