CN220303494U - Anti-dazzle glass - Google Patents

Abstract

The utility model relates to the technical field of optical glass, and discloses anti-dazzle glass which comprises a base layer, wherein a first coating layer is arranged at the upper end of the inside of the base layer, a second coating layer is arranged at the lower end of the first coating layer, and a light component is arranged at the lower end of the second coating layer. According to the anti-dazzle glass, the local surface of the base layer is uniformly frosted by using water sand by adopting a numerical control machine tool, so that the light-transmitting surface of the base layer in a local specific area is changed into a matte non-reflecting surface, and meanwhile, an AR coating process is utilized to coat an anti-reflecting film on the light-emitting area of the base layer and the coating layer, so that the reflectivity of the glass is effectively reduced, the directional light transmittance of the glass is increased, the anti-dazzle glass can be processed on reinforced safety glass with different thicknesses, in practical application, the projection of the lamp in a specific angle can be ensured, the glare and light pollution of invalid diffuse light of the lamp to pedestrians and vehicles can be avoided, and the given luminous flux and color reduction degree of a lamp product can be ensured.

Description

Anti-dazzle glass

Technical Field

The utility model relates to the technical field of optical glass, in particular to anti-dazzle glass.

Background

In outdoor landscape illumination, an upper illumination lamp is installed on the common ground, and diffused light generated after the lamp emits light can generate glare to pedestrians and vehicles to form light pollution.

The prior art scheme (Chinese patent publication No. CN 210711283U) discloses an anti-dazzle glass. The anti-dazzle glass is characterized by comprising a basal layer and an optical nano coating; the surface of the basal layer is provided with a rough structure layer; the optical nano coating is a SiO2 coating. The anti-dazzle glass has the characteristics of high transmittance, high definition and ageing resistance. The comparison file is difficult to apply to outdoor landscape lighting brightening engineering.

Disclosure of Invention

In order to overcome the defects in the prior art, the utility model provides anti-dazzle glass for solving the problems in the background.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the anti-glare glass comprises a base layer, wherein a first coating layer is arranged at the upper end of the inside of the base layer, a second coating layer is arranged at the lower end of the first coating layer, a light component is arranged at the lower end of the second coating layer, a printing layer is arranged at the lower end of the inside of the base layer, and a hollow layer is arranged above the printing layer;

the lamplight assembly comprises a lamplight bar, a light source and a lens, wherein the lower end of the lamplight bar is fixedly connected with the light source, and the lower end of the light source is fixedly connected with the lens.

Preferably, the base layer is AR coated anti-dazzle glass, and the base layer adopts a water sand sanding process.

Through the technical scheme, the water Sha Mosha process can uniformly sand the surface of the base layer, so that the light-transmitting surface of the glass in a local specific area is changed into a matte non-reflecting surface.

Preferably, the first coating layer is a single-sided AR coating, and the transmittance of the first coating layer is 91.5% -93.5%.

Through the technical scheme, the reflectivity of the glass can be effectively reduced, and the directional light transmittance of the glass is increased.

Preferably, the second coating layer is an AF coating, and the second coating layer is positioned between the first coating layer and the light component.

Through the technical scheme, the AF coating film of the coating layer II can protect the coating layer I and improve the durability.

Preferably, the lamp strip of the light assembly is in adhesive connection with the second coating layer, and the lower end of the lamp strip is fixedly connected with a plurality of light sources and lenses and distributed at equal intervals.

Through above-mentioned technical scheme, the light subassembly can carry out the luminous of basic unit inside and see through the basic unit and throw away.

Preferably, the printing layer adopts a single-sided screen printing process, and the color of the printing layer is gray.

Through the technical scheme, the printing layer adopts a single-sided screen printing process, so that the attractiveness can be improved.

Compared with the prior art, the utility model provides the anti-dazzle glass, which has the following beneficial effects: according to the anti-dazzle glass, the local surface of the base layer is uniformly frosted by using water sand by adopting a numerical control machine tool, so that the light-transmitting surface of the base layer in a local specific area is changed into a matte non-reflecting surface, meanwhile, an AR coating process is utilized to coat an anti-reflecting film on the light-emitting area of the base layer and the first coating layer, the reflectivity of the glass is effectively reduced, the directional light transmittance of the glass is increased, the first coating layer can be used for protecting the first coating layer, the durability is improved, the anti-dazzle glass can be processed on reinforced safety glass with different thicknesses, and is usually matched with underground lamps, projection lamps, underwater lamps and tree lamps for use.

Drawings

FIG. 1 is a schematic diagram of a cross-sectional structure of the present utility model;

FIG. 2 is a schematic diagram of a cross-sectional structure of the present utility model;

FIG. 3 is a schematic diagram of a infrastructure of the present utility model;

fig. 4 is a schematic view of a light assembly according to the present utility model.

Wherein: 1. a base layer; 2. a first coating layer; 3. a second coating layer; 4. a light assembly; 401. a light bar; 402. a light source; 403. a lens; 5. a hollow layer; 6. and (5) printing a layer.

Description of the embodiments

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Examples

As shown in fig. 1-4, the anti-glare glass provided by the utility model comprises a base layer 1, wherein a first coating layer 2 is arranged at the upper end of the interior of the base layer 1, a second coating layer 3 is arranged at the lower end of the first coating layer 2, a light component 4 is arranged at the lower end of the second coating layer 3, a printing layer 6 is arranged at the lower end of the interior of the base layer 1, and a hollow layer 5 is arranged above the printing layer 6;

the light assembly 4 comprises a light bar 401, a light source 402 and a lens 403, wherein the light source 402 is fixedly connected to the lower end of the light bar 401, and the lens 403 is fixedly connected to the lower end of the light source 402.

Specifically, the base layer 1 is AR coated anti-glare glass, and the base layer 1 adopts a water sand sanding process. The water Sha Mosha process can uniformly sand the surface of the base layer 1, so that the light-transmitting surface of the glass in a local specific area is changed into a matte non-reflecting surface.

Specifically, the first coating layer 2 is a single-sided AR coating, and the transmittance of the first coating layer 2 is 91.5% -93.5%. The reflectivity of the glass can be effectively reduced, and the directional light transmittance of the glass can be increased.

Specifically, the second coating layer 3 is an AF coating, and the second coating layer 3 is positioned between the first coating layer 2 and the light component 4. The AF coating film of the coating layer II 3 can protect the coating layer I2 and improve the durability.

Examples

As shown in fig. 2-4, as an improvement over the previous embodiment. Specifically, the light bar 401 of the light assembly 4 is in adhesive connection with the second coating layer 3, and the lower end of the light bar 401 is fixedly connected with a plurality of light sources 402 and lenses 403 and distributed at equal intervals. The light assembly 4 is capable of emitting light from the interior of the base layer 1 and projecting through the base layer 1.

Specifically, the printing layer 6 adopts a single-sided screen printing process, and the color of the printing layer 6 is gray. The printing layer 6 can improve the aesthetic appearance by adopting a single-sided screen printing process.

Working principle: the numerical control machine tool is used for uniformly sanding the local surface of the base layer 1 by utilizing water sand, so that the light-transmitting surface of the base layer 1 in a local specific area is changed into a matte non-reflecting surface, and meanwhile, an AR coating process is utilized to coat an antireflection film on the light-emitting area of the base layer 1 and the first coating layer 2, so that the reflectivity of glass is effectively reduced, the directional light transmittance of the glass is increased, the process treatment can be carried out on reinforced safety glass with different thicknesses, and the reinforced safety glass can be used on buried lamps, projection lamps, underwater lamps and tree-illuminating lamps in a matched mode.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. An antiglare glazing comprising a substrate (1), characterized in that: the upper end of the inside of the base layer (1) is provided with a first coating layer (2), the lower end of the first coating layer (2) is provided with a second coating layer (3), the lower end of the second coating layer (3) is provided with a light component (4), the lower end of the inside of the base layer (1) is provided with a printing layer (6), and a hollow layer (5) is arranged above the printing layer (6);

the lamplight assembly (4) comprises a lamplight bar (401), a light source (402) and a lens (403), wherein the light source (402) is fixedly connected to the lower end of the lamplight bar (401), and the lens (403) is fixedly connected to the lower end of the light source (402).

2. The antiglare glass according to claim 1, wherein: the base layer (1) is AR coated anti-dazzle glass, and the base layer (1) adopts a water sand frosting process.

3. The antiglare glass according to claim 1, wherein: the first coating layer (2) is a single-sided AR coating, and the transmittance of the first coating layer (2) is 91.5% -93.5%.

4. The antiglare glass according to claim 1, wherein: the second coating layer (3) is an AF coating, and the second coating layer (3) is positioned between the first coating layer (2) and the light component (4).

5. The antiglare glass according to claim 1, wherein: the lamp strip (401) of the light assembly (4) is in adhesive connection with the second coating layer (3), and the lower end of the lamp strip (401) is fixedly connected with a plurality of light sources (402) and lenses (403) and distributed at equal intervals.

6. The antiglare glass according to claim 1, wherein: the printing layer (6) adopts a single-sided screen printing process, and the color of the printing layer (6) is gray.