CN205498208U - Low -E glass that alternative messenger's visible light passed - Google Patents

Low -E glass that alternative messenger's visible light passed Download PDF

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Publication number
CN205498208U
CN205498208U CN201620237846.1U CN201620237846U CN205498208U CN 205498208 U CN205498208 U CN 205498208U CN 201620237846 U CN201620237846 U CN 201620237846U CN 205498208 U CN205498208 U CN 205498208U
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CN
China
Prior art keywords
film layer
glass
low
thickness
alternative
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Expired - Fee Related
Application number
CN201620237846.1U
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Chinese (zh)
Inventor
曹耀明
Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)
Dongguan Yinjian Glass Engineering Co Ltd
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Dongguan Yinjian Glass Engineering Co Ltd
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
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Priority to CN201620237846.1U priority Critical patent/CN205498208U/en
Application granted granted Critical
Publication of CN205498208U publication Critical patent/CN205498208U/en
Expired - Fee Related legal-status Critical Current
Anticipated expiration legal-status Critical

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Abstract

The utility model discloses a low that alternative messenger's visible light passed E glass, include from the last low who sets gradually extremely down the low energy -conserving glass layer of radiation of E, first anti -reflection rete, the 2nd glass basic unit, the anti -reflection rete of second, multi -functional composite membrane layer, the 3rd glass basic unit, multi -functional composite membrane layer includes that the infrared ray covers the rete and dyes the coating film layer. The beneficial effects of the utility model are that: set up multi -functional composite membrane layer, infrared ray that multi -functional composite membrane layer contains cover the rete and one alternative make that the visible light passes dye the coating film layer, should dye the requirement that can satisfy various colored glass in the coating film layer, make this product have the alternative function that makes the visible light pass, and the infrared ray covers the rete can make this product have the effect of radiation protection.

Description

A kind of alternative makes the Low-E glass that visible ray passes
Technical field
This utility model relates to glass art, is specifically related to the Low-E glass that a kind of alternative makes visible ray pass.
Background technology
Glass plays key player in the production and life in the present age, its application very extensive, such as windowpane, glass Decorative accessory, glassmaking ware, vehicle-mounted glass, glass curtain wall etc..Along with the continuous expansion of glass applications scope, market needs The amount of asking also constantly is increasing, and the exploitation about New Glasses Materials has become development trend in the industry.
Summary of the invention
The purpose of this utility model is the Low-E glass providing a kind of alternative to make visible ray pass.
The technical solution adopted in the utility model is: the Low-E glass that a kind of alternative makes visible ray pass, including from The Low-E Low emissivity energy-saving glass layer that sets gradually down, the first antireflective coating, the second glass-base, the second anti-reflection film Layer, multifunctional composite film layer, the 3rd glass-base;Described multifunctional composite film layer includes infrared ray shielding film layer and dyeing film Layer.
Further, described Low-E Low emissivity energy-saving glass layer includes setting gradually from top to bottom the first glass-base, Two Si3N4 film layers, the 3rd AZO film layer, the 4th Cu film layer, the 5th NiCr film layer, the 6th AZO film layer, the 7th Si3N4 Film layer, the 8th AZO film layer, the 9th Ag film layer, the tenth NiCr film layer, the 11st TiO2Film layer, the 12nd SiNxFilm Layer and the 13rd Sic film layer.
Further, the thickness of described 2nd Si3N4 film layer and the 7th Si3N4 film layer is 10-30nm;Described 3rd AZO The thickness of film layer, the 6th AZO film layer and the 8th AZO film layer is 10-20nm;The thickness of described 4th Cu film layer is 2-10nm;The thickness of described 5th NiCr film layer and the tenth NiCr film layer is 0.5-20nm;Described 9th Ag film layer Thickness is 2-15nm;The thickness of described 13rd Sic film layer is 25-50nm;Described 11st TiO2The thickness of film layer is 10-25nm;Described 12nd SiNxThe thickness of film layer is 15-25nm.
Further, the thickness of described first antireflective coating and the second antireflective coating is 10-25nm.
Further, the thickness of described multifunctional composite film layer is 0.2-3.5mm.
Further, described infrared ray shielding film layer is contained within a plurality of equally distributed infrared ray absorbing nanoparticle.
Further, described dyeing film layer contains one or more chromotropic dye.
The beneficial effects of the utility model are: arrange multifunctional composite film layer, and the infrared ray that multifunctional composite film layer comprises hides Covering film layer and dyeing film layer that an alternative makes visible ray pass, this dyeing film layer can meet the requirement of various coloured glass, This product is made to have the function that alternative makes visible ray pass;And infrared ray shielding film layer can make this product have radioprotective Effect.
Accompanying drawing explanation
Fig. 1 is structural representation of the present utility model.
Fig. 2 is the structural representation of Low-E Low emissivity energy-saving glass layer.
Fig. 3 is the structural representation of multifunctional composite film layer.
In figure: Low-E Low emissivity energy-saving glass layer the 1, first antireflective coating the 2, second glass-base the 3, second anti-reflection film Layer 4, multifunctional composite film layer the 5, the 3rd glass-base 6;Described multifunctional composite film layer 5 includes infrared ray shielding film layer 23 With dyeing film layer the 24, first glass-base the 10, the 2nd Si3N4 film layer the 11, the 3rd AZO film layer the 12, the 4th Cu film layer 13, the 5th NiCr film layer the 14, the 6th AZO film layer the 15, the 7th Si3N4 film layer the 16, the 8th AZO film layer the 17, the 9th Ag film layer the 18, the tenth NiCr film layer the 19, the 11st TiO2Film layer the 20, the 12nd SiNxFilm layer the 21 and the 13rd Sic film Layer 22.
Detailed description of the invention
With embodiment, the technical solution of the utility model is illustrated below in conjunction with the accompanying drawings.
With reference to shown in Fig. 1 and Fig. 3, a kind of alternative makes the Low-E glass that visible ray passes, including depending on from top to bottom Low-E Low emissivity energy-saving glass layer the 1, first antireflective coating the 2, second glass-base 3, second antireflective coating 4 of secondary setting, Multifunctional composite film layer the 5, the 3rd glass-base 6;Described multifunctional composite film layer 5 includes infrared ray shielding film layer 23 and dye Color film layer 24.The thickness of described first antireflective coating 2 and the second antireflective coating 4 is 10-25nm.Described multi-functional compound The thickness of film layer 5 is 0.2-3.5mm.Described infrared ray shielding film layer 23 is contained within a plurality of equally distributed infrared ray absorbing Nanoparticle.Described dyeing film layer 24 is containing one or more chromotropic dye, and this dyeing film layer 24 can meet various The requirement of coloured glass, makes this product have the function that alternative makes visible ray pass.Infrared ray shielding film layer 23 can make this Product has the effect of radioprotective.
With reference to shown in Fig. 2, described Low-E Low emissivity energy-saving glass layer includes the first glass base set gradually from top to bottom Layer the 10, the 2nd Si3N4 film layer the 11, the 3rd AZO film layer the 12, the 4th Cu film layer the 13, the 5th NiCr film layer 14, the Six AZO film layer the 15, the 7th Si3N4 film layer the 16, the 8th AZO film layer the 17, the 9th Ag film layer the 18, the tenth NiCr films Layer the 19, the 11st TiO2Film layer the 20, the 12nd SiNx film layer the 21 and the 13rd Sic film layer 22.Described 2nd Si3N4 film The thickness of layer 11 and the 7th Si3N4 film layer 16 is 10-30nm;Described 3rd AZO film 12 layers, the 6th AZO film layer 15 and the 8th the thickness of AZO film layer 17 be 10-20nm;The thickness of described 4th Cu film layer 13 is 2-10nm;Described The thickness of the 5th NiCr film layer 14 and the tenth NiCr film layer 19 is 0.5-20nm;The thickness of described 9th Ag film layer 18 For 2-15nm;The thickness of described 13rd Sic film layer 22 is 25-50nm;Described 11st TiO2The thickness of film layer 20 is 10-25nm;Described 12nd SiNxThe thickness of film layer 21 is 15-25nm.
Above-described embodiment is only that of the present utility model ultimate principle, principal character and advantage have been shown and described.The industry Skilled person will appreciate that, this utility model is not restricted to the described embodiments, described in above-described embodiment and description only Being that principle of the present utility model is described, on the premise of without departing from this utility model spirit and scope, this utility model also has Various changes and modifications, in the range of these changes and improvements both fall within claimed this utility model.

Claims (6)

1. the Low-E glass that an alternative makes visible ray pass, it is characterised in that: the Low-E Low emissivity energy-saving glass layer that includes setting gradually from top to bottom, the first antireflective coating, the second glass-base, the second antireflective coating, multifunctional composite film layer, the 3rd glass-base;Described multifunctional composite film layer includes infrared ray shielding film layer and dyeing film layer.
The Low-E glass that a kind of alternative the most according to claim 1 makes visible ray pass, it is characterised in that: the first glass-base that described Low-E Low emissivity energy-saving glass layer includes setting gradually from top to bottom, the 2nd Si3N4 film layer, the 3rd AZO film layer, the 4th Cu film layer, the 5th NiCr film layer, the 6th AZO film layer, the 7th Si3N4 film layer, the 8th AZO film layer, the 9th Ag film layer, the tenth NiCr film layer, the 11st TiO2Film layer, the 12nd SiNxFilm layer and the 13rd Sic film layer.
The Low-E glass that a kind of alternative the most according to claim 2 makes visible ray pass, it is characterised in that: the thickness of described 2nd Si3N4 film layer and the 7th Si3N4 film layer is 10-30nm;The thickness of described 3rd AZO film layer, the 6th AZO film layer and the 8th AZO film layer is 10-20nm;The thickness of described 4th Cu film layer is 2-10nm;The thickness of described 5th NiCr film layer and the tenth NiCr film layer is 0.5-20nm;The thickness of described 9th Ag film layer is 2-15nm;The thickness of described 13rd Sic film layer is 25-50nm;Described 11st TiO2The thickness of film layer is 10-25nm;Described 12nd SiNxThe thickness of film layer is 15-25nm.
The Low-E glass that a kind of alternative the most according to claim 1 makes visible ray pass, it is characterised in that: the thickness of described first antireflective coating and the second antireflective coating is 10-25nm.
The Low-E glass that a kind of alternative the most according to claim 1 makes visible ray pass, it is characterised in that: the thickness of described multifunctional composite film layer is 0.2-3.5mm.
The Low-E glass that a kind of alternative the most according to claim 1 makes visible ray pass, it is characterised in that: described infrared ray shielding film layer is contained within a plurality of equally distributed infrared ray absorbing nanoparticle.
CN201620237846.1U 2016-03-24 2016-03-24 Low -E glass that alternative messenger's visible light passed Expired - Fee Related CN205498208U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN201620237846.1U CN205498208U (en) 2016-03-24 2016-03-24 Low -E glass that alternative messenger's visible light passed

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN201620237846.1U CN205498208U (en) 2016-03-24 2016-03-24 Low -E glass that alternative messenger's visible light passed

Publications (1)

Publication Number Publication Date
CN205498208U true CN205498208U (en) 2016-08-24

Family

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Family Applications (1)

Application Number Title Priority Date Filing Date
CN201620237846.1U Expired - Fee Related CN205498208U (en) 2016-03-24 2016-03-24 Low -E glass that alternative messenger's visible light passed

Country Status (1)

Country Link
CN (1) CN205498208U (en)

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GR01 Patent grant
CF01 Termination of patent right due to non-payment of annual fee
CF01 Termination of patent right due to non-payment of annual fee

Granted publication date: 20160824