CN205416573U - Curved infrared thermal resistance can be heated up and energy -conserving coated glass is kept off - Google Patents

Curved infrared thermal resistance can be heated up and energy -conserving coated glass is kept off Download PDF

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Publication number
CN205416573U
CN205416573U CN201521039648.6U CN201521039648U CN205416573U CN 205416573 U CN205416573 U CN 205416573U CN 201521039648 U CN201521039648 U CN 201521039648U CN 205416573 U CN205416573 U CN 205416573U
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layer
electrolyte
thickness
anti oxidation
energy
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陈大伟
陈宾
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XINYI GLASS (TIANJIN) CO Ltd
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XINYI GLASS (TIANJIN) CO Ltd
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Abstract

The utility model discloses a curved infrared thermal resistance can be heated up and energy -conserving coated glass is kept off, including glass substrate, metallic film and compound film, utilize off -line vacuum magnetron sputtering once to superpose and set up 20 layers of film on affiliated glass substrate surface, its thin layer includes dielectric interference layer, the low radiating layer of metal, alloy light absorbing zone, dielectric oxidation resisting layer, composite media protective layer. The utility model discloses possess excellent energy -conservation nature, strange land machinability, good decorative. This energy -conservation coated glass LOW -E coated glass the same with shading coefficient compares, and it is the ordinary silver -colored LOW -E's of list 18 that its solar energy sees through the ability, is ordinary two silver -colored LOW -E's 14. Because direct radiation's heat energy is extremely low, indoor personnel can effectively enlarge the activity space, and the hot comfort index of human perception also promotes greatly. Can make summer infrared ray radiant heat energy basically not see through, play good thermal insulation function, also can keep winter heating installation not run off, play fine heat preservation effect.

Description

A kind of can hot bending infra-red heat stop energy-conservation coated glass
Technical field
This utility model relate to a kind of can hot bending infra-red heat stop energy-conservation coated glass, particularly to off-line vacuum magnetic-control sputtering low radiation coated glass field, this glass uses vacuum magnetic-control sputtering method to produce, and emissivity is extremely low, and energy-saving effect promotes substantially, color is various.
Background technology
The eighties in last century starts, off-line vacuum magnetic-control sputtering is coated with low radiation coated glass technology and obtains swift and violent development, it is obviously improved so that the energy conservation characteristic of coated glass has had, raising building energy conservation required along with country, people are when selecting building doors and windows glass, in addition to considering its external aesthetical feature, increasingly focus on the glass energy saving to building, the problem projecting comfortable balance including heat control, refrigeration cost and internal sunlight.The most most importantly heat is solved through problem, and the overwhelming majority of solar heat concentrates on infrared band, the most how to control the glass stop to infrared ray wave band, make its diathermanous amount minimum, heat insulating ability is the highest, reduce refrigeration or heating cost is used for lifting section energy, accomplish that light thermal balance is the problem that current low radiation coated glass primarily solves simultaneously.
But the most common low radiation coated glass that can control heat energy has single silver LOW-E and double-silver LOW-E, its emissivity list silver LOW-E is between 0.06-0.15, double-silver LOW-E is between 0.03-0.06, under the situation of shading coefficient 0.4 requires, single silver LOW-E visible light transmissivity is about 50%, solar energy passes through about 24%, and double-silver LOW-E visible light transmissivity is about 68%, and solar energy passes through about 12%.Although double-silver LOW-E energy saving has had the progress of matter, but this can not meet the building energy conservation of higher standard and requirement, also has the space promoted further.Occur that the three a small amount of silver medal LOW-E product overwhelming majority all can not carry out tempering and hot bending after plated film on the market simultaneously, and color is single, limit the structure diversity of building glass development.Given this technical problem, inventor, according to being engaged in working experience and the technology of the industry for many years, is made that multiple trial and effort, finally develops new technology and the new glass kind that can solve the problem that this problem.The glass that this utility model provides is that a kind of radiance is extremely low, stop that infrared emanation is very competent, energy saving prominent, the adjustable and multifarious product that can carry out tempering, hot bending, color and light transmittance.
Utility model content
Technical problem to be solved in the utility model is to overcome the defect of existing coated glass technology, promotes coated glass integrated artistic level and properties of product, it is provided that a kind of the infra-red heat of hot bending can stop energy-conservation coated glass.The radiance of this glass, infra-red radiation heat energy transmitance are far below the most wide variety of all double-silver LOW-E glass, drastically increase the energy saving of glass.It addition, this glass can be carried out, tempering, hot bending, color and light transmittance be adjustable and multiformity, provides a favorable guarantee for the development of building glass industry energy-saving and product structure, outward appearance multiformity.
For achieving the above object, this utility model be the technical scheme is that
nullA kind of can hot bending infra-red heat stop energy-conservation coated glass,Including glass substrate,Described glass baseplate surface has been sequentially overlapped 20 layer films,20 layer films on described glass substrate be sequentially overlapped composition order be the 1st layer for glass substrate、2nd、3 layers is electrolyte interfering layer,4th layer is electrolyte anti oxidation layer,5th layer is metal Low emissivity layer,6th layer is electrolyte anti oxidation layer,7th、8 layers is electrolyte interfering layer,9th layer is electrolyte anti oxidation layer,10th layer is metal Low emissivity layer,11th layer is alloy light absorbing zone,12nd layer is electrolyte anti oxidation layer,13rd、14 layers is electrolyte interfering layer,15th layer is electrolyte anti oxidation layer,16th layer is metal Low emissivity layer,17th layer is alloy light absorbing zone,18th layer is electrolyte anti oxidation layer,19th、20、21 layers is compound dielectric protective layer;
It is Si that layer is penetrated in the interference of wherein said electrolyte3N4Layer, SnO2Composite bed more than layer, ZnSnOx layer, TiOx layer, ZnO layer or above each layer two-layer;
Described metal Low emissivity layer is any one layer in Ag layer, Cu layer, Al layer or AgCu alloy-layer;
Described alloy light absorbing zone is any one layer in NiCr layer, NiCrNx layer, NiCrOx layer, Nb layer, NbNx layer, NbOx layer;
Described electrolyte anti oxidation layer is AZO layer;
Described compound dielectric protective layer is Si3N4Layer, SnO2Layer, ZnO layer, TiOx layer, ZrO2In Ceng one layer or composite bed more than above each layer two-layer.
nullWherein said the 2nd、3 layers of electrolyte interfering layer superposition gross thickness are 15nm~40nm,The 4th layer of described electrolyte anti oxidation layer thickness is 1nm~10nm,The 5th layer of described metal Low emissivity layer thickness is 3nm~10nm,The 6th layer of described electrolyte anti oxidation layer thickness is 1nm~10nm,Described the 7th、8 layers of electrolyte interfering layer superposition gross thickness are 55nm~85nm,The 9th layer of described electrolyte anti oxidation layer thickness is 1nm~10nm,The 10th layer of described metal Low emissivity layer thickness is 7nm~17nm,Described 11th layer alloy light absorbing zone thickness is 0.5nm~10nm,The 12nd layer of described electrolyte anti oxidation layer thickness is 1nm~10nm,Described the 13rd、14 layers of electrolyte interfering layer superposition gross thickness are 60nm~90nm,The 15th layer of described electrolyte anti oxidation layer thickness is 1nm~10nm,The 16th layer of described metal Low emissivity layer thickness is 8nm~18nm,The 17th described lamination golden light absorber thickness is 0.5nm~10nm,The 18th layer of described electrolyte anti oxidation layer thickness is 1nm~10nm,Described the 19th、20、21 layers of compound dielectric protective layer superposition gross thickness are 20nm~50nm.
20 wherein said layer films are off-line vacuum magnetic control cathode sputtering deposition at glass baseplate surface stacked system.
Wherein said electrolyte anti oxidation layer is pottery AZO layer.
Compared with prior art, the utility model has the advantage of of technique scheme is used:
1, this utility model product material and technical maturity are reliable, workable, applied range.Simultaneously because the structure common double-silver LOW-E common compared with on market, three silver medal LOW-E are increasingly complex and unique, so product is replicated high with the difficulty of imitation by other people, it is ensured that the originality of product.
2, this utility model product surface radiance is less than 0.02, can stop the infra-red radiation heat energy of more than 95%, the solar infrared heat energy that it passes through is the 1/8 of common single silver LOW-E, is the 1/4 of common double-silver LOW-E, good energy saving performance, selects for more preferable for building and door and window Energy Conservation.
3, this utility model product can carry out tempering and the hot bending processing of rear operation, increases plasticity and the added value of product, beneficially scale, mass production and strange land processing, improves production efficiency, provide more for building and door and window structure variation and select.
4, this utility model product visible light transmissivity is adjustable in 50%~75%.Appearance color can be muted color, Lycoperdon polymorphum Vitt, blueness is adjustable, reduces the unicity of product on market, guides the development in pluralism of the energy-efficient product in market.
Accompanying drawing explanation
Fig. 1 is product structure schematic diagram of the present utility model;
What Fig. 2 and Fig. 3 was respectively this utility model embodiment 1 and embodiment 2 the infra-red heat of hot bending can stop the structural representation of energy-conservation coated glass.
Description of reference numerals: 1-glass substrate;2-electrolyte interfering layer;3-electrolyte interfering layer;4-electrolyte anti oxidation layer;5-is metal Low emissivity layer;6-electrolyte anti oxidation layer;7-electrolyte interfering layer;8-electrolyte interfering layer;9-electrolyte anti oxidation layer;10-metal Low emissivity layer;11-alloy light absorbing zone;12-electrolyte anti oxidation layer;13-electrolyte interfering layer;14-electrolyte interfering layer;15-electrolyte anti oxidation layer;16-metal Low emissivity layer;17-alloy light absorbing zone;18-electrolyte anti oxidation layer;19-compound dielectric protective layer;20-compound dielectric protective layer;21-compound dielectric protective layer.
Detailed description of the invention
In order to make the technical problems to be solved in the utility model, technical scheme and beneficial effect the clearest, further describe this utility model below in conjunction with specific embodiment, advantage of the present utility model and feature will be with describe and apparent.But embodiment is only exemplary, scope of the present utility model is not constituted any restriction.It will be understood by those skilled in the art that and the details of technical solutions of the utility model and form can be modified or replace under without departing from spirit and scope of the present utility model, but these amendments and replacement each fall within protection domain of the present utility model.
This utility model provides a kind of sound construction, compact, emissivity is less than 0.02, can stop the infrared radiation heat energy of more than 95%, simultaneously visible light transmittance rate and Color tunable, possessing can be with follow-up tempering and the high energy saving infrared shield glass of hot bending function.As shown in Figure 1, this infrared shield glass includes glass substrate 1, and utilize vacuum magnetic-control sputtering mode to be sequentially depositing the electrolyte interfering layer 2 of superposition on glass substrate 1 surface, electrolyte interfering layer 3, electrolyte anti oxidation layer 4, metal Low emissivity layer 5, electrolyte anti oxidation layer 6, electrolyte interfering layer 7, electrolyte interfering layer 8, electrolyte anti oxidation layer 9, metal Low emissivity layer 10, alloy light absorbing zone 11, electrolyte anti oxidation layer 12, electrolyte interfering layer 13, electrolyte interfering layer 14, electrolyte anti oxidation layer 15, metal Low emissivity layer 16, alloy light absorbing zone 17, electrolyte anti oxidation layer 18, compound dielectric protective layer 19, compound dielectric protective layer 20, compound dielectric protective layer 21.So this electrolyte interfering layer 2 contained by infrared shield glass, electrolyte interfering layer 3, electrolyte anti oxidation layer 4 can the bond strength of reinforced glass substrate 1 and metal Low emissivity layer 5 effectively.By metal Low emissivity layer 5, metal Low emissivity layer 10, the setting of metal Low emissivity layer 16 and regulation, strengthen the blocking capability of solar energy infra-red radiation, reduce the transmitance of infrared thermal radiation, play and reduce radiation and energy-conservation effect.By alloy light absorbing zone 11, alloy light absorbing zone 17 regulation is set, reduce the transmitance of visible ray, thus reduce light from glass substrate 1 directive metal Low emissivity layer 5, metal Low emissivity layer 10, the intensity of metal Low emissivity layer 16, play regulation light transmittance and the effect of light comfort level.The oxidative phenomena contacting generation of metal Low emissivity layer 5, metal Low emissivity layer 10, metal Low emissivity layer 16 and air can be effectively stoped, it is ensured that metal Low emissivity layer 5, metal Low emissivity layer 10, the Low emissivity energy saving of metal Low emissivity layer 16 by electrolyte anti oxidation layer 4, electrolyte anti oxidation layer 6, electrolyte anti oxidation layer 9, electrolyte anti oxidation layer 12, electrolyte anti oxidation layer 15, the setting of electrolyte anti oxidation layer 18 and regulation.Electrolyte interfering layer 7, electrolyte interfering layer 8, electrolyte interfering layer 13, electrolyte interfering layer 14 can occur refraction on its interface to effectively making light and interfere, make the visible ray under different wave length optionally pass through and reflection, determine the different colours that glass substrate outer surface presents.All film layers before it can be played protection and play heat-resisting, scratch resistance effect by compound dielectric protective layer 19, compound dielectric protective layer 20, compound dielectric protective layer 21 effectively; make this infrared shield glass film layers more resistant to processing; it is hardly damaged; compound dielectric protective layer 19, the color adaptation of compound dielectric protective layer 20 can also be passed through simultaneously, change product appearance effect.
Concrete, glass substrate 1 can be simple glass, or other types glass commonly used in the art, this glass substrate 1 surface relative with above-mentioned electrolyte interfering layer 2 infra-red heat of hot bending can stop the outer surface of energy-conservation coated glass as the present invention, and this surface that is to say the inspection surface of this glass.
Concrete, the 2nd, 3 layers of above-mentioned electrolyte interfering layer are Si3N4Layer, SnO2The composite bed that any and at least two in layer, ZnSnOx layer, TiOx layer, ZnO layer is formed, wherein the x in ZnSnOx molecular formula is 1~2, and the x in TiOx molecular formula is 2, and superposition gross thickness is 15nm~40nm.The 4th layer of above-mentioned electrolyte anti oxidation layer is pottery AZO layer, and thickness is 1nm~10nm.The 5th layer of above-mentioned metal Low emissivity layer is any one layer in Ag layer, Cu layer, Al layer or AgCu alloy-layer, and thickness is 3nm~10nm.The 6th layer of above-mentioned electrolyte anti oxidation layer is pottery AZO layer, and thickness is 1nm~10nm.The 7th, 8 layers of above-mentioned electrolyte interfering layer are Si3N4Layer, SnO2The composite bed that any and at least two in layer, ZnSnOx layer, TiOx layer, ZnO layer is formed, superposition gross thickness is 55nm~85nm.The 9th layer of above-mentioned electrolyte anti oxidation layer is pottery AZO layer, and thickness is 1nm~10nm.The 10th layer of above-mentioned metal Low emissivity layer is any one layer in Ag layer, Cu layer, Al layer or AgCu alloy-layer, and thickness is 7nm~17nm.Above-mentioned 11th layer alloy light absorbing zone is any one layer in NiCr layer, NiCrNx layer, NiCrOx layer, Nb layer, NbNx layer, NbOx layer, and the x in NiCrOx molecular formula is 1~1.33, and the x in NbOx molecular formula is 0.5~2.5, and thickness is 0.5nm~10nm.The 12nd layer of above-mentioned electrolyte anti oxidation layer is pottery AZO layer, and thickness is 1nm~10nm.The 13rd, 14 layers of above-mentioned electrolyte interfering layer are Si3N4Layer, SnO2The composite bed that any and at least two in layer, ZnSnOx layer, TiOx layer, ZnO layer is formed, superposition gross thickness is 60nm~90nm.The 15th layer of above-mentioned electrolyte anti oxidation layer is pottery AZO layer, and thickness is 1nm~10nm.The 16th layer of above-mentioned metal Low emissivity layer is any one layer in Ag layer, Cu layer, Al layer or AgCu alloy-layer, and thickness is 8nm~18nm.The 17th above-mentioned lamination golden light absorbed layer is any one layer in NiCr layer, NiCrNx layer, NiCrOx layer, Nb layer, NbNx layer, NbOx layer, and thickness is 0.5nm~10nm.The 18th layer of above-mentioned electrolyte anti oxidation layer is pottery AZO layer, and thickness is 1nm~10nm.The 19th, 20,21 layers of above-mentioned compound dielectric protective layer are Si3N4Layer, SnO2Layer, ZnO layer, TiOx layer, ZrO2The composite bed that any and at least two in Ceng is formed, superposition gross thickness is 20nm~50nm.
In sum, this utility model the infra-red heat of hot bending can stop that energy-conservation coated glass embodiment can be at least the preferred embodiment of following several structure, is certainly not limited only to following structure:
The first structure: as in figure 2 it is shown, this utility model embodiment can hot bending infra-red heat stop energy-conservation coated glass include that glass substrate 1 and a superposition are arranged on the Si on glass substrate 1 surface3N4Layer 2, ZnO layer 3, AZO layer 4, Ag layer 5, AZO layer 6, ZnSnOx layer 7, ZnO layer 8, AZO layer 9, Ag layer 10, NiCr layer 11, AZO layer 12, ZnSnOx layer 13, ZnO layer 14, AZO layer 15, Ag layer 16, NiCr layer 17, AZO layer 18, ZnO layer 19, Si3N4Layer 20, ZrO2Layer 21.
The second structure: as it is shown on figure 3, this utility model embodiment can hot bending infra-red heat stop energy-conservation coated glass include that glass substrate 1 and a superposition are arranged on the Si on glass substrate 1 surface3N4Layer 2, TiOx layer 3, AZO layer 4, Cu layer 5, AZO layer 6, Si3N4Layer 7, ZnSnOx layer 8, AZO layer 9, Ag layer 10, NiCr layer 11, AZO layer 12, Si3N4Layer 13, ZnSnOx layer 14, AZO layer 15, Ag layer 16, NiCr layer 17, AZO layer 18, ZnSnOx layer 19, Si3N4Layer 20, ZrO2Layer 21.
In conjunction with example, this utility model is further described.
Embodiment 1
The present embodiment can hot bending infra-red heat stop energy-conservation coated glass structure as in figure 2 it is shown, this can hot bending infra-red heat stop energy-conservation coated glass include glass substrate 1 and superposition Si in its surface3N4Layer 2, ZnO layer 3, superposition thickness is 30nm, AZO layer 4, thickness is 1nm, Ag layer 5, and thickness is 10nm, AZO layer 6, thickness is 1nm, ZnSnOx layer 7, ZnO layer 8, superposition thickness is 74m, AZO layer 9, and thickness is 1nm, Ag layer 10, thickness is 14nm, NiCr layer 11, thickness is 0.5nm, AZO layer 12, and thickness is 1nm, ZnSnOx layer 13, ZnO layer 14, superposition thickness is 74nm, AZO layer 15, thickness is 1nm, Ag layer 16, and thickness is 14nm, NiCr layer 17, thickness is 0.5nm, AZO layer 18, thickness is 1nm, ZnO layer 19, Si3N4Layer 20, ZrO2Layer 21 superposition thickness are 44nm.
Its preparation method is: utilize plate glass vacuum magnetron sputtering film plating machine, use the technological parameter that table 1 below is listed, use 20 negative electrodes to produce, prepare this utility model can hot bending infra-red heat stop energy-conservation coated glass, its concrete technology parameter see table:
Table 1
According to the technological parameter in above-mentioned table prepare can hot bending infra-red heat stop energy-conservation coated glass carry out optical performance test, its result is as follows:
The visible light transmissivity of common white glass real estate (inspection surface): 73%, through color: a*=-4.5, b*=4.5;
The visible reflectance of common white glass real estate (inspection surface): 6%, reflection colour: a*=-1.6, b*=-7;
The solar infrared heat energy transmitance of common white glass real estate (inspection surface): 4.5%;
ZrO2The emissivity value of aspect (measuring surface) is: 0.01.
Embodiment 2
The present embodiment can hot bending infra-red heat stop energy-conservation coated glass structure as it is shown on figure 3, this infrared shield glass includes glass substrate 1 and superposition Si in its surface3N4Layer 2, TiOx layer 3, superposition thickness is 32nm, AZO layer 4, and thickness is 1nm, Cu layer 5, and thickness is 12nm, AZO layer 6, and thickness is 1.5nm, Si3N4Layer 7, ZnSnOx layer 8, superposition thickness is 70m, AZO layer 9, and thickness is 1nm, Ag layer 10, and thickness is 15nm, NiCr layer 11, and thickness is 2nm, AZO layer 12, and thickness is 1nm, Si3N4Layer 13, ZnSnOx layer 14, superposition thickness is 75nm, AZO layer 15, and thickness is 1nm, Ag layer 16, and thickness is 16nm, NiCr layer 17, and thickness is 1.5nm, AZO layer 18, and thickness is 1nm, ZnSnOx layer 19, Si3N4Layer 20, ZrO2Layer 21 superposition thickness are 40nm.
Its preparation method is: utilize plate glass vacuum magnetron sputtering film plating machine, use the technological parameter that table 2 below is listed, use 20 negative electrodes to produce, prepare this utility model can hot bending infra-red heat stop energy-conservation coated glass, its concrete technology parameter see table:
Table 2
According to the technological parameter in above-mentioned table prepare can hot bending infra-red heat stop energy-conservation coated glass carry out optical performance test, its result is as follows:
The visible light transmissivity of common white glass real estate (inspection surface): 56%, through color: a*=-7.5, b*=-1;
The visible reflectance of common white glass real estate (inspection surface): 8%, reflection colour: a*=-3, b*=-5;
The solar infrared heat energy transmitance of common white glass real estate (inspection surface): 2.5%;
ZrO2The emissivity value of aspect (measuring surface) is: 0.01.
The foregoing is only preferred embodiments of the present utility model, not in order to limit this utility model, all any amendment, equivalent and improvement etc. made within spirit of the present utility model and principle, within should be included in protection domain of the present utility model.

Claims (4)

  1. null1. one kind can hot bending infra-red heat stop energy-conservation coated glass,Including glass substrate,It is characterized in that: described glass baseplate surface has been sequentially overlapped 20 layer films,20 layer films on described glass substrate be sequentially overlapped composition order be the 1st layer for glass substrate、2nd、3 layers is electrolyte interfering layer,4th layer is electrolyte anti oxidation layer,5th layer is metal Low emissivity layer,6th layer is electrolyte anti oxidation layer,7th、8 layers is electrolyte interfering layer,9th layer is electrolyte anti oxidation layer,10th layer is metal Low emissivity layer,11th layer is alloy light absorbing zone,12nd layer is electrolyte anti oxidation layer,13rd、14 layers is electrolyte interfering layer,15th layer is electrolyte anti oxidation layer,16th layer is metal Low emissivity layer,17th layer is alloy light absorbing zone,18th layer is electrolyte anti oxidation layer,19th、20、21 layers is compound dielectric protective layer;
    It is Si that layer is penetrated in the interference of wherein said electrolyte3N4Layer, SnO2Composite bed more than layer, ZnSnOx layer, TiOx layer, ZnO layer or above each layer two-layer;
    Described metal Low emissivity layer is any one layer in Ag layer, Cu layer, Al layer or AgCu alloy-layer;
    Described alloy light absorbing zone is any one layer in NiCr layer, NiCrNx layer, NiCrOx layer, Nb layer, NbNx layer, NbOx layer;
    Described electrolyte anti oxidation layer is AZO layer;
    Described compound dielectric protective layer is Si3N4Layer, SnO2Layer, ZnO layer, TiOx layer, ZrO2In Ceng one layer or composite bed more than above each layer two-layer.
  2. nullThe most according to claim 1 can hot bending infra-red heat stop energy-conservation coated glass,It is characterized in that: described the 2nd、3 layers of electrolyte interfering layer superposition gross thickness are 15nm~40nm,The 4th layer of described electrolyte anti oxidation layer thickness is 1nm~10nm,The 5th layer of described metal Low emissivity layer thickness is 3nm~10nm,The 6th layer of described electrolyte anti oxidation layer thickness is 1nm~10nm,Described the 7th、8 layers of electrolyte interfering layer superposition gross thickness are 55nm~85nm,The 9th layer of described electrolyte anti oxidation layer thickness is 1nm~10nm,The 10th layer of described metal Low emissivity layer thickness is 7nm~17nm,Described 11th layer alloy light absorbing zone thickness is 0.5nm~10nm,The 12nd layer of described electrolyte anti oxidation layer thickness is 1nm~10nm,Described the 13rd、14 layers of electrolyte interfering layer superposition gross thickness are 60nm~90nm,The 15th layer of described electrolyte anti oxidation layer thickness is 1nm~10nm,The 16th layer of described metal Low emissivity layer thickness is 8nm~18nm,The 17th described lamination golden light absorber thickness is 0.5nm~10nm,The 18th layer of described electrolyte anti oxidation layer thickness is 1nm~10nm,Described the 19th、20、21 layers of compound dielectric protective layer superposition gross thickness are 20nm~50nm.
  3. The most according to claim 1 can hot bending infra-red heat stop energy-conservation coated glass, it is characterised in that: 20 described layer films are off-line vacuum magnetic control cathode sputtering deposition at glass baseplate surface stacked system.
  4. The most according to claim 1 the infra-red heat of hot bending can stop energy-conservation coated glass, it is characterised in that: described electrolyte anti oxidation layer be ceramic AZO layer.
CN201521039648.6U 2015-12-14 2015-12-14 Curved infrared thermal resistance can be heated up and energy -conserving coated glass is kept off Expired - Fee Related CN205416573U (en)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN115611526A (en) * 2022-09-26 2023-01-17 吴江南玻华东工程玻璃有限公司 Low-emissivity glass capable of being thermally processed and preparation method thereof

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN115611526A (en) * 2022-09-26 2023-01-17 吴江南玻华东工程玻璃有限公司 Low-emissivity glass capable of being thermally processed and preparation method thereof

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