TW201402499A - High-permeability double-silver low-E coated glass - Google Patents

Abstract

The present invention relates to a high-permeability double-silver low-E coated glass including: a glass substrate; and a base dielectric combination layer, a first insulation layer, a first functional Ag layer, a second insulation layer, an intermediate dielectric combination layer, a third insulation layer, a second functional Ag layer, a fourth insulation layer and a top dielectric, which are sequentially deposited on the glass substrate. The base dielectric combination layer further includes a first base dielectric layer deposited on the glass substrate and a second base dielectric layer deposited on one side of the first base dielectric layer opposite to the glass substrate. The film layer according to the present invention has the advantages of high stability, excellent high-temperature resistance, color drift improvement before and after reinforcement, low radiation ratio, high mechanical performance, excellent oxidation resistance and high adhesion, thereby being worthy of application promotion.

Description

High-permeability double-silver low-emission coated glass

The invention relates to the field of glass deep processing, in particular to a high-permeability double-silver low-emission coated glass.

Low-E Glass is a kind of energy-saving product that sputters a multilayer dielectric film and a functional film on the surface of the glass to achieve high reflection of infrared light and high transmission of visible light. Low-emission coated glass is a new-generation coating that can transmit solar energy, visible light, and infrared mirrors like float glass (especially the high reflectivity of the far-infrared), reflecting the secondary radiant heat of the object. glass. Used in any climate, it can control sunlight, save energy, regulate heat and improve the environment. At the same time, no matter how much indoor and outdoor temperature difference, as long as the low-radiation glass is installed, the summer heat-proof energy can enter the room, and the winter heat-proof energy leaks, which has two-way energy-saving effect, so that indoor air conditioning costs can be maintained for a long time in winter and summer.

At present, the low-emission coated glass used in the market is mostly a common double-silver low-emission coating product, which has short oxidation resistance, poor wear resistance, and has no different processing characteristics; on the other hand, it produces double-silver low-emission coated glass. The cost of equipment is expensive and cannot be tolerated by small glass processing enterprises, thus limiting the use and promotion of double-silver low-emission coated glass.

In view of the defects of the prior art, the inventor of the present invention actively researched and improved by many years of design experience in the field, and thus has the high-permeability double-silver low-emission coated glass of the present invention.

In view of the deficiencies in the prior art, the first object of the present invention is to provide a temperable, low-radiation, high-permeability double-silver low-emission coated glass, which improves adhesion, enhances mechanical performance protection, and improves resistance. Processing performance.

In order to achieve the above object, a first object of the present invention is to provide a high-permeability double-silver low-emission coated glass comprising a glass substrate, and a base dielectric combination layer, a first barrier layer, a first functional Ag layer, a second barrier layer, an intermediate dielectric combination layer, a third barrier layer, a second functional Ag layer, and a fourth barrier layer, which are sequentially deposited on the glass substrate, And top layer dielectric.

A second object of the present invention is that the base electrolyte composition layer further includes a first base dielectric layer deposited on the glass substrate and a second base dielectric layer deposited on a side of the first base dielectric layer different from the glass substrate .

A third object of the present invention is that the first base dielectric layer is titanium oxide Ti _X O, and the value of X ranges from 0.1 to 0.9.

A fourth object of the present invention is that the oxide of titanium is Ti ₂ O ₃ or TiO ₂ .

A fifth object of the present invention is that the second base layer dielectric is Si ₃ N ₄ .

A sixth object of the present invention is that the intermediate dielectric layer combination layer further includes a first intermediate dielectric layer, a second intermediate dielectric layer, and a third intermediate dielectric layer sequentially deposited in this order.

According to a seventh aspect of the invention, the first intermediate dielectric layer and the third intermediate dielectric layer are Si3N4, and the second intermediate dielectric layer is ZnSnO ₃ .

According to an eighth aspect of the present invention, the first barrier layer and the third barrier layer are NiCr.

According to a ninth aspect of the present invention, the second barrier layer and the fourth barrier layer are AZO.

According to a tenth aspect of the present invention, the first functional Ag layer and the second functional Ag layer are silver-containing film layers.

The eleventh object of the present invention is that the film layer of the invention has the advantages of stable film layer, high temperature resistance, improved color shift after steel front steel, low emissivity, high mechanical property, good oxidation resistance and high adhesion. use.

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〔this invention〕

10‧‧‧ glass substrate

11‧‧‧Basic dielectric combination layer

111‧‧‧First base dielectric layer

112‧‧‧Second base dielectric layer

12‧‧‧First barrier

13‧‧‧First functional Ag layer

14‧‧‧Second barrier

15‧‧‧Intermediate dielectric combination layer

151‧‧‧First intermediate dielectric layer

152‧‧‧Second intermediate dielectric layer

153‧‧‧ Third intermediate dielectric layer

16‧‧‧ third barrier

17‧‧‧Second functional Ag layer

18‧‧‧ fourth barrier

19‧‧‧Top dielectric layer

1 is a schematic view showing the structure of a high-permeability double-silver low-emission coated glass according to the present invention.

In order to achieve the technical means, creative features, achievement of purpose and efficacy of the present invention It will be apparent that the invention is further described below in conjunction with the specific embodiments.

Please refer to FIG. 1 , which is a schematic view showing the structure of a high-permeability double-silver low-emission coated glass according to the present invention. The high-permeability double-silver low-emission coated glass comprises a glass substrate 10, a base dielectric combination layer 11 sequentially deposited on the glass substrate 10, a first barrier layer 12, a first functional Ag layer 13, and a second barrier layer 14, The intermediate dielectric combination layer 15, the third barrier layer 16, the second functional Ag layer 17, the fourth barrier layer 18, and the top dielectric layer 19.

The base dielectric layer 11 further includes a first base dielectric layer 111 deposited on the glass substrate 10 and a second base dielectric layer 112 deposited on a side of the first base dielectric layer 111 different from the glass substrate 10. . The first dielectric layer 111 is a base layer of titanium oxide Ti _X O, the X range is any value between 0.1 to 0.9, titanium oxide Ti ₂ O ₃ may be used or TiO _2. The second base dielectric layer 112 is Si3N4. The intermediate dielectric combining layer 15 further includes a first intermediate dielectric layer 151, a second intermediate dielectric layer 152, and a third intermediate dielectric layer 153 which are sequentially sequentially deposited. The first intermediate dielectric layer 151 and the third intermediate dielectric layer 153 are Si ₃ N ₄ , and the second intermediate dielectric layer 152 is ZnSnO ₃ . The first barrier layer 12 and the third barrier layer 16 are NiCr. The second barrier layer 14 and the fourth barrier layer 18 are AZO. The top dielectric layer 19 is Si ₃ N ₄ .

As a specific embodiment, without limitation, in the first base dielectric layer 111 of the base dielectric composite layer 11, the value of X is 0.5, that is, TiO ₂ is used, and the oxide of titanium is set as the antireflection. The film, the first base dielectric layer 111 has an increased light transmission property, which in turn can increase the light transmission performance of the visible light of the film system. Meanwhile, in this embodiment, by providing a double-layer low-emission film layer, specifically the first-function Ag layer 13 and the second-function Ag layer 17, the radiance of the infrared ray is greatly reduced. By disposing the second barrier layer 14 and the first barrier layer 12 on the first functional Ag layer 13 and the lower film surface, the oxidation of the first functional Ag layer 13 is effectively avoided; by passing on the second functional Ag layer 17, The provision of the fourth barrier layer 18 and the third barrier layer 16 effectively avoids oxidation of the second functional Ag layer 17. The second barrier layer 14, the first barrier layer 12, the fourth barrier layer 18, and the third barrier layer 16 enable the film system to be subjected to processing pretreatment or high temperature processing such as tempering and hot bending, and the appearance and performance thereof are not affected. The effect is to avoid the falling off of the film layer, better wear resistance and oxidation resistance, and can be stored for a long time. In addition, the provision of the third intermediate dielectric layer 153 and the first intermediate dielectric layer 151 on the lower and lower portions of the second intermediate dielectric layer 152 enhances the mechanical properties of the film system and improves the processability of the film system. The second intermediate dielectric layer 152 effectively performs toning in the film system and reduces color drift before and after tempering of the film.

Optionally, the first functional Ag layer 13 and the second functional Ag layer 17 are doped Ag layer or Ag element; as a preferred solution, the first functional Ag layer 13 and the second functional Ag layer 17 of the embodiment are both adopted. The Ni-doped Ag layer can improve the adhesion of the film by the incorporation of Ni, so that it has the characteristics of low radiation, heat insulation and heat preservation performance, and its high adhesion through the film layer avoids the film layer. Release film.

In this embodiment, a top dielectric layer 19 is disposed on the top layer of the film system to enhance the mechanical properties of the film system and facilitate product transportation and storage.

The invention has the advantages of stable film layer, high temperature resistance, improved color shift after steel front steel, low emissivity, high mechanical property, good oxidation resistance and high adhesion.

The basic principles and main features of the present invention and the advantages of the present invention are shown and described above. It should be understood by those skilled in the art that the present invention is not limited by the foregoing embodiments, and that the present invention is only described in the foregoing description and the description of the present invention, without departing from the spirit and scope of the invention. Various changes and modifications are intended to be included within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and their equivalents.

10‧‧‧ glass substrate

11‧‧‧Basic dielectric combination layer

111‧‧‧First base dielectric layer

112‧‧‧Second base dielectric layer

12‧‧‧First barrier

13‧‧‧First functional Ag layer

14‧‧‧Second barrier

15‧‧‧Intermediate dielectric combination layer

151‧‧‧First intermediate dielectric layer

152‧‧‧Second intermediate dielectric layer

153‧‧‧ Third intermediate dielectric layer

16‧‧‧ third barrier

17‧‧‧Second functional Ag layer

18‧‧‧ fourth barrier

19‧‧‧Top dielectric layer

Claims (10)

A high-permeability double-silver low-emission coated glass, characterized in that the high-permeability double-silver low-emission coated glass comprises: a glass substrate, and a base dielectric combination layer sequentially deposited on the glass substrate, a first barrier a layer, a first functional Ag layer, a second barrier layer, an intermediate dielectric combination layer, a third barrier layer, a second functional Ag layer, a fourth barrier layer, and a top dielectric. The high-permeability double-silver low-emission coated glass according to claim 1, wherein the base electrolyte composition layer further comprises a first base dielectric layer deposited on the glass substrate and deposited on the first base dielectric layer A second base dielectric layer that is different from the side of the glass substrate. The high-permeability double-silver low-emission coated glass according to claim 2, wherein the first base dielectric layer is titanium oxide Ti _X O, and the value of X ranges from 0.1 to 0.9. Value. The high-permeability double-silver low-emission coated glass according to claim 3, wherein the titanium oxide is Ti ₂ O ₃ or TiO ₂ . The high-permeability double-silver low-emission coated glass according to claim 2, wherein the second base layer dielectric is Si ₃ N ₄ . The high-permeability double-silver low-emission coated glass according to claim 1, wherein the intermediate dielectric layer combination layer further comprises a first intermediate dielectric layer, a second intermediate dielectric layer, and a third intermediate dielectric sequentially deposited in this order. Floor. The request type high permeability double silver low-emissivity coated glass according to the item 1, wherein the first intermediate dielectric layer and the third intermediate dielectric layer of Si ₃ N _4, the second intermediate dielectric layer ZnSnO _3. The high-permeability double-silver low-emission coated glass according to claim 1, wherein the first barrier layer and the third barrier layer are NiCr. The high-permeability double-silver low-emission coated glass according to claim 1, wherein the second barrier layer and the fourth barrier layer are AZO. The high-permeability double-silver low-emission coated glass according to claim 1, wherein the first functional Ag layer and the second functional Ag layer are silver-containing film layers.