CN213897723U - Energy-conserving glass curtain wall of assembled - Google Patents

Abstract

The utility model relates to an energy-conserving glass curtain wall of assembled, it is including installing framework on the wall body, installing glass board in the framework and setting up the heat-conducting component on glass board, heat-conducting component is including surrounding at glass board heat conduction frame all around, wearing to locate a plurality of heat conduction filaments in the glass board and extending the heat conduction contact of glass board outer formation by heat conduction filament, heat conduction filament is align to grid in the glass board, heat conduction contact is inconsistent with heat conduction frame. The application has the effect of reducing the risk of bursting of the glass plate due to uneven heating.

Description

Energy-conserving glass curtain wall of assembled

Technical Field

The application relates to the field of glass curtain walls, in particular to an assembled energy-saving glass curtain wall.

Background

In recent years, news about personal injuries and property loss caused by burst of glass curtain walls on high-rise buildings is frequently available. Glass curtain wall buildings are becoming more and more popular as a combination of modern building technology and art. At present, the glass curtain wall with the exposed frame and the glass curtain wall with the hidden frame are generally available, wherein the glass curtain wall with the exposed frame is the most traditional form, the application is the most extensive, and the working performance is reliable; the aluminum alloy section with special section is used as a frame, and the glass panel is fully embedded into the groove of the section. The design of the exposed frame makes the glass panel heated unevenly, especially the temperature at the edge is lower than that at the center, so that the collision speed at the middle part is higher than the expansion speed at the edge, the stress is increased sharply, and the glass panel is burst.

Disclosure of Invention

In order to reduce the risk of bursting of the glass plates due to uneven heating, the application provides the assembled energy-saving glass curtain wall.

The application provides a pair of energy-conserving glass curtain wall of assembled adopts following technical scheme:

the utility model provides an assembled glass curtain wall, is including installing framework on the wall body, installing the glass board in the framework and setting up the heat-transfer assembly on the glass board, heat-transfer assembly is including surrounding at glass board heat conduction frame all around, wearing to locate a plurality of heat conduction filaments in the glass board and extending the heat conduction contact of glass board outer formation by the heat conduction filament, the heat conduction filament is align to grid in the glass board, the heat conduction contact is inconsistent with heat conduction frame.

Through adopting above-mentioned technical scheme, the thermal expansion rate of heat conduction filament is less than glass, is difficult for leading to glass inside to produce stronger stress because of the inflation when glass is heated the inflation. The heat conduction filament has better heat conductivity, and when the glass middle part was heated, the heat conduction filament will absorb glass's heat and with heat transfer to the heat conduction contact on, the heat conduction contact is used for increasing the area of contact of heat conduction filament and heat conduction frame to make the heat conduction filament can fully dispel the heat. On the one hand, the heat conduction fine wires can transmit the heat in the middle of the glass plate to the periphery to improve the uniform distribution of the heat on the glass plate, and on the other hand, the heat conduction frame uniformly heats the periphery of the glass plate after absorbing the heat of the metal contact. In conclusion, the heat of the glass plate is distributed more uniformly when being heated, and the risk of thermal explosion is reduced.

Preferably, the frame body includes that one side opening is equipped with the frame of installation spout, installs the inside casing in the installation spout and installs the fixed subassembly that is used for fixed inside casing on the frame, the heat conduction frame is installed in the installation spout and the shape and the open shape looks adaptation of installation spout, the shape of inside casing and the open shape looks adaptation of installation spout and the tank bottom cooperation centre gripping glass board of installation spout.

Through adopting above-mentioned technical scheme, when the installation, earlier push the glass board in the frame along the installation spout, until the butt in the tank bottom of installation spout, push the inside casing along the installation spout again, until the butt in the glass board, fixed inside casing of fixed subassembly is in order to prevent the outside roll-off of inside casing this moment, and inside casing and frame cooperate the centre gripping and fix the glass board. The inner frame, the outer frame and the glass plate can be simply separated by removing the fixing component during disassembly, and the disassembly is very convenient.

Preferably, a guide sliding groove is formed in the groove wall of the mounting sliding groove, a guide sliding block extending into the guide sliding groove is arranged at the edge of the inner frame, and the guide sliding block is connected with the guide sliding groove in a sliding mode.

Through adopting above-mentioned technical scheme, the direction spout plays the guide effect to the inside casing to prevent because production error leads to the unable locking inside casing of fixed subassembly when the unable accuracy of inside casing frame is counterpointed.

Preferably, the tank bottom of direction spout is provided with and holds the recess, fixed subassembly is including being located the commentaries on classics board that holds in the recess, wear to locate commentaries on classics board middle part and both ends and rotate respectively and connect in the axis of rotation that holds two relative cell walls of recess and connect commentaries on classics board one end and the pressure spring that holds the recess tank bottom, the axis of rotation is on a parallel with the tank bottom setting of installation spout, the pressure spring is located between the tank bottom of axis of rotation and installation spout.

Preferably, when the rotating plate rotates to a position parallel to the bottom of the accommodating groove, one side of the rotating plate departing from the bottom of the accommodating groove is flush with the side wall of the mounting chute.

Through adopting above-mentioned technical scheme, the pressure spring can make the tank bottom one end perk that the commentaries on classics board is close to the installation spout hold the recess, and when glass board or inside casing slided and the butt when changeing the board towards the tank bottom of installation spout, glass board or inside casing will oppress the commentaries on classics board and will change the board and impress in holding the recess, break away from mutually until glass board or inside casing and commentaries on classics board, and the pressure spring will be again will change the board and pop out holding the recess near the tank bottom one end of installation spout this moment to restriction inside casing roll-off installation spout. When needs separation inside casing, frame and glass board, only need to change the board and impress the installation spout and can remove the spacing to the inside casing, it is very convenient.

Preferably, the groove wall of the mounting chute is connected with the gap of the inner frame through glass cement.

Through adopting above-mentioned technical scheme, the glass is glued and is connected inside casing and frame fixed connection to block the intercommunication of glass board both sides. When the inner frame, the outer frame and the glass plate need to be separated, the glass cement is scraped, and the glass cement separating device is very convenient.

Preferably, the rotating plate is a metal plate.

Through adopting above-mentioned technical scheme, the commentaries on classics board is supported by metal material, will have higher intensity, can effectively prevent that the inside casing from deviating from the installation spout.

Preferably, the heat conducting filament is a copper wire, and the heat conducting contact is a copper contact.

Through adopting above-mentioned technical scheme, copper wire and copper contact have higher thermal conductivity, can the thermal-conductive component improve the effect of dispersion heat.

In summary, the present application includes at least one of the following beneficial technical effects:

1. the heat of the glass plate is distributed more uniformly when being heated, so that the risk of thermal explosion is reduced;

2. the outer frame, the inner frame and the glass plate are assembled mounting structures, so that the outer frame, the inner frame and the glass plate can be conveniently and quickly mounted and dismounted, and the construction efficiency is favorably improved.

Drawings

Fig. 1 is an overall schematic view of a fabricated energy-saving glass curtain wall in the embodiment of the application.

Fig. 2 is an exploded view of a fabricated energy-saving glass curtain wall in the embodiment of the application.

FIG. 3 is a cross-sectional view of a glass sheet and a thermally conductive assembly taken along a plane in which the axis of the thermally conductive filament is located in an embodiment of the present application.

Fig. 4 is a partial sectional view of an outer frame in an embodiment of the present application.

Fig. 5 is an enlarged view at a in fig. 4.

Description of reference numerals:

1. a frame body; 11. an outer frame; 111. installing a chute; 112. a guide chute; 113. an accommodating recess; 12. an inner frame; 121. a guide slider; 13. a fixing assembly; 131. a rotating shaft; 132. rotating the plate; 133. a pressure spring;

2. a glass plate;

3. a heat conducting component; 31. a thermally conductive frame; 32. a thermally conductive filament; 33. a thermally conductive contact.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses an assembled energy-saving glass curtain wall. Referring to fig. 1 and 2, the energy-saving glass curtain wall assembly includes a frame 1 mounted on a wall, a glass plate 2 mounted in the frame 1, and a heat-conducting assembly 3 disposed on the glass plate 2.

Referring to fig. 3, the heat conducting assembly 3 includes a heat conducting frame 31 surrounding the glass plate 2, a plurality of heat conducting filaments 32 penetrating the glass plate 2, and a heat conducting contact 33 formed by extending the heat conducting filaments 32 out of the glass plate 2, the heat conducting filaments 32 are uniformly arranged in the glass plate 2, and the heat conducting contact 33 is abutted to the heat conducting frame 31. In the present embodiment, the thermal conductive filament 32 is a copper wire, the thermal conductive contact 33 is a copper contact, and the thermal conductive frame 31 is an aluminum frame.

Referring to fig. 2, the frame body 1 includes an outer frame 11, an inner frame 12 and a fixing assembly 13, the outer frame 11 is used for being fixedly installed on a wall, an installation chute 111 is arranged in an opening on one side of the outer frame, an opening direction of the installation chute 111 is the same as a frame opening direction of the outer frame 11, in this embodiment, the outer frame 11 and the inner frame 12 are both square frames, a shape of the inner frame 12 is matched with an opening shape of the installation chute 111, and the heat conducting frame 31 is installed in the installation chute 111 and is matched with the opening shape of the installation chute 111. The inner frame 12 is matched with the groove bottom of the mounting chute 111 to clamp the glass plate 2, and the inner frame 12 is connected with the side wall of the mounting chute 111 through glass cement.

Referring to fig. 4 and 5, each groove wall of the mounting sliding groove 111 is provided with a guide sliding groove 112, and the guide sliding groove 112 is a square groove and is provided along a direction departing from the bottom of the mounting sliding groove 111. The edge of the inner frame 12 is provided with a guide sliding block 121 extending into the guide sliding chute 112, and the shape of the guide sliding block 121 is matched with the guide sliding chute 112 and is connected with the guide sliding chute 112 in a sliding manner. When the glass plate is installed, the glass plate 2 is pushed into the outer frame 11 along the installation chute 111 until the glass plate abuts against the bottom of the installation chute 111, the inner frame 12 is pushed into the inner frame 12 along the installation chute 111 until the glass plate 2 abuts against the inner frame, at this time, the inner frame 12 is fixed by the fixing component 13 to prevent the inner frame 12 from sliding outwards, and the inner frame 12 and the outer frame 11 are matched to clamp and fix the glass plate 2.

Referring to fig. 4 and 5, the groove bottom of the guide chute 112 is provided with a receiving groove 113, and in the present embodiment, the receiving groove 113 is a square groove. The fixing component 13 includes a rotating plate 132 located in the accommodating groove 113, a rotating shaft 131 penetrating through the middle of the rotating plate 132 and having two ends respectively rotatably connected to two opposite groove walls of the accommodating groove 113, and a pressure spring 133 connecting one end of the rotating plate 132 and the bottom of the accommodating groove 113, the rotating shaft 131 is parallel to the bottom of the mounting chute 111, the pressure spring 133 is located between the rotating shaft 131 and the bottom of the mounting chute 111, and in this embodiment, the rotating plate 132 is a metal plate. When the rotating plate 132 is rotated to a position parallel to the bottom of the receiving groove 113, a side of the rotating plate 132 facing away from the bottom of the receiving groove 113 is flush with a side wall of the mounting chute 111. The pressure spring 133 can tilt the end of the rotating plate 132 close to the bottom of the installation chute 111 out of the accommodating groove 113, when the glass plate 2 or the inner frame 12 slides towards the bottom of the installation chute 111 and abuts against the rotating plate 132, the glass plate 2 or the inner frame 12 will press the rotating plate 132 and press the rotating plate 132 into the accommodating groove 113 until the glass plate 2 or the inner frame 12 is separated from the rotating plate 132, and at this time, the pressure spring 133 will eject the end of the rotating plate 132 close to the bottom of the installation chute 111 out of the accommodating groove 113 again, so as to limit the inner frame 12 from sliding out of the installation chute 111.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides an energy-conserving glass curtain wall of assembled, its characterized in that, is including installing framework (1) on the wall body, installing glass board (2) in framework (1) and setting up heat-conducting component (3) on glass board (2), heat-conducting component (3) are including surrounding at glass board (2) heat conduction frame (31) all around, wear to locate a plurality of heat conduction filaments (32) in glass board (2) and extend glass board (2) outer heat conduction contact (33) that forms by heat conduction filament (32), heat conduction filament (32) align to grid in glass board (2), heat conduction contact (33) are inconsistent with heat conduction frame (31).

2. The assembled energy-saving glass curtain wall as claimed in claim 1, wherein the frame body (1) comprises an outer frame (11) with an opening at one side provided with a mounting chute (111), an inner frame (12) mounted in the mounting chute (111), and a fixing component (13) mounted on the outer frame (11) and used for fixing the inner frame (12), the heat-conducting frame (31) is mounted in the mounting chute (111) and has a shape matched with the opening shape of the mounting chute (111), and the inner frame (12) has a shape matched with the opening shape of the mounting chute (111) and matched with the groove bottom of the mounting chute (111) to clamp the glass plate (2).

3. The assembled energy-saving glass curtain wall as claimed in claim 2, wherein a guide chute (112) is formed in a chute wall of the mounting chute (111), a guide slider (121) extending into the guide chute (112) is arranged at an edge of the inner frame (12), and the guide slider (121) is connected with the guide chute (112) in a sliding manner.

4. The assembled energy-saving glass curtain wall as claimed in claim 3, wherein the guide chute (112) is provided with a receiving groove (113) at the bottom, the fixing component (13) comprises a rotating plate (132) positioned in the receiving groove (113), a rotating shaft (131) penetrating the middle of the rotating plate (132) and having two ends respectively rotatably connected to two opposite walls of the receiving groove (113), and a compression spring (133) connecting one end of the rotating plate (132) and the bottom of the receiving groove (113), the rotating shaft (131) is arranged parallel to the bottom of the mounting chute (111), and the compression spring (133) is positioned between the rotating shaft (131) and the bottom of the mounting chute (111).

5. The energy-saving glass curtain wall of claim 4, wherein when the rotating plate (132) rotates to a position parallel to the bottom of the receiving groove (113), the side of the rotating plate (132) facing away from the bottom of the receiving groove (113) is flush with the side wall of the mounting chute (111).

6. The assembled energy-saving glass curtain wall as claimed in claim 5, wherein the gap between the groove wall of the mounting chute (111) and the inner frame (12) is connected by glass cement.

7. The energy-saving glass curtain wall of claim 4, wherein the rotating plate (132) is a metal plate.

8. The energy-saving glass curtain wall of assembly type according to claim 1, characterized in that the heat-conducting filament (32) is a copper wire and the heat-conducting contact (33) is a copper contact.

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