CN216587314U - Green healthy low carbon building energy-saving wall of heat exchange - Google Patents

Abstract

The utility model discloses a heat exchange green, healthy and low-carbon building energy-saving wall which comprises an energy-saving wall main body and sliding blocks, wherein two sides of the outer wall of the energy-saving wall main body are connected with connecting mechanisms in a sliding mode, the bottom end of each connecting mechanism is connected with a bottom rod, a pressing plate is arranged in the middle of the inner wall of the energy-saving wall main body, clamping grooves with the same size are formed in two sides of the inner wall of each pressing plate, positioning blocks are welded on two sides of the outer wall of each clamping groove, and the sliding blocks are arranged on two sides of the outer wall of the energy-saving wall main body. According to the heat exchange green, healthy and low-carbon building energy-saving wall, the connecting mechanism is of a detachable structure, and the bottom rod, the ejector rod, the pressing plate and the energy-saving wall main body are matched for use, so that the energy-saving wall is more convenient to detach or install; through setting up energy-conserving wall main part including preventing scraping layer, anticorrosive coating, insulating layer, puigging and vacuum layer, can reduce the heat transfer among the heat-conduction process effectively, have good thermal-insulated and syllable-dividing effect.

Description

Green healthy low carbon building energy-saving wall of heat exchange

Technical Field

The utility model relates to the relevant technical field of buildings, in particular to a heat exchange green, healthy and low-carbon building energy-saving wall.

Background

The wall body mainly comprises a bearing wall and a non-bearing wall, and mainly plays roles of enclosing and separating a space, the wall body of a wall bearing structure building integrates bearing and enclosing, the wall body of a framework structure system building serves as the enclosing and separating space, the wall body has enough strength and stability, has the capabilities of heat preservation, heat insulation, sound insulation, fire prevention and water prevention, is more in variety of wall bodies, has a single-material wall body and a composite-material wall body, and comprehensively considers the factors of enclosing, bearing, energy conservation, attractiveness and the like, so that a reasonable wall body scheme is designed, and is an important task of building construction, heat exchange is a heat transfer process between two objects or parts of the same object caused by temperature difference, and heat exchange is generally completed in three modes of heat conduction, heat convection and heat radiation, so that the heat exchange green, healthy and low-carbon building energy-saving wall is provided.

The existing building energy-saving wall is usually provided with a heat-insulating material inside the wall body to prevent the heat exchange process, but the heat-insulating effect is not obvious, and the common non-bearing energy-saving wall is inconvenient to assemble or disassemble.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a heat exchange green, healthy and low-carbon building energy-saving wall, which aims to solve the problems that the heat insulation material is usually arranged in the wall body to prevent the heat exchange process of the existing building energy-saving wall in the background technology, but the heat insulation effect is not obvious, and the common non-bearing energy-saving wall is inconvenient to assemble or disassemble.

In order to achieve the purpose, the utility model provides the following technical scheme: a heat exchange green healthy low-carbon building energy-saving wall comprises an energy-saving wall main body and sliding blocks, wherein two sides of the outer wall of the energy-saving wall main body are connected with connecting mechanisms in a sliding manner, the bottom end of the connecting mechanism is connected with a bottom rod, the top end of the connecting mechanism is fixedly provided with an ejector rod, the middle position of the inner wall of the energy-saving wall main body is provided with a pressing plate, the two sides of the inner wall of the pressing plate are both provided with clamping grooves with the same size, positioning blocks are welded on two sides of the outer wall of the clamping groove, the sliding blocks are arranged on two sides of the outer wall of the energy-saving wall main body, the two sides below the outer wall of the energy-saving wall main body are both provided with fixed blocks with the same size, the inner wall of the energy-saving wall main body comprises a scratch-resistant layer, an anti-corrosion layer, a heat insulation layer, a sound insulation layer and a vacuum layer, circular joint interface is all installed at the outer wall top both sides edge of sill bar, rectangular joint piece has been seted up to coupling mechanism's outer wall below.

Preferably, coupling mechanism includes connecting block, spout and fixture block, the outer wall top at energy-conserving wall main part is installed to the connecting block, the inner wall of connecting block is equipped with size assorted spout, the welding of the outer wall below of connecting block has the fixture block.

Preferably, the sliding blocks and the connecting blocks form a sliding structure through the sliding grooves, and the sliding blocks are symmetrically arranged with a central axis of the energy-saving wall main body.

Preferably, the fixed block is connected with the pressing plate in a clamping mode through a clamping groove, and the width of the clamping groove is larger than that of the fixed block.

Preferably, the outermost side of the energy-saving wall main body is symmetrically provided with a scratch-resistant layer, the inner side of the scratch-resistant layer is symmetrically provided with an anti-corrosion layer, a heat insulation layer and a sound insulation layer respectively, and a vacuum layer is arranged inside the sound insulation layer.

Preferably, the circular clamping interface is connected with the bottom rod in a clamping mode through a clamping block, and the circular clamping interface is symmetrically arranged on the central axis of the bottom rod.

Compared with the prior art, the utility model has the beneficial effects that:

the heat exchange green, healthy and low-carbon building energy-saving wall has the advantages that the connecting mechanism is arranged to be a detachable structure, and the bottom rod, the ejector rod, the pressing plate and the energy-saving wall main body are matched for use, so that the energy-saving wall is more convenient to detach or install; the energy-saving wall main body comprises the anti-scraping layer, the anti-corrosion layer, the heat insulation layer, the sound insulation layer and the vacuum layer, so that heat transfer in the heat conduction process can be effectively reduced, and good heat insulation and sound insulation effects are achieved; the device has simple structure, reasonable arrangement and high practicability.

Drawings

FIG. 1 is a schematic front view of the present invention;

FIG. 2 is a schematic view of the connecting mechanism of the present invention;

FIG. 3 is a schematic view of the internal structure of the energy-saving wall body according to the present invention;

FIG. 4 is a schematic view of the surface structure of the platen according to the present invention.

In the figure: 1. an energy-saving wall main body; 2. a connecting mechanism; 201. connecting blocks; 202. a chute; 203. a clamping block; 3. a bottom bar; 4. a top rod; 5. pressing a plate; 6. a card slot; 7. positioning blocks; 8. a slider; 9. a fixed block; 10. a scratch-resistant layer; 11. an anti-corrosion layer; 12. a thermal insulation layer; 13. a sound insulating layer; 14. a vacuum layer; 15. a circular card interface; 16. a rectangular clamping block.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-4, the present invention provides a technical solution: a heat exchange green healthy low-carbon building energy-saving wall comprises an energy-saving wall main body 1 and a sliding block 8;

outer wall both sides sliding connection of energy-conserving wall main part 1 has coupling mechanism 2, coupling mechanism 2's bottom is connected installs sill bar 3, coupling mechanism 2's top fixed mounting has ejector pin 4, energy-conserving wall main part 1's inner wall intermediate position sets up installs clamp plate 5, the same draw-in groove 6 of size is all seted up to clamp plate 5's inner wall both sides, locating piece 7 has all been welded to draw-in groove 6's outer wall both sides, slider 8 installs the outer wall both sides at energy-conserving wall main part 1, the same fixed block 9 of size is all installed to energy-conserving wall main part 1's outer wall below both sides, energy-conserving wall main part 1's inner wall is including preventing scraping layer 10, anti-corrosion layer 11, insulating layer 12, puigging 13 and vacuum layer 14, circular joint mouth 15 is all installed to sill bar 3's outer wall top both sides edge, rectangular joint piece 16 has been seted up to coupling mechanism 2's outer wall below.

Connecting mechanism 2 includes connecting block 201, spout 202 and fixture block 203, connecting block 201 is installed in the outer wall top of energy-conserving wall main part 1, the inner wall of connecting block 201 is equipped with size assorted spout 202, the welding of outer wall below of connecting block 201 has fixture block 203, connecting mechanism 2 can be connected between sill bar 3 and clamp plate 5, locating piece 7 at the installation of 5 outer walls of clamp plate carries out gliding in the middle of the inner wall of spout 202, the fixed circular opening with fixture block 203 inner wall installation, fix in the middle of the circular joint interface 15 of the installation of the inner wall both sides of sill bar 3, then can fix a position connecting block 201's position like this.

The sliding block 8 forms a sliding structure with the connecting block 201 through the sliding groove 202, and the sliding block 8 is symmetrically arranged with the central axis of the energy-saving wall main body 1, so that the connecting mechanism 2 is conveniently installed on the two side positions of the energy-saving wall main body 1, and the position of the energy-saving wall main body 1 is conveniently located.

The fixing block 9 is connected with the pressing plate 5 in a clamping mode through the clamping groove 6, the width of the clamping groove 6 is larger than that of the fixing block 9, the fixing block 9 below the energy-saving wall main body 1 is fixed in the middle of the inner wall of the clamping groove 6, and therefore the energy-saving wall main body 1 can be installed conveniently.

The outermost side of the energy-saving wall main body 1 is symmetrically provided with a scratch-resistant layer 10, the inner side of the scratch-resistant layer 10 is symmetrically provided with an anti-corrosion layer 11, a heat insulation layer 12 and a sound insulation layer 13 respectively, and a vacuum layer 14 is arranged inside the sound insulation layer 13, so that heat transfer in the heat conduction process can be effectively reduced, and good heat insulation and sound insulation effects are achieved.

Circular joint interface 15 passes through fixture block 203 and is connected with the dead lever 3 block, and circular joint interface 15 sets up with the axis symmetry of dead lever 3, is convenient for like this install coupling mechanism 2 on the both sides position of dead lever 3, is convenient for dismantle coupling mechanism 2 simultaneously.

The working principle is as follows: firstly, the device is placed at a designated position, the connecting mechanism 2 can connect the bottom rod 3 and the pressing plate 5, when the positioning block 7 arranged on the outer wall of the pressing plate 5 slides in the inner wall of the chute 202, the circular opening for installing the inner wall of the clamping block 203 is fixed in the circular clamping interface 15 arranged on the two sides of the inner wall of the bottom rod 3, so that the position of the connecting block 201 can be positioned, the energy-saving wall main body 1 is conveniently installed in the inner walls of the bottom rod 3 and the pressing plate 5, meanwhile, the fixing block 9 below the energy-saving wall main body 1 is fixed in the inner wall of the clamping groove 6, so that the energy-saving wall main body 1 is conveniently installed, the inner wall of the energy-saving wall main body 1 is provided with the anti-scraping layer 10, the anti-corrosion layer 11, the thermal insulation layer 12, the sound insulation layer 13 and the vacuum layer 14, and thus the heat transfer in the heat conduction process can be effectively reduced, have good thermal-insulated and syllable-dividing effect, fix the rectangle joint piece 16 of ejector pin 4 below in the spout 202 that the connecting block 201 inner wall was seted up is suitable for like this to carry out fixed mounting to the top position of energy-conserving wall main part 1, has just so accomplished the operation flow of the green healthy low carbon building energy-saving wall of a heat exchange.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a green healthy low carbon building energy-saving wall of heat exchange, includes energy-conserving wall main part (1) and slider (8), its characterized in that: the energy-saving wall is characterized in that the two sides of the outer wall of the energy-saving wall main body (1) are slidably connected with connecting mechanisms (2), the bottom ends of the connecting mechanisms (2) are connected with bottom rods (3), ejector rods (4) are fixedly mounted at the top ends of the connecting mechanisms (2), pressing plates (5) are arranged at the middle positions of the inner walls of the energy-saving wall main body (1), clamping grooves (6) with the same size are formed in the two sides of the inner wall of each pressing plate (5), positioning blocks (7) are welded on the two sides of the outer wall of each clamping groove (6), sliding blocks (8) are mounted on the two sides of the outer wall of the energy-saving wall main body (1), fixing blocks (9) with the same size are mounted on the two sides below the outer wall of the energy-saving wall main body (1), and the inner wall of the energy-saving wall main body (1) comprises an anti-scraping layer (10), an anti-corrosion layer (11), a heat insulation layer (12), a sound insulation layer (13) and a vacuum layer (14), circular joint interface (15) are all installed to the outer wall top both sides edge of sill bar (3), rectangle joint piece (16) have been seted up to the outer wall below of coupling mechanism (2).

2. The heat exchange green healthy low-carbon building energy-saving wall as claimed in claim 1, is characterized in that: connecting mechanism (2) include connecting block (201), spout (202) and fixture block (203), the outer wall top at energy-conserving wall main part (1) is installed in connecting block (201), the inner wall of connecting block (201) is equipped with size assorted spout (202), the welding of the outer wall below of connecting block (201) has fixture block (203).

3. The heat exchange green healthy low-carbon building energy-saving wall as claimed in claim 1, is characterized in that: the sliding block (8) forms a sliding structure with the connecting block (201) through the sliding groove (202), and the sliding block (8) is symmetrically arranged on the central axis of the energy-saving wall main body (1).

4. The heat exchange green healthy low-carbon building energy-saving wall as claimed in claim 1, is characterized in that: the fixing block (9) is connected with the pressing plate (5) in a clamping mode through the clamping groove (6), and the width of the clamping groove (6) is larger than that of the fixing block (9).

5. The heat exchange green healthy low-carbon building energy-saving wall as claimed in claim 1, is characterized in that: the energy-saving wall is characterized in that the outermost side of the energy-saving wall main body (1) is symmetrically provided with a scratch-proof layer (10), the inner side of the scratch-proof layer (10) is symmetrically provided with an anti-corrosion layer (11), a heat insulation layer (12) and a sound insulation layer (13) respectively, and a vacuum layer (14) is arranged inside the sound insulation layer (13).

6. The heat exchange green healthy low-carbon building energy-saving wall as claimed in claim 1, is characterized in that: the round clamping interface (15) is clamped and connected with the bottom rod (3) through a clamping block (203), and the round clamping interface (15) is symmetrically arranged along the central axis of the bottom rod (3).

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