TWM483442U - Structure of view mirror - Google Patents

Description

Mirror structure

This creation is related to the sight glass, especially the use of oxide layer, reflective layer, anti-fog layer, conductive layer, so that this creation not only has long-lasting anti-fog effect, but also has impedance glare, blue light effect, protective electromagnetic wave, best Anti-fouling, anti-static and other effects form a multi-functional mirror structure.

As shown in Figures 1 to 2, the general sight glass (1) can bring a clear view when worn on the user, but it still has inconveniences. For example, when drinking hot drinks or eating hot food, the fog will make it visible. The lens body (2) of the mirror (1) is filled with misty water to blind the field of view, and it is impossible to continue to drink and eat.

In particular, when riding a mask on a motorcycle, the exhaled gas will cause the lens body (2) of the mirror (1) to be filled with mist to blind the field of view, and cause dangerous collisions and accidents during the running of the locomotive.

Therefore, an acquaintance person sprays a layer of anti-fogging agent (3), water repellent or soapy water in front of the lens body (2), and attempts to form an anti-fog cover body in front of the lens body (2) by using an anti-fogging agent (3). Prevent hot air from adhering to the surface of the lens body (2).

I don't know, whether it is spraying an anti-fogging agent (3), water repellent or soapy water, it will only remain for a short period of time. After contact with the external environment, it will gradually disappear and lose the anti-fog effect.

However, how to have an anti-fog effect at the same time, and can maintain a long time, and has other functions, is the key to breakthrough for this creation.

The main purpose of this creation is to make this creation not only have long-lasting anti-fog effect, but also have the functions of impedance glare, blue light effect, protection electromagnetic wave, best anti-fouling, anti-static and so on.

In order to achieve the goal, the present invention comprises: a lens body, a first oxide layer and a second oxide layer respectively disposed on the inner and outer sides of the lens, and the first oxide layer may be samarium dioxide (SIO ₂ ), Zirconium dioxide (ZRO ₂ ) and cerium oxide (SIO ₂ ) sequentially form a first film layer, a second film layer, and a third film layer, and the second oxide layer may be zirconium dioxide (ZRO _{2 )} ), cerium oxide (SIO ₂ ), sequentially forming a fourth film layer, a fifth film layer, adding a light reflecting layer outside the second oxide layer, and finally, adding an anti-fog layer to the outermost layer of the light reflecting layer.

(1) ‧‧ ‧Sight Mirror

(2) ‧ ‧ lens body

(3) ‧ ‧ anti-fogging agent

(10)‧‧‧ lens body

(11)‧‧‧First oxide layer

(111)‧‧‧First film

(112)‧‧‧Second film

(113) ‧‧‧ third film

(12)‧‧‧Second oxide layer

(121) ‧‧‧Fourth film

(122)‧‧‧ Fifth film

(13) ‧‧‧ Conductive film

(14) ‧‧‧reflective layer

(15) ‧ ‧ anti-fog layer

(16) ‧‧‧Interfacial active layer

Figure 1 is a schematic view of conventional glasses.

Figure 2 is a schematic cross-sectional view of a conventional lens body.

Figure 3 is a partial cross-sectional view of the first and second oxide layers of the present invention.

Figure 4 is an enlarged schematic view of a portion of the first oxide layer of the present invention.

Figure 5 is a schematic cross-sectional view showing a portion of the first, second oxide layer and the conductive layer.

Figure 6 is an enlarged schematic view of a portion of the first, second oxide layer and the conductive layer and the light-reflecting layer of the present invention.

Figure 7 is an enlarged schematic view of a portion of each layer of the creation.

Figure 8 is an enlarged schematic view of a portion of the layer and the active layer of the interface.

In order to enable the reviewers to have a better understanding and recognition of the structure, features and effects of this creation, the following preferred embodiments are listed, with the following description of the drawings.

Please refer to FIG. 3 to FIG. 8. The first embodiment of the present invention comprises: a lens body (10), which may be made of glass or plastic or resin, and concave or convex. A shape of the lens, and a hardening treatment by a hardener immersion plating treatment.

As shown in Figures 3 and 4, the present invention is exemplified by the use of myopia, and a first oxide layer (11) and a second oxide layer (12) are respectively disposed on the inner and outer sides of the lens body (10).

The first oxide layer (11) is coated on the lens body (10) by vacuum coating, and the first oxide layer (11) may be cerium oxide (SIO ₂ ), zirconium dioxide (ZRO ₂ ), and dioxide.矽 (SIO ₂ ) sequentially forms a first film layer (111), a second film layer (112), and a third film layer (113).

The second oxide layer (12) is also applied by vacuum coating on the outside of the first oxide layer (11) on the lens body (10), and the second oxide layer (12) may be zirconium dioxide (ZRO ₂ ). The ruthenium dioxide (SIO ₂ ), the fourth film layer (121) and the fifth film layer (122) are sequentially formed (refer to Fig. 6).

The cerium oxide (SIO ₂ ) has the characteristics of reinforcing and optical shielding, and the characteristics of bonding and aggregation with each film layer.

The zirconium dioxide (ZRO ₂ ) is a high temperature resistant glass material.

As shown in FIG. 5, a conductive film layer (13) is deposited between the first oxide layer (11) and the second oxide layer (12) by vacuum coating, and the conductive film layer (13) is ITO coated. It can increase the transparency of visible light and has electromagnetic wave protection.

As shown in FIG. 6, a light reflecting layer (14) is added outside the second oxide layer (12), and the light reflecting layer (14) may be an absorbing film or a single film or a film of any one of the reflecting films. Floor.

The absorbing film is made of orange and yellow color materials, thereby filtering blue light in the artificial light source, and can increase light transmittance, reduce color shift and increase the efficiency of filtering blue light, thereby forming a simple eye protection effect.

The reflective film is made of mercury or aluminum or metal which can be glare-resistant, blue light generated by an artificial light source.

As shown in Fig. 7, finally, an anti-fog layer (15) is added to the outermost layer of the light-reflecting layer (14), and the anti-fog layer (15) is plated with a hydrophilic nano anti-fogging agent on the reflective layer (14).

Please continue to refer to Figures 3 to 7, and use the above-mentioned combination of components to form the present invention. The inner and outer sides of the lens body (10) are respectively vacuum-coated to be cerium oxide (SIO ₂ ) and oxidized. ZrO (ZRO ₂ ) and cerium oxide (SIO ₂ ) sequentially form a first oxide layer formed by a first film layer (111), a second film layer (112), and a third film layer (113). (11) and each of the same vacuum deposition method is provided with zirconium dioxide (ZRO ₂ ), cerium oxide (SIO ₂ ), and a fourth film layer (121) and a fifth film layer (122) formed in sequence. The second oxide layer (12) adds a light reflecting layer (14) outside the second oxide layer (12), and finally, an antifogging layer (15) is added to the outermost layer of the light reflecting layer (14).

When in use, the user needs to apply a special antifouling and antistatic surfactant to the surface of the outermost layer to form an interface active layer (16) to maintain the best antifouling and antistatic effect. Figure 8)).

The advantages of this creation are as follows:

First, due to the creation of cerium oxide (SIO ₂ ), it has the characteristics of reinforcing and optical shielding, and the characteristics of bonding and aggregation with each film layer.

Second, due to the creation of zirconium dioxide (ZRO ₂ ) as a high temperature resistant glass material, this creation has the characteristics of high temperature resistance.

Third, because the creation of the conductive film layer can increase the transparency of visible light, and has electromagnetic wave protection.

4. Because the creation has an absorbing film or a reflective layer of a reflective film, thereby filtering the blue light in the artificial light source, and increasing the light transmittance, reducing the color shift and increasing the blue light filtering effect, the simple eye protection effect can be formed. Impedance glare, blue light generated by artificial light sources.

5. Because this creation has a hydrophilic nano anti-fogging agent, this creation has an anti-fog effect.

6. Since the creation has an interface active layer of an interface active agent, the best antifouling and antistatic effect can be maintained.

In this way, the creation not only has a long-lasting anti-fog effect, but also has impedance glare, blue light performance, protection of electromagnetic waves, optimal anti-fouling, Anti-static and other effects form a multi-functional mirror.

The above description is only for the preferred embodiment of the present invention, and is intended to clarify the features of the present invention, and is not intended to limit the scope of the patent application, and the equivalent changes made by those skilled in the art according to the present invention, and the present disclosure. Changes known to those skilled in the art should still fall within the scope of this creation.

(11)‧‧‧First oxide layer

(111)‧‧‧First film

(112)‧‧‧Second film

(113) ‧‧‧ third film

(12)‧‧‧Second oxide layer

(121) ‧‧‧Fourth film

(122)‧‧‧ Fifth film

(13) ‧‧‧ Conductive film

(14) ‧‧‧reflective layer

(15) ‧ ‧ anti-fog layer

(16) ‧‧‧Interfacial active layer

Claims (7)

A mirror structure comprises: a lens body, a first oxide layer and a second oxide layer respectively disposed on the inner and outer sides of the lens; the first oxide layer is coated on the lens body by vacuum coating, and the first The first oxide layer (SIO ₂ ), zirconium dioxide (ZRO ₂ ), and cerium oxide (SIO ₂ ) may sequentially form a first film layer, a second film layer, and a third film layer; The second oxide layer is also coated on the outside of the first oxide layer on the lens body by vacuum coating, and the second oxide layer may be formed by zirconium dioxide (ZRO ₂ ), cerium oxide (SIO ₂ ), and sequentially. a fourth film layer and a fifth film layer; a reflective layer is added outside the second oxide layer; and an anti-fog layer is added to the outermost layer of the light reflecting layer. The mirror structure according to claim 1, wherein the cerium oxide (SIO ₂ ) has characteristics of reinforcing and optical shielding, and a property of bonding and aggregation with each film layer; the zirconium dioxide (ZRO) ₂ ) It is made of high temperature resistant glass. According to the mirror structure of claim 1, wherein the first oxide layer and the second oxide layer are coated with a conductive film layer by vacuum coating, and the conductive film layer is ITO coated to increase visible light. Transparency and electromagnetic wave protection. The sight glass structure according to claim 1, wherein the light reflecting layer may be an absorbing film or a single film layer or a multi-film layer of any one of the reflecting films; the absorbing film is an orange or yellow color material. In order to filter the blue light in the artificial light source, and increase the light transmittance and reduce the color shift and increase the blue light filtering The effect can be formed into a simple eye protection effect; the reflective film is made of mercury or aluminum or metal which can be impedance glare, blue light generated by an artificial light source. The mirror structure according to claim 1, wherein the anti-fog layer is a hydrophilic nano anti-fogging agent coated on the light-reflecting layer. The mirror structure according to claim 1, wherein the lens body is made of glass or plastic or resin, and the lens is concave or convex in any shape, and is hardened by a hardening agent. The treatment is formed. According to the mirror structure described in claim 1, wherein the outer surface of the lens body is provided with an interface active layer, which is a special antifouling and antistatic surfactant, applied to the surface of the antifogging layer to maintain Best anti-fouling and anti-static effect.