CN115162580B

CN115162580B - Embedded wood structure glass curtain wall

Info

Publication number: CN115162580B
Application number: CN202210746960.7A
Authority: CN
Inventors: 鲁志俊; 何永春; 舒云峰
Original assignee: Chongqing Design Institute Co ltd
Current assignee: Chongqing Design Institute Co ltd
Priority date: 2022-06-29
Filing date: 2022-06-29
Publication date: 2023-10-10
Anticipated expiration: 2042-06-29
Also published as: CN115162580A

Abstract

The invention belongs to the field of building processing, and particularly discloses an embedded wood structure glass curtain wall, which comprises glass, a supporting component and a connecting component, wherein the supporting component comprises a truss, the connecting component comprises a first connecting piece for connecting the end part of the glass with the inner wall of a mounting hole, the first connecting piece comprises two symmetrically arranged angle steels, one right-angle side of each angle steel is detachably connected with the inner wall of the mounting hole, and the other right-angle side of each angle steel is used for limiting the glass; the glass is characterized by further comprising a buffer assembly, wherein the buffer assembly is used for buffering the displacement of the glass relative to the truss or the glass relative to the angle steel, and the buffer assembly comprises a flexible cushion block arranged on one side of the angle steel, which faces to the glass, and on the inner wall of the mounting hole. By adopting the scheme of the invention, the problem that glass is damaged easily due to the fact that the displaced glass directly collides on the truss or the connecting member when the glass is subjected to thermal expansion or encounters extreme weather environments such as strong wind, earthquake and the like and is displaced to a certain extent relative to the truss can be solved.

Description

Embedded wood structure glass curtain wall

Technical Field

The invention belongs to the field of building processing, and particularly relates to an embedded wood structure glass curtain wall.

Background

Glass curtain walls are a beautiful and novel method for decorating building walls, are a remarkable feature of the modern times of high-rise buildings, and generally comprise trusses and glass mounted on the trusses, the trusses being usually used for bearing loads and being processed into a desired shape, such as triangular frames. With the deep energy-saving and environment-friendly concept, wood-structure buildings are attracting more and more attention, and wood-structure glass curtain walls are trusses with wood structures as glass installation.

In the case of the girder, since the girder is usually finished in advance, when installing glass, the glass is usually connected to the outer side or the inner side of the girder through a connection member, for example, patent CN202110924587.5 discloses a connection method of a wood structure glass curtain wall, and the glass is installed to the outer side of a keel. In order to achieve the attractive appearance of the inside of a building, the glass is embedded into the truss, the installation and connection modes of the glass and the truss are needed to be considered, meanwhile, after the glass is embedded into the truss, the glass is directly contacted with the truss, and due to the fact that the thermal expansion coefficients of the glass and the truss are different, when the thermal expansion occurs at a high temperature, the situation that the glass is mutually extruded easily occurs, the glass is damaged, and the glass curtain wall requires that the glass can cope with extreme weather environments such as strong wind and earthquakes, namely, the glass can generate certain displacement relative to the truss, and the displaced glass is directly collided on the truss or a connecting member, so that the glass is easily damaged.

Disclosure of Invention

Aiming at the defects in the prior art, the invention provides an embedded wood structure glass curtain wall, which solves the problems that when glass is subject to thermal expansion or encounters extreme weather environments such as strong wind, earthquake and the like, the glass generates certain displacement relative to a truss, and the displaced glass directly collides with the truss or a connecting member, so that the glass is easy to damage.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

the embedded wood structure glass curtain wall comprises glass, a supporting component for installing the glass and a connecting component for connecting the glass and the supporting component, wherein the supporting component comprises a truss, a plurality of installing holes for installing the glass are formed in the truss, the connecting component comprises a first connecting piece for connecting the end part of the glass with the inner wall of the installing hole, the first connecting piece comprises two symmetrically arranged angle steels, one right-angle side of each angle steel is detachably connected with the inner wall of the installing hole, and the other right-angle side of each angle steel is used for limiting the glass; the glass is characterized by further comprising a buffer assembly, wherein the buffer assembly is used for buffering the displacement of the glass relative to the truss or the glass relative to the angle steel, and comprises a flexible cushion block arranged on one side of the angle steel facing to the glass and on the inner wall of the mounting hole, and the flexible cushion block is used for being attached to the end part of the glass or the surface of the glass.

Compared with the prior art, the invention has the following beneficial effects:

through the setting of angle steel, when assembling glass, a piece of angle steel is fixed at mounting hole inner wall Zhou Xiangxian, then place glass in the mounting hole and paste with the angle steel mutually, and another piece of angle steel is fixed at mounting hole inner wall circumference again, can be simple accomplish the assembly to glass. Meanwhile, the flexible cushion blocks are arranged in the angle steel and the mounting holes, so that the flexible cushion blocks are attached to the glass, and the glass can be subjected to the buffer effect of the flexible cushion blocks when subjected to thermal expansion or displacement in extreme weather environments such as strong wind, earthquake and the like, and damage caused by direct rigid contact with the truss and the angle steel is avoided.

Drawings

Fig. 1 is a schematic overall structure of an embodiment of the present invention.

Fig. 2 is an enlarged view of a portion a in fig. 1.

Fig. 3 is an enlarged view of a portion B in fig. 1.

Fig. 4 is a schematic diagram of another arrangement of the portion a in fig. 1.

Fig. 5 is a schematic diagram of another arrangement of the portion B in fig. 1.

Fig. 6 is a schematic structural diagram of an air inlet and an air outlet in an embodiment of the present invention.

In the figure: 1. truss; 2. glass; 3. a keel; 4. angle steel; 5. a buckle plate; 6. a flexible cushion block; 7. i-steel; 8. a second slider; 9. a second chute; 10. an elastic member; 11. a first slider; 12. a first chute; 13. a first communication hole; 14. a second communication hole; 15. an airway; 16. an air inlet hole; 17. and an air outlet hole.

Detailed Description

The invention is described in further detail below with reference to the drawings in the specification and the detailed description is given.

As shown in fig. 1 and 2, the embedded wood structure glass curtain wall comprises glass 2, a support component for installing the glass 2 and a connection component for connecting the glass 2 and the support component, the support component comprises a truss 1, a plurality of installation holes for installing the glass 2 are formed in the truss 1, the connection component comprises a first connecting piece for connecting the end part of the glass 2 with the inner wall of the installation hole, the first connecting piece comprises two symmetrically arranged angle steels 4, one right-angle side of each angle steel 4 and the inner wall of the installation hole are detachably connected (hereinafter, the right-angle side of each angle steel 4 is called as an installation part of each angle steel 4), the other right-angle side of each angle steel 4 is used for limiting the glass 2 (hereinafter, the right-angle side of each angle steel 4 is called as a limiting part of each angle steel 4), and specifically, each angle steel 4 is fixed on the inner wall of the installation hole through a special bolt for wood structure in the prior art, and the installation parts of the two angle steels 4 are arranged in a back direction.

The embedded wood structure glass curtain wall still includes buffer assembly, buffer assembly is used for carrying out the displacement to glass 2 relative truss 1 or glass 2 relative angle steel 4, buffer assembly is including installing the flexible cushion 6 in angle steel 4 towards one side of glass 2, mounting hole inner wall, flexible cushion 6 is used for pasting with glass 2 tip or glass 2 surface, in this embodiment, flexible cushion 6 selects rubber cushion, flexible cushion 6 is fixed in the spacing portion of angle steel 4, the inner wall of mounting hole, paste mutually through flexible cushion 6 and glass 2, glass 2 can receive flexible cushion 6's cushioning effect when taking place thermal expansion or displacement because of extreme weather environment such as strong wind, earthquake, avoid direct and truss 1, damage that angle steel 4 rigid contact leads to.

In another embodiment of the present invention, as shown in fig. 3, a plurality of glass pieces 2 are installed in the installation hole, and as shown in fig. 3, two glass pieces 2 are installed in the installation hole, and the two glass pieces 2 are distributed up and down, and the connection assembly further includes a second connection piece for connecting the adjacent glass pieces 2, where the second connection piece includes an i-steel 7, two ends of the i-steel 7 are respectively used for clamping into the end parts of the adjacent glass pieces 2, and specifically, the concave parts at two ends of the i-steel 7 respectively limit the upper and lower glass pieces 2.

The supporting component further comprises a keel 3 fixed on the truss 1, a buckle plate 5 used for limiting the angle steel 4 and the I-steel 7 is arranged on the keel 3, and the buckle plate 5 is a common steel buckle plate 5 in the prior art and is used for being clamped on the outer sides of the angle steel 4 and the I-steel 7, and the keel 3 is fixedly connected with the truss 1. The buffer assembly also comprises a flexible cushion block 6 fixed on the inner side of the I-steel 7, when the buffer assembly is installed, after installing one glass 2, the I-steel 7 is installed at one end of the glass 2 which is not attached to the inner wall of the installation hole (namely, the lower end or the upper end of the glass 2 shown in fig. 3), then a second glass 2 is installed, and a plurality of glass 2 are assembled through the matching of the I-steel 7.

In another embodiment of the present invention, as shown in fig. 4 and 5, the buffer assembly includes a first chute 12 formed on the angle steel 4 and the i-steel 7, and a second chute 9 formed on the truss 1 and the i-steel 7, wherein the opening of the first chute 12 faces the surface of the glass 2, the opening of the second chute 9 faces the end of the glass 2, the first chute 12 on the angle steel 4 is communicated with the second chute 9 on the truss 1 connected with the angle steel 4, and the first chute 12 and the second chute 9 on the i-steel 7 on the same side of the i-steel 7 are communicated. Specifically, the spacing portion of angle steel 4 is last to have seted up first spout 12, has seted up the first communication hole 13 with first spout 12 intercommunication on the installation department of angle steel 4, has seted up second spout 9 on the truss 1, has seted up the second intercommunicating pore 14 with second spout 9 intercommunication on the truss 1, and after angle steel 4 installs to be connected to on the truss 1, first communication hole 13 and second intercommunicating pore 14 aim at the intercommunication, can bond sealed pad on the installation department of angle steel 4 in order to guarantee the leakproofness of gap between angle steel 4 and the truss 1. The structural design in the I-steel 7 is vertically symmetrical, and the upper part of the I-steel 7 is taken as an example for description, and the upper part of the I-steel 7 is provided with a U-shaped air passage 15, and the first chute 12 and the second chute 9 are communicated with the air passage 15.

The first sliding groove 12 is slidably connected with a first sliding block 11, the second sliding groove 9 is slidably connected with a second sliding block 8, elastic pieces 10 are respectively fixed between the first sliding block 11 and the inner wall of the first sliding groove 12 and between the second sliding block 8 and the inner wall of the second sliding groove 9, and specifically, the elastic pieces 10 are springs. The flexible cushion block 6 is wrapped outside the first slide block 11 and the second slide block 8 or fixed on one side of the first slide block 11 and one side of the second slide block 8 facing the glass 2, and in this embodiment, the flexible cushion block 6 is fixed on one side of the first slide block 11 and one side of the second slide block 8 facing the glass 2.

The movement principles of the end of the glass 2 contacting the truss 1 and the end of the glass 2 contacting the i-beam 7 are identical, and the movement principles of the end of the glass 2 contacting the truss 1 shown in fig. 4 will be described below by taking as an example, when the two side surfaces of the glass 2 respectively abut against the first sliding blocks 11 located at the two sides of the glass, and when the end of the glass 2 abuts against the second sliding blocks 8, the amounts of gas in the first sliding groove 12, the second sliding groove 9, the first communication hole 13 and the second communication hole 14 remain unchanged. When the glass 2 is displaced in the horizontal direction, for example, the glass 2 is displaced to the right, the glass 2 pushes the first slide block 11 on the right to move into the first slide groove 12, the buffer effect is further improved through the elastic piece 10, and the gas in the first slide groove 12 on the right enters the second slide groove 9 or the first slide groove 12 on the left, because the glass 2 is displaced to the right, the glass 2 and the first slide block 11 on the left are not abutted, the gas is easier to enter the first slide groove 12 on the left, so that the first slide block 11 on the left moves outwards of the first slide groove 12, further abuts against the glass 2, the first slide blocks 11 on the two sides perform a certain limiting effect along with the glass 2, meanwhile, the buffer effect is also achieved, and the damage of the glass 2 is avoided.

When glass 2 takes place the displacement of vertical direction, glass 2 upward movement promotes second slider 8, and second slider 8 moves to second spout 9 internal motion, and the gas in the second spout 9 gets into in the first spout 12 of both sides for first slider 11 moves outside first spout 12, and then first slider 11 further extrudees and supports tight glass 2, reduces glass 2's vertical displacement, and avoids glass 2 to a certain extent to receive the damage that gravity and inertial force directly drop and lead to when shifting down again after upwards displacement.

In the actual use process, in order to avoid that the glass 2 directly collides on the truss 1 or the angle steel 4 or the I-steel 7, the length of the first sliding block 11 is larger than that of the first sliding groove 12, the length of the second sliding block 8 is larger than that of the second sliding groove 9, namely, when the first sliding block 11 moves to be propped against the inner wall of the first sliding groove 12, the first sliding block 11 is still partially positioned outside the first sliding groove 12, and as the flexible cushion block 6 is fixed on the first sliding block 11, the glass 2 continues to displace, and the flexible cushion block 6 can be extruded to deform.

In another embodiment of the present invention, when the elastic member 10 is in a natural state, the distance between the two first sliding blocks 11 is smaller than the thickness of the glass 2, and after the glass 2 is placed between the two first sliding blocks 11, the first sliding blocks 11 are pressed, so that the elastic member 10 contracts, and the first sliding blocks 11 are subjected to the restoring force of the elastic member 10, so that the glass 2 can be better propped against and limited by the glass 2. With reference to fig. 2, a notch for the first slider 11 to be clamped in is formed in the glass 2, and the first slider 11 is clamped in the notch to vertically limit the glass 2, so that the vertical displacement of the glass 2 is reduced.

In another embodiment of the present invention, as shown in fig. 6, the angle steel 4 and the i-steel 7 are provided with an air inlet hole 16 and an air outlet hole 17, in fig. 6, the air inlet hole 16 and the air outlet hole 17 on the i-steel 7 are taken as examples, the air inlet hole 16 and the air outlet hole 17 penetrate through the buckle plate 5 and the keel 3, the openings of the air inlet hole 16 and the air outlet hole 17 face the outer side of the curtain wall when the curtain wall is installed, the air inlet hole 16 and the air outlet hole 17 are communicated with each other, specifically, the air inlet hole 16 is communicated with the first chute 12 or the second chute 9 or the first chute 12 or the second chute 9 (i.e. the first communication hole 13 or the second communication hole 14 or the air channel 15), and the air outlet hole 17 is also communicated with the first chute 12 or the second chute 9 or the first chute 12 and the second chute 9 (i.e. the first communication hole 13 or the second communication hole 15). The opening of the air inlet hole 16 is provided with a flaring part, a one-way valve for air supply to enter the I-steel 7 or the angle steel 4 in a one-way is arranged in the air inlet hole 16, and a pressure limiting valve is arranged in the air outlet hole 17.

When the strong wind weather is met, wind blows to the angle steel 4 and the I-steel 7, the wind can enter the first chute 12 or the second chute 9 through the air inlet hole 16, on one hand, the gas lost in the first chute 12 and the second chute 9 is supplemented, and when the gas supplementation is finished, namely, the first chute 12, the second chute 9, the first communication hole 13, the second communication hole 14 and the air passage 15 are filled with the gas, the gas continues to enter through the air inlet hole 16, the pressure limiting valve in the air outlet hole 17 is opened, and the redundant gas is discharged; on the other hand, the wind enters the wind inlet hole 16, so that the impact of the wind on the angle steel 4 and the I-steel 7 is reduced to a certain extent.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Finally, it is noted that the above embodiments are only for illustrating the technical solution of the present invention and not for limiting the same, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that modifications and equivalents may be made thereto without departing from the spirit and scope of the technical solution of the present invention, which is intended to be covered by the scope of the claims of the present invention.

Claims

1. The utility model provides an embedded wood structure glass curtain wall, includes glass, is used for installing glass's supporting component and is used for the coupling assembling who connects glass and supporting component, and supporting component includes the truss, has seted up a plurality of mounting holes that are used for installing glass on the truss, its characterized in that: the connecting assembly comprises a first connecting piece for connecting the end part of the glass with the inner wall of the mounting hole, the first connecting piece comprises two symmetrically arranged angle steels, one right-angle side of each angle steel is detachably connected with the inner wall of the mounting hole, and the other right-angle side of each angle steel is used for limiting the glass; the buffer assembly is used for buffering the displacement of the glass relative to the truss or the glass relative to the angle steel, and comprises a flexible cushion block arranged on one side of the angle steel facing the glass and on the inner wall of the mounting hole, wherein the flexible cushion block is used for being attached to the end part of the glass or the surface of the glass; the mounting hole is internally provided with a plurality of pieces of glass, the connecting assembly further comprises a second connecting piece for connecting adjacent pieces of glass, the second connecting piece comprises I-steel, and two ends of the I-steel are respectively used for being clamped into the end parts of the adjacent pieces of glass; the supporting component also comprises a keel fixed on the truss, and a buckle plate used for limiting the angle steel and the I-steel is arranged on the keel; the buffer component comprises a first chute arranged on the angle steel and the I-steel, and a second chute arranged on the truss and the I-steel, wherein the opening of the first chute faces to the surface of the glass, the opening of the second chute faces to the end part of the glass, the first chute on the angle steel is communicated with the second chute on the truss connected with the angle steel, and the first chute and the second chute on the I-steel, which are positioned on the same side of the I-steel, are communicated; the first sliding groove is internally and slidably connected with a first sliding block, the second sliding groove is internally and slidably connected with a second sliding block, and the flexible cushion block is coated on the outer sides of the first sliding block and the second sliding block or fixed on one side, facing glass, of the first sliding block and the second sliding block.

2. The in-line wood-structured glass curtain wall according to claim 1, wherein: the angle steel and the I-steel are provided with an air inlet hole and an air outlet hole, the openings of the air inlet hole and the air outlet hole face the same direction, the air inlet hole and the air outlet hole are mutually communicated, the opening part of the air inlet hole is provided with a flaring part, the air inlet hole is internally provided with a one-way valve for air supply to enter the angle steel or the I-steel in a one-way manner, and the air outlet hole is internally provided with a pressure limiting valve.

3. The in-line wood-structured glass curtain wall according to claim 2, wherein: the air inlet hole is communicated with the first chute or the second chute or the channels communicated between the first chute and the second chute, and the air outlet hole is also communicated with the channels communicated between the first chute or the second chute or the channels communicated between the first chute and the second chute.

4. The in-line wood-structured glass curtain wall according to claim 1, wherein: elastic pieces are fixed between the first sliding block and the inner wall of the first sliding groove and between the second sliding block and the inner wall of the second sliding groove.

5. The in-line wood-structured glass curtain wall according to claim 4, wherein: when the elastic piece is in a natural state, the distance between the two first sliding blocks is smaller than the thickness of the glass.

6. The in-line wood-structured glass curtain wall according to claim 1, wherein: the glass is provided with a notch for the first sliding block to be clamped in.