CN207596736U - A kind of sky blue low radiation coated glass - Google Patents
A kind of sky blue low radiation coated glass Download PDFInfo
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- CN207596736U CN207596736U CN201721657264.XU CN201721657264U CN207596736U CN 207596736 U CN207596736 U CN 207596736U CN 201721657264 U CN201721657264 U CN 201721657264U CN 207596736 U CN207596736 U CN 207596736U
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Abstract
The utility model discloses a kind of sky blue low radiation coated glass, including glass matrix, are included successively outward by glass matrix:Zinc-tin oxide antimony film layer, AZO film layers, metal nickel chromium triangle film layer, silver film, Titanium film layer, ceramic titanium film layer, tin oxide film layer, titanium oxide layer.The each thicknesses of layers of the utility model show that such thickness setting can either reach due effect, and can save film material, reduce cost by experiment repeatedly.
Description
Technical field
The utility model is related to coated glass technical field, in particular to a kind of low-emission coated glass of sky blue
Glass.
Background technology
Low radiation coated glass is rich other than having effect of the barrier ultraviolet reflection infrared ray so as to play heat-insulation and heat-preservation
The rich perfect Spanish furnish effect of appearance color is also the big reason that it is widely used.Sky blue cladding glass like
Put on a beautiful coat to building, be integrated with background sky to a kind of visual enjoyment as snug as a bug in a rug of people and
There is excellent heat preservation and insulation and favor by client.However the sky blue low radiation coated glass on building at present
Using substantially blank out, it is primarily due to interfere skyblue color also not using offline vacuum magnetic-control sputtering technique film
Suitable technique is developed, color can not be realized pure uniform.Therefore it provides one kind can realize pure sky blue and protect
The low radiation coated glass for having held low emissivity glass excellent thermal insulation heat insulation effect has very important significance.
Utility model content
The utility model is still immature in order to solve sky blue low radiation coated glass technique of the existing technology
Technical problem, providing a kind of can realize pure sky blue and maintain the low of low emissivity glass excellent thermal insulation heat insulation effect
Radiation film coating glass.In order to achieve the above objectives, technical solution is as follows used by the utility model:
A kind of sky blue low radiation coated glass, including glass matrix, it is characterised in that:By glass matrix outward successively
Including:
Zinc-tin oxide antimony film layer, AZO film layers, metal nickel chromium triangle film layer, silver film, Titanium film layer, ceramic titanium film layer, oxidation
Tin film layer, titanium oxide layer.
Further, the thickness of the zinc-tin oxide antimony film layer is 50-60nm.
Further, the thickness of the AZO film layers is 10-20nm.
Further, the thickness of the metal nickel chromium triangle film layer is 2-5nm.
Further, the thickness of the silver film is 10-15nm.
Further, the thickness of the Titanium film layer is 2-5nm.
Further, the thickness of the ceramic titanium film layer is 20-40nm.
Further, the thickness of the tin oxide film layer is 10-20nm.
Further, the thickness of the titanium oxide layer is 5-10nm.
The beneficial effects of the utility model are as follows:
Interference dominant wavelength easily can be transferred to the affiliated wave of blue light very by the zinc-tin oxide antimony film layer that the utility model uses
Section;AZO film layers functionally play with the same effect of zinc-tin oxide antimony film layer, but since it does not need to logical oxygen and carries out reaction to splash
The possibility of the dioxygen oxidation silver film in its underlying zinc-oxide tin antimony film layer can effectively be reduced by penetrating;The tin oxide film layer used for
Color adaptation layer;Played on ceramic titanium film layer function with the same effect of tin oxide film layer, but due to its do not need to logical oxygen into
Row reactive sputtering can effectively reduce the possibility of the dioxygen oxidation silver film in its upper strata tin oxide film layer;The oxidation titanium film of use
Its surface texture with smooth densification of layer improves the corrosion resistance of entire film layer as protective layer, increases mechanical strong
Degree improves the properties for follow of coated glass;
Each thicknesses of layers of the utility model show that such thickness setting, can either reach should by experiment repeatedly
Some effects, and film material can be saved, reduce cost.
Description of the drawings
Fig. 1 is the utility model glass structure schematic diagram;
In figure:1- glass matrix, 2- zinc-tin oxide antimony film layers, 3-AZO film layers, 4- metal nickel chromium triangle film layers, 5- silver films, 6-
Titanium film layer, 7- ceramics titanium film layers, 8- tin oxide film layers, 9- titanium oxide layers.
Specific embodiment
As shown in Figure 1, a kind of sky blue low radiation coated glass, is the white glass of float glass process of 6mm including glass matrix 1, by
Glass matrix 1 includes successively outward:Zinc-tin oxide antimony film layer 2, AZO film layers 3, metal nickel chromium triangle film layer 4, silver film 5, metal titanium membrane
Layer 6, ceramic titanium film layer 7, tin oxide film layer 8, titanium oxide layer 9.
Embodiment 1:
The thickness of each film deposition of the present embodiment is as follows:
2 thickness of zinc-tin oxide antimony film layer be 3 thickness of 50nm, AZO film layer be 10nm, 4 thickness of metal nickel chromium triangle film layer be 2nm,
5 thickness of silver film is 10nm, 6 thickness of Titanium film layer is 2nm, ceramic 7 thickness of titanium film layer is 20nm, 8 thickness of tin oxide film layer
It is 5nm for 10nm, 9 thickness of titanium oxide layer.
Prepare a kind of above-mentioned sky blue low radiation coated glass, using offline vacuum magnetic-control sputtering technology, including with
Lower step:
(1)Glass matrix 1 is cleaned, is dried;
(2)Forevacuum transition;
(3)The zinc-tin oxide antimony film layer 2 that thickness is 50nm is plated on glass matrix 1, when plating the film layer, using intermediate frequency power supply
Add rotating cathode sputtering sedimentation, power 75KW in argon gas 600SCCM oxygen 900SCCM atmosphere;
(4)The AZO film layers 3 that thickness is 10nm are plated in zinc-tin oxide antimony film layer 2, when plating the film layer, using intermediate frequency power supply
Add rotating cathode sputtering sedimentation, power 10KW in argon gas 1000SCCM atmosphere;
(5)The metal nickel chromium triangle film layer 4 that thickness is 2nm is plated in AZO film layers 3, when plating the film layer, using DC power supply in argon
Sputtering sedimentation in gas 300SCCM atmosphere, power 1.2KW;
(6)The silver film 5 that thickness is 10nm is plated in metal nickel chromium triangle film layer 4, when plating the film layer, using DC power supply plus is put down
Face cathode sputtering sedimentation, power 3.8KW in argon gas 500SCCM atmosphere;
(7)The Titanium film layer 6 that thickness is 2nm is plated on silver film 5, when plating the film layer, using DC power supply plus plane
Cathode sputtering sedimentation, power 1KW in argon gas 500SCCM atmosphere;
(8)The ceramic titanium film layer 7 that thickness is 20nm is plated in Titanium film layer 6, when plating the film layer, using intermediate frequency power supply plus
Rotating cathode sputtering sedimentation, power 45KW in argon gas 1000SCCM atmosphere;
(9)The tin oxide film layer 8 that thickness is 10nm is plated on ceramic titanium film layer 7, when plating the film layer, using intermediate frequency power supply plus
Rotating cathode sputtering sedimentation, power 20KW in argon gas 600SCCM oxygen 900SCCM atmosphere;
(10)The titanium oxide layer 9 that thickness is 5nm is plated in tin oxide film layer 8, when plating the film layer, using intermediate frequency power supply plus
Rotating cathode sputtering sedimentation, power 15KW in argon gas 600SCCM oxygen 900SCCM atmosphere;
(11)Forevacuum transition;
(12)Finished product detection.
This glass visible light transmittance is 60% after the completion of plated film, and outdoor face color value is a:-5 b:- 36, realize expection
Performance.
Embodiment 2:
The thickness of each film deposition of the present embodiment is as follows:
2 thickness of zinc-tin oxide antimony film layer be 3 thickness of 55nm, AZO film layer be 15nm, 4 thickness of metal nickel chromium triangle film layer be 3nm,
5 thickness of silver film is 13nm, 6 thickness of Titanium film layer is 4nm, ceramic 7 thickness of titanium film layer is 30nm, 8 thickness of tin oxide film layer
It is 7nm for 15nm, 9 thickness of titanium oxide layer.
Prepare a kind of above-mentioned sky blue low radiation coated glass, using offline vacuum magnetic-control sputtering technology, including with
Lower step:
(1)Glass matrix 1 is cleaned, is dried;
(2)Forevacuum transition;
(3)The zinc-tin oxide antimony film layer 2 that thickness is 55nm is plated on glass matrix 1, when plating the film layer, using intermediate frequency power supply
Add rotating cathode sputtering sedimentation, power 75KW in argon gas 600SCCM oxygen 900SCCM atmosphere;
(4)The AZO film layers 3 that thickness is 15nm are plated in zinc-tin oxide antimony film layer 2, when plating the film layer, using intermediate frequency power supply
Add rotating cathode sputtering sedimentation, power 10KW in argon gas 1000SCCM atmosphere;
(5)The metal nickel chromium triangle film layer 4 that thickness is 3nm is plated in AZO film layers 3, when plating the film layer, using DC power supply in argon
Sputtering sedimentation in gas 300SCCM atmosphere, power 1.2KW;
(6)The silver film 5 that thickness is 13nm is plated in metal nickel chromium triangle film layer 4, when plating the film layer, using DC power supply plus is put down
Face cathode sputtering sedimentation, power 3.8KW in argon gas 500SCCM atmosphere;
(7)The Titanium film layer 6 that thickness is 4nm is plated on silver film 5, when plating the film layer, using DC power supply plus plane
Cathode sputtering sedimentation, power 1KW in argon gas 500SCCM atmosphere;
(8)The ceramic titanium film layer 7 that thickness is 30nm is plated in Titanium film layer 6, when plating the film layer, using intermediate frequency power supply plus
Rotating cathode sputtering sedimentation, power 45KW in argon gas 1000SCCM atmosphere;
(9)The tin oxide film layer 8 that thickness is 15nm is plated on ceramic titanium film layer 7, when plating the film layer, using intermediate frequency power supply plus
Rotating cathode sputtering sedimentation, power 20KW in argon gas 600SCCM oxygen 900SCCM atmosphere;
(10)The titanium oxide layer 9 that thickness is 7nm is plated in tin oxide film layer 8, when plating the film layer, using intermediate frequency power supply plus
Rotating cathode sputtering sedimentation, power 15KW in argon gas 600SCCM oxygen 900SCCM atmosphere;
(11)Forevacuum transition;
(12)Finished product detection.
This glass visible light transmittance is 60% after the completion of plated film, and outdoor face color value is a:-5 b:- 36, realize expection
Performance.
Embodiment 3:
The thickness of each film deposition of the present embodiment is as follows:
2 thickness of zinc-tin oxide antimony film layer be 3 thickness of 60nm, AZO film layer be 20nm, 4 thickness of metal nickel chromium triangle film layer be 5nm,
5 thickness of silver film is 15nm, 6 thickness of Titanium film layer is 5nm, ceramic 7 thickness of titanium film layer is 40nm, 8 thickness of tin oxide film layer
It is 10nm for 20nm, 9 thickness of titanium oxide layer.
Prepare a kind of above-mentioned sky blue low radiation coated glass, using offline vacuum magnetic-control sputtering technology, including with
Lower step:
(1)Glass matrix 1 is cleaned, is dried;
(2)Forevacuum transition;
(3)The zinc-tin oxide antimony film layer 2 that thickness is 60nm is plated on glass matrix 1, when plating the film layer, using intermediate frequency power supply
Add rotating cathode sputtering sedimentation, power 75KW in argon gas 600SCCM oxygen 900SCCM atmosphere;
(4)The AZO film layers 3 that thickness is 20nm are plated in zinc-tin oxide antimony film layer 2, when plating the film layer, using intermediate frequency power supply
Add rotating cathode sputtering sedimentation, power 10KW in argon gas 1000SCCM atmosphere;
(5)The metal nickel chromium triangle film layer 4 that thickness is 5nm is plated in AZO film layers 3, when plating the film layer, using DC power supply in argon
Sputtering sedimentation in gas 300SCCM atmosphere, power 1.2KW;
(6)The silver film 5 that thickness is 15nm is plated in metal nickel chromium triangle film layer 4, when plating the film layer, using DC power supply plus is put down
Face cathode sputtering sedimentation, power 3.8KW in argon gas 500SCCM atmosphere;
(7)The Titanium film layer 6 that thickness is 5nm is plated on silver film 5, when plating the film layer, using DC power supply plus plane
Cathode sputtering sedimentation, power 1KW in argon gas 500SCCM atmosphere;
(8)The ceramic titanium film layer 7 that thickness is 40nm is plated in Titanium film layer 6, when plating the film layer, using intermediate frequency power supply plus
Rotating cathode sputtering sedimentation, power 45KW in argon gas 1000SCCM atmosphere;
(9)The tin oxide film layer 8 that thickness is 20nm is plated on ceramic titanium film layer 7, when plating the film layer, using intermediate frequency power supply plus
Rotating cathode sputtering sedimentation, power 20KW in argon gas 600SCCM oxygen 900SCCM atmosphere;
(10)The titanium oxide layer 9 that thickness is 10nm is plated in tin oxide film layer 8, when plating the film layer, using intermediate frequency power supply
Add rotating cathode sputtering sedimentation, power 15KW in argon gas 600SCCM oxygen 900SCCM atmosphere;
(11)Forevacuum transition;
(12)Finished product detection.
This glass visible light transmittance is 60% after the completion of plated film, and outdoor face color value is a:-5 b:- 36, realize expection
Performance.
Interference dominant wavelength easily can be transferred to the affiliated wave of blue light very by the zinc-tin oxide antimony film layer that the utility model uses
Section;AZO film layers functionally play with the same effect of zinc-tin oxide antimony film layer, but since it does not need to logical oxygen and carries out reaction to splash
The possibility of the dioxygen oxidation silver film in its underlying zinc-oxide tin antimony film layer can effectively be reduced by penetrating;The tin oxide film layer used for
Color adaptation layer;Played on ceramic titanium film layer function with the same effect of tin oxide film layer, but due to its do not need to logical oxygen into
Row reactive sputtering can effectively reduce the possibility of the dioxygen oxidation silver film in its upper strata tin oxide film layer;The oxidation titanium film of use
Its surface texture with smooth densification of layer improves the corrosion resistance of entire film layer as protective layer, increases mechanical strong
Degree improves the properties for follow of coated glass;
Each thicknesses of layers of the utility model show that such thickness setting, can either reach should by experiment repeatedly
Some effects, and film material can be saved, reduce cost.
The scope of protection of the utility model is not limited thereto, and any one skilled in the art is in this practicality
In the technical scope of novel exposure, the change or replacement that can readily occur in, should all cover the scope of protection of the utility model it
It is interior.Therefore, the scope of protection of the utility model should be subject to the protection domain that claim is defined..
Claims (9)
1. a kind of sky blue low radiation coated glass, including glass matrix, it is characterised in that:It is wrapped successively outward by glass matrix
It includes:Zinc-tin oxide antimony film layer, AZO film layers, metal nickel chromium triangle film layer, silver film, Titanium film layer, ceramic titanium film layer, tin oxide film
Layer, titanium oxide layer.
2. a kind of sky blue low radiation coated glass according to claim 1, it is characterised in that:The zinc-tin oxide antimony
The thickness of film layer is 50-60nm.
3. a kind of sky blue low radiation coated glass according to claim 1, it is characterised in that:The AZO film layers
Thickness is 10-20nm.
4. a kind of sky blue low radiation coated glass according to claim 1, it is characterised in that:The metal nickel chromium triangle film
The thickness of layer is 2-5nm.
5. a kind of sky blue low radiation coated glass according to claim 1, it is characterised in that:The thickness of the silver film
It spends for 10-15nm.
6. a kind of sky blue low radiation coated glass according to claim 1, it is characterised in that:The Titanium film layer
Thickness be 2-5nm.
7. a kind of sky blue low radiation coated glass according to claim 1, it is characterised in that:The ceramics titanium film layer
Thickness be 20-40nm.
8. a kind of sky blue low radiation coated glass according to claim 1, it is characterised in that:The tin oxide film layer
Thickness be 10-20nm.
9. a kind of sky blue low radiation coated glass according to claim 1, it is characterised in that:The titanium oxide layer
Thickness be 5-10nm.
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN110104962A (en) * | 2019-04-22 | 2019-08-09 | 太仓耀华玻璃有限公司 | A kind of low radiation coated glass and its preparation process |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN110104962A (en) * | 2019-04-22 | 2019-08-09 | 太仓耀华玻璃有限公司 | A kind of low radiation coated glass and its preparation process |
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