CN219773224U

CN219773224U - Sealing installation structure of three-glass two-cavity

Info

Publication number: CN219773224U
Application number: CN202321369613.3U
Authority: CN
Inventors: 任亮
Original assignee: Sichuan Shuanghua Technology Development Co ltd
Current assignee: Sichuan Shuanghua Technology Development Co ltd
Priority date: 2023-05-31
Filing date: 2023-05-31
Publication date: 2023-09-29
Anticipated expiration: 2033-05-31

Abstract

The utility model relates to the technical field of hollow glass, in particular to a sealing installation structure of a three-glass two-cavity structure, wherein a T-shaped strip is installed between first glass and second glass; wherein the T-bar comprises: a first branch part mounted perpendicular to the first glass and a second branch part mounted parallel to the first glass; a first colloid for first sealing is arranged between the first branch part and the first glass and between the first branch part and the second glass; a second gel for a second seal is disposed between the second leg and the first glass and between the second leg and the second glass. According to the utility model, the extrusion work of the second colloid and the first colloid can be completed simultaneously by using the T-shaped strip to extrude the first glass and the second glass once. The bonding and mounting efficiency of the first glass and the second glass is improved, and the sealing performance of the hollow cavity is effectively ensured.

Description

Sealing installation structure of three-glass two-cavity

Technical Field

The utility model relates to the technical field of hollow glass, in particular to a sealing installation structure of a three-glass two-cavity structure.

Background

Referring to fig. 1, a triple-glass double-cavity hollow glass is a structure commonly used in curtain wall installation, and includes: a first glass 1 in contact with an indoor environment, a third glass 3 in contact with an outdoor environment, and a second glass 2 installed therebetween; it is generally necessary to fill the hollow cavity 11 between the first glass 1 and the second glass 2 with a dry gas (such as argon) to achieve a better heat insulation effect, so that the sealing performance between the first glass 1 and the second glass 2 is required to be high.

In the existing hollow glass sealing, sealing strips 4 are arranged around any two adjacent glass sheets, a first sealant 43 is coated between the sealing strips 4 and the first glass 1 and between the sealing strips and the second glass 2, the first sealant 43 is compacted by a full-automatic tablet press, so that the first sealant 43 is firmly bonded with the surfaces of the glass, and the first sealing work is completed; and a second sealant 44 is coated on one side of the sealing strip 4 far away from the hollow cavity 11 between the glass, and the hollow cavity 11 is subjected to a second sealing operation.

In the existing installation mode, the second sealant 44 is not extruded by the first glass 1 and the second glass 2, secondary extrusion is needed to be performed on the second sealant 44 from the side manually, the installation efficiency is reduced, and the sealing effect of the second sealant 44 on the hollow cavity 11 is not effectively ensured.

Disclosure of Invention

In view of the above problems, the utility model provides a sealing installation structure of three-glass two-cavity, which aims to improve the installation efficiency and ensure the sealing performance of a hollow cavity.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a sealed mounting structure in two chambeies of three glass, including parallel arrangement: the first glass that contacts with indoor environment, the third glass that contacts with outdoor environment, install the second glass between the two and for it provides the curtain frame stile of mounting platform, install T shape strip between first glass and second glass, T shape strip includes: a first branch part mounted perpendicular to the first glass and a second branch part mounted parallel to the first glass; a first colloid for first sealing is arranged between the first branch part and the first glass and between the first branch part and the second glass; a second gel for a second seal is disposed between the second leg and the first glass and between the second leg and the second glass.

Further, the first leg is mounted proximate to the hollow cavity between the first glass and the second glass, and the second leg is mounted distal to the hollow cavity.

Further, the first glass has a smaller size than the second glass.

Further, a third branch part is further arranged at the end part of the second branch part far away from the hollow cavity, and extends for a fixed length along the direction far away from the second glass; a first cavity for storing a second colloid is formed among the first glass, the first branch part, the second branch part and the third branch part; a second chamber for storing a second gel is also formed between the second glass, the first leg and the second leg.

Further, the height of the third branch part is lower than that of the first glass, a first glue overflow opening with a fixed distance is reserved between the third branch part and the first glass, and a second glue overflow opening is formed between the third branch part and the second glass; one side of the first glue overflow opening is provided with a pressing line for shielding, and the second glue overflow opening is provided with a filler for shielding.

Further, the line ball is right triangle-shaped, and a right angle limit and the curtain frame of line ball are installed with the parallel installation of stile, another right angle limit and the parallel installation of first glass.

A light shielding mechanism is installed between the first glass and the second glass.

In the utility model, the coating work of the first colloid and the second colloid can be simultaneously completed on the first branch part and the second branch part by using the T-shaped strip. And the extrusion and bonding of the second colloid and the first colloid can be completed simultaneously by extruding the first glass and the second glass for one time. The bonding and mounting efficiency of the first glass and the second glass is improved, and the sealing performance of the hollow cavity is effectively ensured.

Drawings

Fig. 1 is a schematic sealing diagram of a three-glass two-cavity structure in the prior art.

Fig. 2 is an overall installation schematic diagram of the three-glass two-cavity structure provided in embodiment 1 of the present utility model.

Fig. 3 is an enlarged partial schematic view of the portion a in fig. 2.

Fig. 4 is an overall schematic diagram of installation of a curtain wall stile and a wire according to embodiment 2 of the present utility model.

Fig. 5 is a schematic structural diagram of a T-bar according to embodiment 1 of the present utility model.

1, first glass; 11. a hollow cavity; 2. a second glass; 3. a third glass; 4. a sealing strip; 41. a first colloid; 42. a second colloid; 43. a first sealant; 44. a second sealant; 5. the curtain wall is framed; 51. a first edge line; 52. mounting the impression; 6. a T-bar; 61. a first leg; 62. a second leg; 63. a third leg; 64. a first glue overflow port; 65. a second glue overflow port; 7. pressing line; 71. a first right-angle side; 8. a filler; 9. a shading mechanism.

Detailed Description

In order to better understand the above technical solutions, the following detailed description will refer to the accompanying drawings and specific embodiments.

Example 1

Referring to fig. 2 and 3, the present utility model provides a sealing installation structure of a three-glass two-chamber, comprising: a first glass 1 contacting an indoor environment, a third glass 3 contacting an outdoor environment, a second glass 2 installed therebetween, and a curtain wall stile 5 providing a mounting platform therefor.

In the present utility model, a T-bar 6 is installed between the first glass 1 and the second glass 2.

Wherein the T-bar 6 comprises: a first branch 61 installed perpendicular to the first glass 1 and a second branch 62 installed parallel to the first glass 1; a first glue 41 for a first seal is provided between the first leg 61 and the first glass 1 and between the first leg 61 and the second glass 2; a second glue 42 for a second seal is provided between the second leg 62 and the first glass 1 and between the second leg 62 and the second glass 2.

In the present utility model, the hollow cavity 11 between the first glass 1 and the second glass 2 is doubly sealed by the first colloid 41 and the second colloid 42, it is understood that both side end surfaces of the first leg 61 of the T-shaped strip 6 are used for coating the first colloid 41, and both side end surfaces of the second leg 62 are used for coating the second colloid 42.

By using the T-bar 6, the application work of the first colloid 41 and the second colloid 42 can be completed simultaneously on the first branch 61 and the second branch 62. And the extrusion and bonding of the second colloid 42 and the first colloid 41 can be completed simultaneously by performing one-time extrusion operation on the first glass 1 and the second glass 2. The bonding and mounting efficiency of the first glass 1 and the second glass 2 is improved, and the sealing performance of the hollow cavity 11 is effectively ensured.

Wherein, the first colloid 41 can be butyl rubber; the second colloid 42 may be a silicone structural adhesive.

It should be noted that a light shielding mechanism 9 (such as a shutter, a roller shutter, a honeycomb curtain and a pleated curtain) may be added between the first glass 1 and the second glass 2. In the utility model, the size of the first glass 1 is smaller than that of the second glass 2, a worker can detach the first glass 1 indoors, manually coat the first colloid 41 and the second colloid 42, and finally manually squeeze the first glass to finish adhesion installation, and the design can facilitate the later maintenance work of the shading mechanism 9 to be carried out indoors, transfer the maintenance work to the indoor, ensure the safety of the worker and reduce the operation cost.

It is to be readily understood that the above-described means of attachment and detachment, and the use of tablet presses and coaters, are well known to those skilled in the art and believed to be enabled by the teachings of the present utility model.

It will be appreciated that the first leg 61 is mounted adjacent the hollow cavity 11 between the first glass 1 and the second glass 2 and the second leg 62 is mounted remote from the hollow cavity 11.

Referring to fig. 5, a third branch 63 is further provided at an end of the second branch 62 remote from the hollow cavity 11, the third branch 63 extending a fixed length in a direction remote from the second glass 2; a first chamber for storing the second colloid 42 is formed among the first glass 1, the first branch portion 61, the second branch portion 62 and the third branch portion 63; a second chamber for storing the second gel 42 is also formed between the second glass 2, the first leg 61 and the second leg 62.

Of course, the third leg 63 is lower than the first glass 1, ensuring that the tablet press is able to completely cover the first glass 1 and the T-block.

A first glue overflow port 64 with a fixed distance is reserved between the third branch part 63 and the first glass 1, a second glue overflow port 65 is formed between the third branch part 63 and the second glass 2, and redundant second glue 42 in the extrusion process is discharged through the first glue overflow port 64 and the second glue overflow port 65 and then is manually removed and flattened, so that the appearance is maintained; when the second glue 42 is not fully filled in the first chamber and the second chamber, the second glue 42 is manually added to seal the first glue overflow opening 64 and the second glue overflow opening 65.

In the utility model, the first glue overflow opening 64 and the second glue overflow opening 65 are reserved, a certain installation gap is reserved for the first glass 1 and the second glass 2, and when slight vibration is encountered, the first glass 1 and the second glass 2 can complete a certain angle of offset movement, so that the first glass 1 or the second glass 2 is prevented from being damaged due to impact.

A pressing line 7 for shielding is arranged on one side of the first glue overflow opening 64, and a filler 8 for shielding is arranged on the second glue overflow opening 65; the filler 8 is made of soundproof cotton and has the functions of caulking, buffering and soundproof.

Further, the pressing line 7 is a right triangle, one right-angle side of the pressing line 7 is arranged in parallel with the curtain wall frame stile 5, and the other right-angle side is arranged in parallel with the first glass 1; in the utility model, the pressing line 7 is in a right triangle shape, so that the traditional square pressing line 7 is abandoned, and a certain indoor space is released.

Of course, on the basis of the utility model, a plurality of parallel glass can be additionally arranged to form a multi-cavity structure (such as four-glass three-cavity), so that the sound insulation effect is enhanced.

Example 2

Referring to fig. 4, in this embodiment, the length of the first right-angle edge 71 of the pressing line 7 near the curtain wall stile 5 is consistent with the length of the first edge line 51 of the curtain wall stile 5, and the first right-angle edge 71 of the pressing line 7 can completely shield the first edge line 51 of the curtain wall stile 5, so that the installation mark 52 exposed in a room when the length of the first right-angle edge 71 is shorter than the length of the first edge line 51 is eliminated, the installation simplicity of the utility model is improved, and the user experience is improved.

It will be apparent to those skilled in the art that while preferred embodiments of the present utility model have been described, additional variations and modifications may be made to these embodiments once the basic inventive concepts are known to those skilled in the art. It is therefore intended that the following claims be interpreted as including the preferred embodiments and all such alterations and modifications as fall within the scope of the utility model. It will be apparent to those skilled in the art that various modifications and variations can be made to the present utility model without departing from the spirit or scope of the utility model. Thus, it is intended that the present utility model also include such modifications and alterations insofar as they come within the scope of the appended claims or the equivalents thereof.

Claims

1. The utility model provides a sealed mounting structure in two chambeies of three glass, includes parallel arrangement: a first glass (1) contacting with indoor environment, a third glass (3) contacting with outdoor environment, a second glass (2) installed between the two and a curtain wall frame (5) providing a mounting platform for the first glass and the third glass, which is characterized in that,

-mounting a T-bar (6) between the first glass (1) and the second glass (2), the T-bar (6) comprising: a first branch portion (61) mounted perpendicularly to the first glass (1) and a second branch portion (62) mounted parallel to the first glass (1);

a first colloid (41) for a first seal is arranged between the first branch part (61) and the first glass (1) and between the first branch part (61) and the second glass (2);

a second glue (42) for a second seal is arranged between the second limb (62) and the first glass (1) and between the second limb (62) and the second glass (2).

2. The sealed mounting structure of two-chamber of three glass according to claim 1, characterized in that the first branch (61) is mounted close to the hollow chamber (11) between the first glass (1) and the second glass (2), and the second branch (62) is mounted distant from the hollow chamber (11).

3. The sealing mounting structure of a three-glass two-chamber according to claim 2, characterized in that the size of the first glass (1) is smaller than the size of the second glass (2).

4. A sealing mounting structure for a three-glass two-chamber according to claim 3, characterized in that a third branch part (63) is further provided at the end of the second branch part (62) far from the hollow chamber (11), the third branch part (63) extending for a fixed length in a direction far from the second glass (2); a first chamber for storing the second colloid (42) is formed among the first glass (1), the first branch part (61), the second branch part (62) and the third branch part (63);

a second chamber for storing the second gel (42) is also formed between the second glass (2), the first branch (61) and the second branch (62).

5. The sealing installation structure of the three-glass two-cavity according to claim 4, wherein the third branch part (63) is lower than the first glass (1), a first glue overflow opening (64) with a fixed distance is reserved between the third branch part (63) and the first glass (1), and a second glue overflow opening (65) is formed between the third branch part (63) and the second glass (2); one side of the first glue overflow opening (64) is provided with a pressing line (7) for shielding, and the second glue overflow opening (65) is provided with a filler (8) for shielding.

6. The sealing installation structure of the three-glass two-cavity according to claim 5, wherein the pressing line (7) is a right triangle, one right-angle side of the pressing line (7) is installed in parallel with the curtain wall framing (5), and the other right-angle side is installed in parallel with the first glass (1).

7. The sealed mounting structure of the three-glass two-chamber according to claim 6, characterized in that a light shielding mechanism (9) is mounted between the first glass (1) and the second glass (2).