CN204570955U - A kind of anti-heat bridge energy-saving support structure - Google Patents

Abstract

An energy-saving support structure for a heat-proof bridge, comprising a wall, the outer side of the wall is provided with a heat-insulating backing plate through expansion bolts, and a heat-insulating plate is arranged between the heat-insulating backing plate and the wall. A thermal insulation gasket is provided between the thermal insulation pad and the expansion bolt; the outer side of the thermal insulation pad is connected with a mounting bracket connector provided with a mounting bracket through a connecting bolt, and the mounting bracket connector A heat-insulating circular gasket is arranged between the connecting bolts. The utility model solves the problem of thermal bridges between the installation of air-conditioning brackets, solar heat collector brackets, rainwater pipe brackets, etc. and walls in buildings, and meets the technical problems of energy-saving construction with high requirements for the installation of energy-saving brackets.

Description

A thermal bridge energy-saving support structure

technical field

The utility model relates to the field of energy-saving installation structure processing and construction of air-conditioning brackets, solar heat-collecting gas brackets, rainwater pipe brackets, etc. in buildings, in particular to a heat-proof bridge energy-saving bracket structure.

Background technique

Passive low-energy buildings put forward relatively high requirements for building energy conservation. In terms of energy-saving design, node structure, and energy-saving construction, it is necessary to form an energy-saving construction supporting technology that integrates design and construction. Thermal bridges and detailed energy-saving node structures are weak links in current energy-saving design and construction. In terms of building energy-saving technology, there are still technical bottleneck constraints in building thermal bridge treatment, thermal bridge node design and construction, and thermal insulation construction. In the gap between the outer wall and the window, the air conditioner bracket, the rainwater pipe, the solar collector bracket, etc. The traditional method is to install the bracket by reserving metal embedded parts or using expansion bolts to install the bracket. In this way, a heat transfer channel will appear between the bracket and the wall, resulting in heat loss and forming a thermal bridge. , affect the energy-saving effect of the building .

Contents of the invention

The problem to be solved by the utility model is to overcome the deficiencies of the above-mentioned prior art and provide an energy-saving support structure for heat-proof bridges.

The utility model is realized in the following manner: an energy-saving support structure for a heat-proof bridge, including a wall, the outer side of the wall is provided with a thermal insulation backing plate through expansion bolts, and the thermal insulation backing plate and the A thermal insulation board is provided between the walls, and a thermal insulation gasket is provided between the thermal insulation backing plate and the expansion bolt; the outer side of the thermal insulation backing plate is connected with a mounting bracket provided with a mounting bracket through a connecting bolt. A bracket connector, a heat insulating round gasket is provided between the mounting bracket connector and the connecting bolt.

It further includes: the thermal insulation backing plate is a polytetrafluoroethylene board, and the thickness of the thermal insulation backing plate is not less than 25mm.

The thermal insulation board is a lightweight foamed ceramic thermal insulation board, the tensile strength of the thermal insulation board is not less than 0.25MPa, the thermal conductivity is not greater than 0.10, the water absorption is not greater than 8%, the heat storage coefficient is not less than 1.60, and the combustion performance is A1 .

The length of the expansion bolt anchored into the bearing layer of the wall is not less than 25 mm.

The depth at which the connecting bolts are anchored into the thermal insulation backing plate is not less than 20mm, and the connecting bolts cannot penetrate the thermal insulation backing plate and extend into the thermal insulation plate.

The heat insulating gasket and the heat insulating circular gasket are made of heat insulating elastic material, the thickness of the heat insulating gasket and the heat insulating circular gasket is not less than 5 mm, and the heat insulating gasket and the heat insulating circular gasket are not less than 5 mm in thickness. The diameter of the heat insulating round gasket is not smaller than the outer diameter of the nut.

The utility model has the following advantages: the utility model adopts bridge breaking and heat insulation technical measures to avoid the formation of thermal bridges between the installation bracket and the wall, realizes the energy-saving requirements of the bracket, improves the energy-saving efficiency of the building wall, and solves the problem of air-conditioning brackets in buildings. , Solar heat collecting support, rainwater pipe support, etc. and the thermal bridge problem of wall installation, meet the technical problems of energy-saving construction with high requirements for energy-saving support installation.

Description of drawings

Fig. 1 is the structural representation of the utility model;

In the figure: 1. Mounting bracket, 2. Thermal insulation pad, 3. Thermal insulation board, 4. Thermal insulation gasket, 5. Mounting frame connector, 6. Expansion bolt, 7. Thermal insulation round gasket, 8. Connecting bolt, 9, body of wall.

Detailed ways

A heat-proof bridge energy-saving support structure as shown in Figure 1, including a wall 9, is characterized in that: the outer side of the wall 9 is provided with a thermal insulation pad 2 through an expansion bolt 6, and the thermal insulation pad A thermal insulation board 3 is provided between the board 2 and the wall 9, and a thermal insulation gasket 4 is provided between the thermal insulation backing plate 2 and the expansion bolt 6; the outer side of the thermal insulation backing plate 2 A mounting bracket connecting piece 5 provided with a mounting bracket 1 is connected through a connecting bolt 8 , and a heat insulating round gasket 7 is arranged between the mounting bracket connecting piece 5 and the connecting bolt 8 . In the utility model, the installation bracket is installed on the thermal insulation backing plate, and the goal of breaking the bridge is realized through the thermal insulation backing plate between the installation bracket and the base wall, and the thermal insulation backing plate is fixed on the base wall by expansion bolts. A thermal insulation gasket is set between the expansion bolt and the thermal insulation backing plate, and the thermal insulation plate set between the thermal insulation backing plate and the wall further strengthens the effect of the thermal bridge; the mounting bracket is connected through the mounting bracket connector, Bolts and heat insulation round gaskets are connected with heat insulation pads, and heat insulation round gaskets and heat insulation pads isolate the direct contact between connecting bolts, mounting brackets and the base wall, avoiding the formation of heat transfer channels. The utility model can meet the high requirements of the design and construction of passive building wall energy saving, reduce the heat transfer loss of the heat bridge of the traditional installation bracket, and improve the building energy efficiency.

As shown in FIG. 1 , a thermal bridge energy-saving support structure, the thermal insulation backing plate 2 is a polytetrafluoroethylene board, and the thickness of the thermal insulation backing plate 2 is not less than 25mm. The polytetrafluoroethylene material used in the heat preservation and heat insulation backing board has good heat insulation performance, which meets the requirements of the utility model, and the thickness of the heat preservation and heat insulation backing board must be 25mm or more to achieve the expected effect, and better meet the requirements of heat protection. Bridge function and strength requirements.

A heat-proof bridge energy-saving support structure as shown in Figure 1, the thermal insulation board 3 is a lightweight foamed ceramic thermal insulation board, the tensile strength of the thermal insulation board 3 is not less than 0.25MPa, the thermal conductivity is not greater than 0.10, and the water absorption The efficiency is not more than 8%, the heat storage coefficient is not less than 1.60, and the combustion performance is A1. The thermal insulation board used in the utility model adopts lightweight foamed ceramic thermal insulation board, and some properties of the thermal insulation board, such as tensile strength, thermal conductivity, water absorption rate, heat storage coefficient and combustion grade, are within a reasonable range.

As shown in FIG. 1 , a heat-proof bridge energy-saving support structure, the length of the expansion bolt 6 anchored into the bearing layer of the wall body 9 is not less than 25mm. In order to ensure the stability of the entire structure, the length of the expansion bolt anchored into the wall bearing layer is at least 25mm.

A heat-proof bridge energy-saving support structure as shown in Figure 1, the depth of the connecting bolt 8 anchored into the thermal insulation backing plate 2 is not less than 20mm, and the connecting bolt 8 cannot penetrate the thermal insulation Backing plate 2 and stretches in described insulation board 3. The requirements for the length of the connecting bolts extending into the thermal insulation backing plate must not only ensure the strength and stability of the connection between the mounting frame connector and the thermal insulation backing plate, but also ensure that the connecting bolts cannot penetrate into the thermal insulation board. The purpose is to ensure the thermal bridge performance of the overall structure.

A heat-proof bridge energy-saving support structure as shown in Figure 1, the material of the heat-insulating gasket 4 and the heat-insulating round gasket 7 is a heat-insulating elastic material, and the heat-insulating gasket 4 and the heat-insulating circular gasket 7 The thickness of the thermal circular gasket 7 is not less than 5 mm, and the diameters of the thermal insulation gasket 4 and the thermal insulation circular gasket 7 are not smaller than the outer diameter of the nut. Heat insulating gaskets and round gaskets can not only reduce the pressure between the bolts and the contact area, thereby protecting the integrity of the contact area from being damaged, but more importantly, they also need to isolate the bolts from the contact area to avoid the formation of thermal bridges and cause heat loss. Therefore, the material of the thermal insulation gasket and the round gasket is adiabatic elastic material with a thickness of at least 5mm, and the diameter of the gasket is not smaller than the outer diameter of the bolt and nut.

A pilot passive building pilot project, the wall is reinforced concrete shear wall, the thickness of the structural wall is 150mm, and the heat transfer coefficient of the wall is required to be no more than 0.20 (W/m ² ·K). This utility model is used for the wall mounting bracket A new energy-saving support structure for thermal bridge protection. The implementation case adopts bridge breaking and heat insulation technical measures to avoid the formation of thermal bridges between the installation bracket and the wall, realize the energy-saving requirements of the bracket, and improve the energy-saving efficiency of the building wall.

The utility model can meet the high requirements of the design and construction of passive building wall energy-saving, reduce the heat transfer loss of the heat bridge of the traditional installation bracket, and improve the building energy efficiency. The thermal bridge energy-saving bracket structure is used to solve the technical problem of thermal bridge construction on the building wall. The energy-saving method of thermal bridge treatment has a heat transfer coefficient of no more than 0.195 (W/m ² ·K), achieving the expected energy-saving goal of the design.

Claims (6)

1. A heat-proof bridge energy-saving support structure, including a wall (9), characterized in that: the outer side of the wall (9) is provided with a thermal insulation backing plate (2) through expansion bolts (6), and the A thermal insulation board (3) is provided between the thermal insulation pad (2) and the wall (9), and a thermal insulation board (2) is provided between the thermal insulation pad (2) and the expansion bolt (6). Gasket (4); the outer side of the thermal insulation pad (2) is connected with the mounting bracket connector (5) provided with the mounting bracket (1) through the connecting bolt (8), and the mounting bracket connector (5) ) and the connecting bolts (8) are provided with heat-insulating round gaskets (7). 2. An energy-saving support structure for preventing heat bridges according to claim 1, characterized in that: the thermal insulation backing plate (2) is a polytetrafluoroethylene board, and the thermal insulation backing plate (2) The thickness is not less than 25mm. 3. The thermal bridge energy-saving support structure according to claim 1, characterized in that: the thermal insulation board (3) is a lightweight foamed ceramic thermal insulation board, and the tensile strength of the thermal insulation board (3) is less than Less than 0.25MPa, thermal conductivity not greater than 0.10, water absorption not greater than 8%, heat storage coefficient not less than 1.60, combustion performance A1. 4. The heat-resistant bridge energy-saving support structure according to claim 1, characterized in that the length of the expansion bolt (6) anchored into the bearing layer of the wall (9) is not less than 25 mm. 5. An energy-saving support structure for heat-resistant bridges according to claim 1, characterized in that: the depth of the connecting bolts (8) anchored into the thermal insulation backing plate (2) is not less than 20mm, and the The connecting bolts (8) cannot penetrate the thermal insulation pad (2) and extend into the thermal insulation board (3). 6. The energy-saving support structure for heat-resistant bridges according to claim 1, characterized in that: the materials of the heat-insulating gasket (4) and the heat-insulating round gasket (7) are heat-insulating elastic materials, The thickness of the heat insulation gasket (4) and the heat insulation circular gasket (7) is not less than 5 mm, and the diameter of the heat insulation gasket (4) and the heat insulation circular gasket (7) is not less than The outer diameter of the nut.