CN217783294U - Light modulation type LOW-radiation off-line LOW-E safe and energy-saving hollow glass - Google Patents

Abstract

The utility model provides a light modulation type LOW radiation off-line LOW-E safe energy-saving hollow glass, include: the first low-radiation glass is positioned on the inner side of the metal window frame, a sealing rubber plug is bonded at the edge of the first low-radiation glass, and the sealing rubber plug is fixed in the metal window frame; the solar panel is positioned on the upper surface of the metal window frame, and a converter is fixed at the lower end of the solar panel; the first dimming glass is positioned at the lower end of the first low-emissivity glass, and the surface of the first dimming glass is attached with an explosion-proof metal film. The utility model provides a current LOW-E cavity glass can not adjust luminance, leads to lacking the privacy in the cavity glass installation region, reduces LOW-E cavity glass performance, the energy-conserving cavity glass of LOW-E safety lack the problem of light modulation performance.

Description

Light modulation type LOW-radiation off-line LOW-E safe and energy-saving hollow glass

Technical Field

The utility model relates to a cavity glass field, concretely relates to light modulation type LOW radiation off-line LOW-E safe energy-conserving cavity glass.

Background

The hollow glass invented by Americans in 1865 is a novel building material which has good heat insulation, sound insulation, attractive appearance and applicability and can reduce the self weight of a building, wherein the LOW-radiation off-line LOW-E safe and energy-saving hollow glass is widely used, but the existing LOW-E hollow glass cannot be dimmed, so that the problems that privacy is lacked in a hollow glass installation area, the service performance of the LOW-E hollow glass is reduced, and the LOW-E safe and energy-saving hollow glass is lacked in dimming performance are caused.

SUMMERY OF THE UTILITY MODEL

In order to overcome the defects in the prior art, the light modulation type LOW-radiation off-line LOW-E safe and energy-saving hollow glass is provided so as to solve the problems that privacy is lacked in a hollow glass installation area, the use performance of the LOW-E hollow glass is reduced and the LOW-E safe and energy-saving hollow glass is lacked in light modulation performance because the existing LOW-E hollow glass cannot be subjected to light modulation.

In order to achieve the above object, there is provided a light modulation type LOW-radiation off-line LOW-E safety energy-saving hollow glass, comprising:

the first low-radiation glass is positioned on the inner side of the metal window frame, a sealing rubber plug is bonded at the edge of the first low-radiation glass, and the sealing rubber plug is fixed in the metal window frame;

the solar panel is positioned on the upper surface of the metal window frame, and a converter is fixed at the lower end of the solar panel;

the first dimming glass is positioned at the lower end of the first low-emissivity glass, and the surface of the first dimming glass is attached with an explosion-proof metal film.

Furthermore, a first low-emissivity glass and a second low-emissivity glass are fixed on the inner side of the metal window frame; and the second LOW-emissivity glass is positioned at the lower end of the first LOW-emissivity glass, and a LOW-E film is sprayed on the surface of the first LOW-emissivity glass.

Further, a hollow area is arranged between the first low-emissivity glass and the second low-emissivity glass, and a drying adsorption box is fixed at the edge of the hollow area.

Furthermore, the upper end and the lower end of the second low-emissivity glass are respectively bonded with the first dimming glass and the second dimming glass through adhesive layers, and the dimming controller is installed on the lower surface of the metal window frame.

Furthermore, the dimming controller is connected with a converter and an electrode connector through wires, and the electrode connector is arranged at the right ends of the first dimming glass and the second dimming glass.

Further, the first dimming glass and the second dimming glass are composed of a conductive glass layer and polymer liquid crystal; and the surfaces of the first dimming glass and the second dimming glass are both attached with explosion-proof metal films.

The utility model has the advantages that the dimming type LOW-radiation off-line LOW-E safe and energy-saving hollow glass of the utility model utilizes the first dimming glass and the second dimming glass to be bonded on the two sides of the second LOW-radiation glass, and the polymer liquid crystal inside the dimming glass is regularly arranged by the power supply transmitted by the electric wire, and the first dimming glass and the second dimming glass are in a transparent state, so that the light can conveniently pass through; when the LED dimming lamp is not powered on, the polymer liquid crystals in the dimming glass are irregularly arranged, so that the dimming glass is in an opaque state, light penetration is greatly blocked, the dimming function of the LOW-E safe energy-saving hollow glass is realized, the practicability of the LOW-E safe energy-saving hollow glass is improved, a power supply is provided for the dimming glass through the solar panel, the energy-saving and environment-friendly effects are achieved, and the problem that the LOW-E safe energy-saving hollow glass is lack of dimming performance is solved.

Drawings

Fig. 1 is a schematic view of a light-modulation type LOW-radiation off-line LOW-E safety energy-saving hollow glass in a top view structure according to an embodiment of the present invention.

Fig. 2 is a schematic view of a front view cross section of a light modulation type LOW-radiation off-line LOW-E safety energy-saving hollow glass provided by the embodiment of the present invention.

Fig. 3 is a schematic structural diagram of an embodiment of the present invention.

1. A metal window frame; 11. sealing the rubber plug; 12. drying the adsorption box; 2. a first low emissivity glass; 21. a LOW-E film; 22. a hollow region; 3. a solar panel; 31. a converter; 4. a second low emissivity glass; 5. a first light control glass; 51. a second light control glass; 52. an electric wire; 53. an electrode connector; 54. an explosion-proof metal film; 55. a conductive glass layer; 56. a polymer liquid crystal; 57. an adhesive layer; 6. a dimming controller.

Detailed Description

The following description of the embodiments of the present invention is provided for illustrative purposes, and other advantages and effects of the present invention will be readily apparent to those skilled in the art from the disclosure herein. The present invention can also be implemented or applied through other different specific embodiments, and various details in the present specification can be modified or changed based on different viewpoints and applications without departing from the spirit of the present invention.

Fig. 1, 2, 3.

Referring to fig. 1 to 3, the utility model provides a light modulation type LOW radiation off-line LOW-E safe and energy-saving hollow glass, which comprises: first low emissivity glass 2, solar panel 3 and first light control glass 5.

The first low-emissivity glass 2 is positioned on the inner side of the metal window frame 1, a sealing rubber plug 11 is bonded at the edge of the first low-emissivity glass 2, and the sealing rubber plug 11 is fixed inside the metal window frame 1.

And the solar panel 3 is positioned on the upper surface of the metal window frame 1, and the converter 31 is fixed at the lower end of the solar panel 3.

And the first dimming glass 5 is positioned at the lower end of the first low emissivity glass 2, and an explosion-proof metal film 54 is attached to the surface of the first dimming glass 5.

The existing LOW-E hollow glass cannot be dimmed, so that privacy is lacked in a hollow glass installation area, the service performance of the LOW-E hollow glass is reduced, and the problem that the LOW-E safe energy-saving hollow glass is lacked in dimming performance is solved. Therefore, the dimming type LOW-radiation off-line LOW-E safe and energy-saving hollow glass of the utility model is bonded on two sides of the second LOW-radiation glass by utilizing the first dimming glass and the second dimming glass, and the polymer liquid crystal inside the dimming glass is regularly arranged by transmitting power through the electric wire, and the first dimming glass and the second dimming glass are in a transparent state, so that light can conveniently pass through; when the LED dimming lamp is not powered on, the polymer liquid crystals in the dimming glass are irregularly arranged, so that the dimming glass is in an opaque state, light penetration is greatly blocked, the dimming function of the LOW-E safe energy-saving hollow glass is realized, the practicability of the LOW-E safe energy-saving hollow glass is improved, a power supply is provided for the dimming glass through the solar panel, the energy-saving and environment-friendly effects are achieved, and the problem that the LOW-E safe energy-saving hollow glass is lack of dimming performance is solved.

A first low emissivity glass 2 and a second low emissivity glass 4 are fixed on the inner side of the metal window frame 1; and the second LOW emissivity glass 4 is positioned at the lower end of the first LOW emissivity glass 2, and the surface of the first LOW emissivity glass 2 is sprayed with a LOW-E film 21.

The first low emissivity glass 2 and the second low emissivity glass 4 are secured to the metal window frame 1 using a high strength, high air impermeability composite adhesive. The LOW-E film 21 has an effect of attenuating radiation of light, which is convenient for reducing radiation of indoor light energy.

A hollow area 22 is arranged between the first low-emissivity glass 2 and the second low-emissivity glass 4, and a drying adsorption box 12 is fixed at the edge of the hollow area 22.

The inside packing of hollow region 22 has dry gas, and the box 12 is adsorbed to the drying owing to adsorb the steam that the edge produced, avoids steam to get into hollow region 22 in, influences the inside syllable-dividing effect of cavity glass. The first low emissivity glass 2 is located on the outdoor side and the second low emissivity glass 4 is fixed on the indoor side.

The upper end and the lower end of the second low emissivity glass 4 are respectively bonded with the first light control glass 5 and the second light control glass 51 through an adhesive layer 57, and the light control device 6 is mounted on the lower surface of the metal window frame 1.

The first light control glass 5 and the second light control glass 51 enable the second low emissivity glass 4 to have light control function from the inner side and the outer side, so that the light control effect of the light control glass is enhanced. The dimmer control 6 may be remotely controlled using an infrared remote control.

The dimmer controller 6 is connected to the converter 31 and the electrode connector 53 via the electric wire 52, and the electrode connector 53 is provided at the right end of the first and second light control glasses 5 and 51.

The converter 31 transmits the electric energy converted from the light energy to the dimming controller 6 through the electric wire, so that the dimming controller 6 controls and turns on/off the first dimming glass 5 and the second dimming glass 51, thereby playing the role of energy conservation and environmental protection and being convenient for providing energy-saving electric energy.

The first light control glass 5 and the second light control glass 51 are composed of a conductive glass layer 55 and polymer liquid crystals 56; and the explosion-proof metal film 54 is adhered to the surfaces of the first light control glass 5 and the second light control glass 51.

When the dimming glass is powered off, the polymer liquid crystals 56 are arranged irregularly, so that the dimming glass is in an opaque state, and light penetration is greatly blocked; on the contrary, the polymer liquid crystal 56 is in regular arrangement, and the dimming glass is in a transparent state, so that light can pass through the dimming glass conveniently, and the dimming effect is achieved. The explosion-proof metal film 54 has an explosion-proof function against high-temperature radiation and is used for protecting the light control glass.

The utility model discloses a light modulation type LOW radiation off-line LOW-E safe energy-conserving cavity glass can effectively solve the problem that LOW-E safe energy-conserving cavity glass lacks the light modulation performance, realizes LOW-E safe energy-conserving cavity glass light modulation function, improves LOW-E safe energy-conserving cavity glass practicality, is applicable to light modulation type LOW radiation off-line LOW-E safe energy-conserving cavity glass.

Claims (6)

1. The utility model provides a light modulation type LOW radiation off-line LOW-E safe and energy-saving insulating glass which characterized in that includes:

the first low-emissivity glass (2) is positioned on the inner side of the metal window frame (1), a sealing rubber plug (11) is bonded at the edge of the first low-emissivity glass (2), and the sealing rubber plug (11) is fixed in the metal window frame (1);

the solar panel (3) is positioned on the upper surface of the metal window frame (1), and a converter (31) is fixed at the lower end of the solar panel (3);

the first dimming glass (5) is positioned at the lower end of the first low-emissivity glass (2), and an explosion-proof metal film (54) is attached to the surface of the first dimming glass (5).

2. The dimming type LOW-radiation off-line LOW-E safe and energy-saving hollow glass as claimed in claim 1, characterized in that a first LOW-radiation glass (2) and a second LOW-radiation glass (4) are fixed on the inner side of the metal window frame (1); and the second LOW-emissivity glass (4) is positioned at the lower end of the first LOW-emissivity glass (2), and a LOW-E film (21) is sprayed on the surface of the first LOW-emissivity glass (2).

3. The dimming type LOW-radiation off-line LOW-E safe and energy-saving hollow glass as claimed in claim 2, wherein a hollow area (22) is arranged between the first LOW-radiation glass (2) and the second LOW-radiation glass (4), and a dry adsorption box (12) is fixed at the edge of the hollow area (22).

4. The dimming type LOW-radiation off-line LOW-E safe and energy-saving hollow glass as claimed in claim 2, wherein the upper end and the lower end of the second LOW-radiation glass (4) are respectively bonded with a first dimming glass (5) and a second dimming glass (51) through an adhesive layer (57), and a dimming controller (6) is installed on the lower surface of the metal window frame (1).

5. The dimming type LOW-radiation off-line LOW-E safety energy-saving hollow glass as claimed in claim 4, wherein the dimming controller (6) is connected with a converter (31) and an electrode connector (53) through an electric wire (52), and the electrode connector (53) is arranged at the right end of the first dimming glass (5) and the second dimming glass (51).

6. The dimming type LOW-radiation off-line LOW-E safe and energy-saving hollow glass according to claim 4, characterized in that the first dimming glass (5) and the second dimming glass (51) are composed of a conductive glass layer (55) and a polymer liquid crystal (56); and the surfaces of the first dimming glass (5) and the second dimming glass (51) are respectively adhered with an explosion-proof metal film (54).

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