CN213234833U - Light modulation type LOW-radiation off-line LOW-E safe and energy-saving hollow glass - Google Patents

Abstract

The utility model discloses a light modulation type LOW radiation off-line LOW-E safe and energy-conserving cavity glass belongs to cavity glass technical field, light modulation type LOW radiation off-line LOW-E safe and energy-conserving cavity glass includes the glass frame, glass frame lower extreme fixedly connected with L shape clamp splice, the centre gripping has the picture peg between the L clamp splice, the picture peg includes honeycomb sheet layer and fire prevention sheet layer, carry out the veneer between honeycomb sheet layer and the fire prevention sheet layer and be connected, fire prevention sheet layer surface spraying has fire protection coating. The utility model discloses an increase there is the honeycomb sheet layer, and the honeycomb sheet layer specifically adopts cellular structure, can further weaken with sound, has the fire prevention sheet layer through increasing, and the spraying has fire protection coating on the fire prevention sheet layer so has good high temperature resistant fire behavior, plays certain fire prevention effect, and the picture peg wholly can play the effect of mending the glass performance, conveniently inserts at any time and gets, and it is convenient to use, is fit for being extensively promoted and used.

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 technical field especially relates to a 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, beautiful appearance and applicability and can reduce the self weight of buildings. The high-efficiency sound-insulating and heat-insulating glass is prepared by bonding two (or three) pieces of glass with an aluminum alloy frame containing a drying agent by using a high-strength high-airtightness composite bonding agent. The hollow glass has various properties superior to those of common double-layer glass, so that the hollow glass is accepted by all countries in the world, and two or more pieces of glass are effectively supported and uniformly separated and are bonded and sealed at the periphery, so that a dry gas space is formed between glass layers. The main materials are glass, warm edge spacing strips, corner bolts, butyl rubber, polysulfide glue and drying agents.

Patent number CN203383683U discloses a light modulation type LOW radiation off-line LOW-E safe and energy-saving hollow glass, including white glass, sealing layer, off-line LOW-E glass and light modulation type liquid crystal film etc. its characterized in that: the utility model discloses a white glass, sealing layer and off-line LOW-E glass bond, sealing layer setting are in white glass and off-line LOW-E glass's border department all around, make and form a sealed chamber between off-line LOW-E glass and the white glass, the utility model discloses simple structure, reasonable in design has off-line LOW-E's LOW radiation, laminated glass's security, cavity glass's energy-conservation and adjustable light transmissivity, can extensively be applicable to various building curtain, door and window, roofing glass and daylighting canopy etc. can design the various style patterns that satisfy the customer selection simultaneously.

At present, the above patents have certain technical defects: 1. in the past, although the hollow glass has certain sound insulation capability, the glass cannot be completely isolated when the external noise is too high; 2. when the conventional glass meets fire, the glass can explode rapidly at high temperature, thereby generating danger. Therefore, the dimming type LOW-radiation off-line LOW-E safe and energy-saving hollow glass is provided.

SUMMERY OF THE UTILITY MODEL

The utility model provides a light modulation type LOW radiation off-line LOW-E safe energy-conserving cavity glass has the honeycomb sheet layer through increasing, the honeycomb sheet layer specifically adopts cellular structure, can further weaken with sound, there is the fire prevention sheet layer through increasing, the last spraying of fire prevention sheet layer has fire protection coating so have good high temperature resistant fire behavior, play certain fire prevention effect, the whole effect that can play the benefit of full glass performance of picture peg, the convenience is inserted at any time and is got, it is convenient to use, can effectively solve the problem in the background art.

The utility model provides a specific technical scheme as follows:

the utility model provides a pair of light modulation type LOW radiation off-line LOW-E safe energy-conserving cavity glass, including the glass frame, glass frame lower extreme fixedly connected with L shape clamp splice, the centre gripping has the picture peg between the L clamp splice, the picture peg includes honeycomb sheet layer and fire prevention sheet layer, it is connected to carry out the veneer between honeycomb sheet layer and the fire prevention sheet layer, fire prevention sheet layer surface spraying has fire protection coating, glass frame inside wall fixed mounting has glass body.

Optionally, the bottom of the glass frame is fixedly connected with an L-shaped supporting plate, and an inserting plate is erected at the upper end of the L-shaped supporting plate.

Optionally, the glass body comprises a glass layer A and a glass layer B, a sealing strip is bonded between the glass layer A and the glass layer B, the sealing strip, the glass layer A and the glass layer B jointly form a sealing space, and dry gas is filled in the sealing space.

Optionally, an intermediate film is bonded to the right side surface of the glass layer B, and a glass layer C is bonded to the right side surface of the intermediate film.

Optionally, an off-line LOW-E glass layer is compounded on the left side of the glass layer a, and a light-adjusting liquid crystal film is bonded to the left side surface of the off-line LOW-E glass layer.

The utility model has the advantages as follows:

1. the utility model discloses the practicality, convenient operation and excellent in use effect through with the vertical L shaped clamping block who inserts glass frame both sides of picture peg between, the picture peg bottom supports through L shape layer board and holds up, the picture peg comprises honeycomb sheet layer and fire prevention sheet layer jointly, has honeycomb sheet layer through increasing, honeycomb sheet layer specifically adopts cellular structure, can further weaken with sound, further improved glass's sound insulation performance.

2. The utility model discloses an increase there is the fire prevention sheet layer, the spraying has the fire prevention coating on the fire prevention sheet layer so has good high temperature resistant fire behavior, the fire prevention coating specifically adopts HX-012 high temperature resistant coating to make, HX-012 type high temperature resistant coating is the new material that is used for the thermal-insulated space technique of spacecraft heat preservation to derive, waterproof, fire prevention, it is anticorrosive, wear-resisting, multiple advantages such as insulation, the latest nanometer ceramic technology is used to coating, thermal-insulated efficiency can reach more than 90%, this product is by the high temperature binder, nanometer high temperature ceramic microballon, various high temperature filler, special additive constitutes, play certain fire prevention effect, the picture peg wholly can play the effect of mending full glass performance, conveniently insert at any time and get, it is convenient to use.

Drawings

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

fig. 2 is a schematic cross-sectional structural view of a dimming type LOW-emissivity off-line LOW-E safety energy-saving hollow glass according to an embodiment of the present invention;

FIG. 3 is a schematic view of a glass layer of a dimming type LOW-emissivity, LOW-E, safe and energy-saving hollow glass according to an embodiment of the present invention;

FIG. 4 is a schematic view of a fire-retardant coating of a dimming type LOW-emissivity, LOW-E, safe and energy-saving hollow glass according to an embodiment of the present invention;

in the figure: 1. a glass body; 101. a glass layer A; 102. a glass layer B; 103. a sealing strip; 104. an intermediate film; 105. a glass layer C; 106. an off-line LOW-E glass layer; 107. a light-modulating liquid crystal film; 2. an L-shaped pallet; 3. an L-shaped clamping block; 4. inserting plates; 401. a honeycomb panel layer; 402. a fire-proof board layer; 403. a fire-retardant coating; 5. and (4) a glass frame.

Detailed Description

The present application will now be described in further detail with reference to the drawings, it should be noted that the following detailed description is given for illustrative purposes only and is not to be construed as limiting the scope of the present application, as those skilled in the art will be able to make numerous insubstantial modifications and adaptations to the present application based on the above disclosure.

Example 1

The dimming type LOW-radiation off-line LOW-E safety energy-saving hollow glass of the embodiment of the present invention will be described in detail with reference to fig. 1 to 4.

As shown in fig. 1-4, a light modulation type LOW-radiation off-line LOW-E safe and energy-saving hollow glass comprises a glass frame 5, the lower end of the glass frame 5 is fixedly connected with an L-shaped clamping block 3, an inserting plate 4 is clamped between the L-shaped clamping blocks 3, the inserting plate 4 comprises a honeycomb plate layer 401 and a fireproof plate layer 402, the honeycomb plate layer 401 and the fireproof plate layer 402 are connected through gluing, a fireproof coating 403 is sprayed on the outer surface of the fireproof plate layer 402, and a glass body 1 is fixedly mounted on the inner side wall of the glass frame 5.

In the embodiment, as shown in fig. 1-4, the inserting plate 4 is vertically inserted between the L-shaped clamping blocks 3 on two sides of the glass frame 5, the bottom of the inserting plate 4 is supported by the L-shaped supporting plate 2, the inserting plate 4 is composed of a honeycomb plate layer 401 and a fireproof plate layer 402, the honeycomb plate layer 401 is added, the honeycomb plate layer 401 is of a honeycomb structure, sound can be further weakened, and the sound insulation performance of the glass is further improved; the fireproof plate layer 402 is added, the fireproof coating 403 is sprayed on the fireproof plate layer 402, so that the fireproof plate layer has good high-temperature-resistant fireproof performance, the fireproof coating 403 is specifically made of HX-012 high-temperature-resistant coating, the HX-012 high-temperature-resistant coating is a new material derived from a space technology for heat preservation and heat insulation of a spacecraft, and the fireproof plate has the advantages of water resistance, fire resistance, corrosion resistance, wear resistance, insulation and the like, the coating is applied to the latest nano ceramic technology, the heat insulation efficiency can reach over 90 percent, the product is composed of a high-temperature binder, nano high-temperature ceramic microbeads, various high-temperature fillers and special additives, a certain fireproof effect is achieved, the whole inserting plate 4 can play a role in complementing the performance of glass, and is convenient to insert and take at.

The bottom of the glass frame 5 is fixedly connected with an L-shaped supporting plate 2, and a plug board 4 is erected at the upper end of the L-shaped supporting plate 2.

In this embodiment, as shown in fig. 1, the bottom of the insert plate 4 is supported and lifted by the L-shaped support plate 2.

The glass body 1 comprises a glass layer A101 and a glass layer B102, a sealing strip 103 is connected between the glass layer A101 and the glass layer B102 in an adhesive mode, the sealing strip 103, the glass layer A101 and the glass layer B102 jointly form a sealing space, and dry gas is filled in the sealing space.

In this embodiment, as shown in fig. 3, the sealing tape 103, the glass layer a101 and the glass layer B102 together form a sealed space, thereby forming hollow glass with high energy saving performance.

Wherein, the right side surface of the glass layer B102 is bonded with an intermediate film 104, and the right side surface of the intermediate film 104 is bonded with a glass layer C105.

In this embodiment, as shown in fig. 3, a laminated glass formed by combining the glass layer B102 with the glass layer C105 and the interlayer film 104 has high safety.

An off-line LOW-E glass layer 106 is compounded on the left side of the glass layer a101, and a light-adjusting liquid crystal film 107 is bonded to the left side surface of the off-line LOW-E glass layer 106.

In this embodiment, as shown in fig. 3, the off-line LOW-E enables the whole glass to have LOW radiation performance, and the light-adjusting liquid crystal film 107 can adjust the transmittance of the whole glass.

It should be noted that, the utility model relates to a light modulation type LOW radiation off-line LOW-E safe and energy-saving hollow glass, during operation, the staff inserts picture peg 4 vertically between the L-shaped clamp splice 3 of glass frame 5 both sides, the bottom of picture peg 4 supports through L-shaped layer board 2 and holds up, picture peg 4 comprises honeycomb board layer 401 and fire prevention board layer 402 together, through increasing honeycomb board layer 401, honeycomb board layer 401 specifically adopts the honeycomb structure, can further weaken with sound, further improve glass's sound insulation performance; the fireproof plate layer 402 is added, the fireproof coating 403 is sprayed on the fireproof plate layer 402, so that the fireproof plate layer has good high-temperature-resistant fireproof performance, the fireproof coating 403 is specifically made of HX-012 high-temperature-resistant coating, the HX-012 high-temperature-resistant coating is a new material derived from a space technology for heat preservation and heat insulation of a spacecraft, and the fireproof plate has the advantages of water resistance, fire resistance, corrosion resistance, wear resistance, insulation and the like, the coating is applied to the latest nano ceramic technology, the heat insulation efficiency can reach over 90 percent, the product is composed of a high-temperature binder, nano high-temperature ceramic microspheres, various high-temperature fillers and special additives, a certain fireproof effect is achieved, the whole inserting plate 4 can play a role in complementing the performance of glass, and is convenient to insert and take at; the sealing strip 103, the glass layer A101 and the glass layer B102 jointly form a sealed space to form hollow glass with high energy-saving performance, the safety of laminated glass formed by the glass layer B102, the glass layer C105 and the intermediate film 104 is high, the off-line LOW-E enables the whole glass to have LOW radiation performance, and the light transmission of the whole glass can be adjusted by the light-adjusting liquid crystal film 107.

The utility model discloses a glass body 1; a glass layer A101; a glass layer B102; a sealing strip 103; an intermediate film 104; a glass layer C105; an off-line LOW-E glass layer 106; a light-modulating liquid crystal film 107; an L-shaped pallet 2; an L-shaped clamp block 3; an inserting plate 4; a honeycomb panel layer 401; a fire floor layer 402; a fire-resistant coating 403; the glass rim 5 components are all standard or known to those skilled in the art, and their structure and principle are known to those skilled in the art through technical manuals or through routine experimentation.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention.

Claims (5)

1. The utility model provides a light modulation type LOW radiation off-line LOW-E safe energy-conserving cavity glass, includes glass frame (5), its characterized in that, glass frame (5) lower extreme fixedly connected with L shape clamp splice (3), centre gripping has picture peg (4) between L shape clamp splice (3), picture peg (4) are including honeycomb sheet layer (401) and fire prevention sheet layer (402), carry out the veneer between honeycomb sheet layer (401) and fire prevention sheet layer (402) and be connected, fire prevention sheet layer (402) surface spraying has fire protection coating (403), glass frame (5) inside wall fixed mounting has glass body (1).

2. The dimming type LOW-radiation off-line LOW-E safe and energy-saving hollow glass as claimed in claim 1, wherein an L-shaped supporting plate (2) is fixedly connected to the bottom of the glass frame (5), and a plug board (4) is erected at the upper end of the L-shaped supporting plate (2).

3. The dimming type LOW-radiation off-line LOW-E safe and energy-saving hollow glass according to claim 1, wherein the glass body (1) comprises a glass layer A (101) and a glass layer B (102), a sealing strip (103) is bonded between the glass layer A (101) and the glass layer B (102), the sealing strip (103), the glass layer A (101) and the glass layer B (102) jointly form a sealed space, and dry gas is filled in the sealed space.

4. The dimming type LOW-radiation off-line LOW-E safe and energy-saving hollow glass as claimed in claim 3, wherein an intermediate film (104) is bonded and connected to the right surface of the glass layer B (102), and a glass layer C (105) is bonded and connected to the right surface of the intermediate film (104).

5. The dimming type LOW-emissivity off-line LOW-E safe and energy-saving hollow glass as claimed in claim 3, wherein an off-line LOW-E glass layer (106) is compounded on the left side of the glass layer A (101), and a dimming type liquid crystal film (107) is bonded and connected to the left side surface of the off-line LOW-E glass layer (106).

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