CN114645663A

CN114645663A - Coated gradual-change hollow glass for building curtain wall and using method

Info

Publication number: CN114645663A
Application number: CN202210247935.4A
Authority: CN
Inventors: 赵光豪; 崔伏球; 邓昌明; 贺一波; 季守林
Original assignee: Jiangmen Yaopi Engineering Glass Co ltd
Current assignee: Jiangmen Yaopi Engineering Glass Co ltd
Priority date: 2022-03-14
Filing date: 2022-03-14
Publication date: 2022-06-21
Anticipated expiration: 2042-03-14
Also published as: CN114645663B

Abstract

The invention discloses coated gradually-changed hollow glass for a building curtain wall and a using method thereof, relates to the technical field of hollow glass, and aims to solve the problems that the internal stress of the hollow glass is increased when the existing temperature is higher, so that the edge part of the glass is deformed, and the gradual-changed color printing of the glass is easy to generate flaws; the gradual change mechanism comprises a glass body, a plurality of concave points, a heat insulation plate, an antifogging film layer, a gradual change mesh point layer, an ink layer and an explosion-proof film. The coated gradual-change hollow glass for the building curtain wall can effectively prevent fuzzy flaws of gradual-change mesh points during printing, and meanwhile, the over-decompression rubber ball is used for buffering, so that the hollow glass can be prevented from being deformed and broken due to over-high pressure, and the coated gradual-change hollow glass is convenient to use.

Description

Coated gradual-change hollow glass for building curtain wall and using method

Technical Field

The invention relates to the technical field of hollow glass, in particular to coated gradual-change hollow glass for a building curtain wall and a using method thereof.

Background

In order to ensure air tightness during installation of the hollow glass, the glass and the metal frame need to be sealed by adopting a sealant, and gas can be filled in the hollow glass after sealing, but in actual use, the glass can expand due to difference of regional temperatures between the glass and the frame, and the expansion coefficients of the glass and the frame are different, so that when temperature change is increased, the internal stress of the hollow glass is increased, so that the edge of the glass is deformed or cracked, and the glass can be subjected to gradient color printing during production.

Disclosure of Invention

The invention provides coated gradual-change hollow glass for a building curtain wall and a using method thereof, which solve the problems that the internal stress of the hollow glass is increased at higher temperature, so that the edge part of the glass is deformed, and the gradual-change color printing of the glass is easy to generate flaws.

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

the coated gradual-change hollow glass for the building curtain wall comprises a frame, wherein a gradual-change mechanism is arranged in the frame and used for reducing flaws of gradual change of the glass, and a pressure reducing mechanism is arranged in the frame and used for buffering the pressure in the hollow glass;

the gradual change mechanism comprises a glass body, a low-depression point, a heat insulation plate, an antifogging film layer, a gradual change mesh point layer, an ink layer and an explosion-proof film, wherein the low-depression point is positioned at the top end of the glass body, the heat insulation plate is positioned at the bottom end of the glass body, and the gradual change mesh point layer is positioned at one end, far away from the heat insulation plate, of the glass body.

Preferably, the antifogging film layer is located at the bottom end of the heat insulation plate, the ink layer is located at the top end of the gradient mesh point layer, and the explosion-proof film is located at the top end of the ink layer.

Preferably, one side of the gradual change mechanism, which is close to the frame, is provided with a first sealing gasket, one side of the gradual change mechanism, which is far away from the first sealing gasket, is provided with a second sealing gasket, and the second sealing gasket is positioned between the gradual change mechanism and the decompression mechanism.

Preferably, the decompression mechanism includes aluminium parting bead, connecting plate, decompression rubber ball, scale plate and third sealed pad, the aluminium parting bead is located two between the glass body.

Preferably, the connecting plate is located inside the glass body, the decompression rubber ball is located at the top end of the connecting plate, and the bottom end of the decompression rubber ball penetrates through the connecting plate and extends to the outside.

Preferably, the scale plate is located one side of decompression rubber ball, just decompression rubber ball evenly sets up along the length direction of connecting plate, the third is sealed to be located between connecting plate and the glass body.

The use method of the coated gradual-change hollow glass for the building tomb wall is characterized by comprising the following steps of:

s1, printing the gradual change dot layer on a reserved concave point of the glass body, and wiping redundant printed matters to prevent the gradual change dot layer from generating fuzzy flaws during printing;

s2, coating an ink layer on the gradual change dot layer, improving the shading effect through the ink layer, and plating an explosion-proof film on the outer part of the glass, so that the broken slag of the glass is not splashed when the glass is cracked, and the explosion-proof effect of the glass body can be improved;

s3 a layer of heat insulation plate and an anti-fog film layer are arranged at the bottom end of the glass body, deposition of water mist on the outer wall of the glass is reduced through the anti-fog film layer, and the visual field effect is improved.

When in use, the device further comprises:

the temperature becomes can make cavity glass's internal pressure grow when this product is using, thereby the inside gas of filling of cavity glass can produce and extrude the glass body outward, thereby inside at cavity glass sets up the decompression rubber ball, during the inside pressure grow of cavity glass, wherein the gas of filling can fill to inside the decompression rubber ball, make decompression rubber ball grow, thereby reduce the inside pressure of cavity glass, reduce the broken risk of glass body deformation, and decompression rubber ball position top is provided with the bleeder vent, can make the decompression rubber ball be in pressure balance's state.

The invention has the beneficial effects that:

1. through set up the low-down pit in glass body department, then set up gradual change site layer at the low-down pit, at gradual change site layer coating printing ink layer afterwards, through the double-deck setting on low-down pit and gradual change site layer, can effectually prevent that the gradual change site from appearing fuzzy flaw when the printing.

2. Through the inside at cavity glass setting decompression rubber ball, when cavity glass's internal pressure is great, cushion through decompression rubber ball, prevent that pressure is too big to lead to cavity glass to appear warping the breakage.

The device can effectually prevent that the gradual change site from appearing fuzzy flaw when the printing, and the decompression rubber ball that crosses cushions simultaneously can prevent that pressure is too big to lead to cavity glass to appear warping broken, facilitates the use.

3. The use method of the product structure is practical and effective, and the functionality and effectiveness of the product are improved.

Drawings

FIG. 1 is a schematic structural diagram of the present invention.

FIG. 2 is a schematic view of the split structure of the present invention.

FIG. 3 is a schematic view of the internal structure of the insulating glass of the present invention.

FIG. 4 is a schematic view of the glass structure of the present invention.

Fig. 5 is an enlarged schematic view of the structure at a in fig. 3 according to the present invention.

Reference numbers in the figures: 1. a frame; 2. a gradation mechanism; 201. a glass body; 202. concave points; 203. a heat insulation plate; 204. an anti-fog film layer; 205. a graded dot layer; 206. an ink layer; 207. an explosion-proof membrane; 3. a first gasket; 4. a second gasket; 5. a pressure reducing mechanism; 501. an aluminum division bar; 502. a connecting plate; 503. a pressure reducing rubber ball; 504. a scale plate; 505. and a third gasket.

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.

Referring to fig. 1 to 5, a gradually-changed hollow glass for coating a film on a building curtain wall includes a frame 1, a gradually-changing mechanism 2 is disposed inside the frame 1, the gradually-changing mechanism 2 is used for reducing flaws of gradual change of glass, a pressure-reducing mechanism 5 is disposed inside the frame 1, and the pressure-reducing mechanism 5 is used for buffering pressure inside the hollow glass;

the gradual change mechanism 2 comprises a glass body 201, a lower concave point 202, a heat insulation board 203, an antifogging film layer 204, a gradual change dot layer 205, an ink layer 206 and an explosion-proof film 207, wherein the lower concave point 202 is positioned at the top end of the glass body 201, the heat insulation board 203 is positioned at the bottom end of the glass body 201, and the gradual change dot layer 205 is positioned at one end of the glass body 201 far away from the heat insulation board 203.

As shown in fig. 2 and 4, the antifogging film layer 204 is located at the bottom end of the heat insulation board 203, the ink layer 206 is located at the top end of the gradient mesh point layer 205, the explosion-proof film 207 is located at the top end of the ink layer 206, one side of the gradient mechanism 2 close to the frame 1 is provided with the first sealing gasket 3, one side of the gradient mechanism 2 away from the first sealing gasket 3 is provided with the second sealing gasket 4, the second sealing gasket 4 is located between the gradient mechanism 2 and the pressure reducing mechanism 5, and fuzzy defects can be effectively reduced when the gradient mesh point is printed through the lower concave point 202 and the gradient mesh point layer 205.

As shown in fig. 2, 3 and 5, the pressure reducing mechanism 5 includes an aluminum division bar 501, a connecting plate 502, a pressure reducing rubber ball 503, a scale plate 504 and a third sealing pad 505, the aluminum division bar 501 is located between two glass bodies 201, the connecting plate 502 is located inside the glass bodies 201, the pressure reducing rubber ball 503 is located at the top end of the connecting plate 502, the bottom end of the pressure reducing rubber ball 503 extends to the outside through the connecting plate 502, the scale plate 504 is located on one side of the pressure reducing rubber ball 503, the pressure reducing rubber ball 503 is uniformly arranged along the length direction of the connecting plate 502, the third sealing pad 505 is located between the connecting plate 502 and the glass bodies 201, when the hollow glass is filled with gas, the expansion dimension of the pressure reducing rubber ball 503 is measured by the scale plate 504, and the deformation caused by excessive gas filling is prevented when the hollow glass is used.

The working principle is as follows: this structural design principle and result of use:

a use method of the coated gradual-change hollow glass for the building tomb wall comprises the following steps:

s1, firstly, printing the gradual change dot layer 205 on the reserved concave dots 202 of the glass body 201, and then wiping the redundant printed matters to prevent the gradual change dot layer 205 from generating fuzzy flaws during printing;

s2, an ink layer 206 is coated on the gradual change dot layer 205, the shading effect is improved through the ink layer 206, and then an explosion-proof film 207 is plated on the outer portion of the glass, so that broken slag of the glass is prevented from splashing when the glass is cracked, and the explosion-proof effect of the glass body 201 can be improved;

s3, arranging a layer of heat insulation board 203 and an anti-fog film layer 204 at the bottom end of the glass body 201, and reducing the deposition of water fog on the outer wall of the glass through the anti-fog film layer 204 to improve the visual field effect.

When in use, the device further comprises:

when this product temperature became the internal pressure grow that can cavity glass when using, thereby the inside gas of filling of cavity glass can produce and extrude glass body 201 outward, thereby inside at cavity glass sets up decompression rubber ball 503, when the inside pressure grow of cavity glass, wherein the gas of filling can fill to inside decompression rubber ball 503, make decompression rubber ball 503 grow, thereby reduce the inside pressure of cavity glass, reduce the broken risk of glass body 201 deformation, and decompression rubber ball 503 position top is provided with the bleeder vent, can make decompression rubber ball 503 be in pressure balance's state.

The use method of the product structure is practical and effective, and the functionality and effectiveness of the product are improved.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. The coated gradual-change hollow glass for the building curtain wall comprises a frame (1) and is characterized in that a gradual-change mechanism (2) is arranged inside the frame (1), the gradual-change mechanism (2) is used for reducing the gradual change flaws of the glass, a pressure reducing mechanism (5) is arranged inside the frame (1), and the pressure reducing mechanism (5) is used for performing pressure buffering inside the hollow glass;

the gradual change mechanism (2) comprises a glass body (201), a low-density point (202), a heat insulation board (203), an antifogging film layer (204), a gradual change mesh point layer (205), an ink layer (206) and an explosion-proof film (207), wherein the low-density point (202) is positioned at the top end of the glass body (201), the heat insulation board (203) is positioned at the bottom end of the glass body (201), and the gradual change mesh point layer (205) is positioned at one end, far away from the heat insulation board (203), of the glass body (201).

2. The coated gradient hollow glass for the building curtain wall as claimed in claim 1, wherein the antifogging film layer (204) is located at the bottom end of the heat insulation board (203), the ink layer (206) is located at the top end of the gradient dot layer (205), and the explosion-proof film (207) is located at the top end of the ink layer (206).

3. The coated gradient hollow glass for the building curtain wall as claimed in claim 1, wherein a first sealing gasket (3) is arranged on one side of the gradient mechanism (2) close to the frame (1), a second sealing gasket (4) is arranged on one side of the gradient mechanism (2) far away from the first sealing gasket (3), and the second sealing gasket (4) is positioned between the gradient mechanism (2) and the pressure reducing mechanism (5).

4. The coated gradient hollow glass for the building curtain wall as claimed in claim 1, wherein the pressure reducing mechanism (5) comprises an aluminum spacing strip (501), a connecting plate (502), a pressure reducing rubber ball (503), a scale plate (504) and a third sealing gasket (505), and the aluminum spacing strip (501) is located between the two glass bodies (201).

5. The coated gradient hollow glass for the building curtain wall as claimed in claim 4, wherein the connecting plate (502) is located inside the glass body (201), the pressure-reducing rubber ball (503) is located at the top end of the connecting plate (502), and the bottom end of the pressure-reducing rubber ball (503) extends to the outside through the connecting plate (502).

6. The coated gradient hollow glass for the building curtain wall as claimed in claim 4, wherein the scale plate (504) is located on one side of the decompression rubber ball (503), the decompression rubber ball (503) is uniformly arranged along the length direction of the connecting plate (502), and the third sealing gasket (505) is located between the connecting plate (502) and the glass body (201).

7. The use method of the coated gradual-change hollow glass for the building tomb wall as claimed in any one of claims 1 to 6 is characterized by comprising the following steps:

8. The method for using the coated gradual-change hollow glass for the building tomb wall as claimed in claim 7, wherein the method further comprises the following steps: