CN219889402U - Anti-dazzle magnetic lamp with optical transparent lens of new structure - Google Patents

Abstract

An anti-dazzle magnetic attraction lamp with a novel structure of an optical transparent lens comprises an anti-dazzle light transmission group, a magnetic attraction lamp and a magnetic attraction lamp, wherein the anti-dazzle light transmission group comprises a Fresnel anti-dazzle transparent light transmission plate and a secondary anti-dazzle transparent light transmission plate positioned outside the Fresnel anti-dazzle transparent light transmission plate; a lamp body having a receiving cavity; the Fresnel anti-dazzle transparent light-transmitting plate is provided with a Fresnel light-entering surface which faces to the lamp and receives light of the LED light source, and a transparent rhombic surface which is used for outputting light emitted by the LED light source after light emitted by the LED light source enters the Fresnel light-entering surface and is subjected to light path oscillation refraction and direction change; the secondary anti-dazzle transparent light-transmitting plate receives light output by the surface of the transparent rhombic crystal, and light path oscillation refraction is carried out again to change the direction so as to output outwards; forming various beam angles of 10-90 degrees; the light beam is changed in direction through the Fresnel light-in surface transparent lens, collected and diffused and output from the surface of the transparent rhombic crystal, and the surface of the transparent rhombic crystal effectively increases the light-out rate to enhance the brightness, and simultaneously passes through the secondary anti-dazzle transparent lens after anti-dazzling.

Description

Anti-dazzle magnetic lamp with optical transparent lens of new structure

Technical Field

The utility model relates to an anti-dazzle magnetic lamp with a novel structure for an optical transparent lens.

Background

According to patent retrieval and market investigation, a main-free lamp is characterized in that a hanging guide rail or a built-in guide rail is not arranged in the middle of a house, and each material magnetic lamp (a spot lamp, a down lamp, a tubular lamp) and the like are installed in a freely detachable manner to illuminate, so that the lighting system belongs to a lighting mode of regional scattered points, and according to space requirements, the lighting requirements of the main-free lamp can be met by combining a line light source and a point light source, so that the lighting requirements of a complex space on the lighting can be met, and the lighting system is very humanized in design and can be arranged in a DIY (direct in space hierarchy) manner, and has good experience; however, the existing magnetic lamp floods have contradictory structural defects of anti-glare and poor brightness, and the anti-glare is a mode of adding a frosting sheet, so that light can penetrate through the frosting sheet to prevent dazzling, but the brightness is greatly reduced; if a transparent flat light plate is adopted, the brightness is improved, but the light is dazzling; in order to solve the problems, an anti-dazzle magnetic lamp with a novel structure and an optical transparent lens is developed.

Disclosure of Invention

The utility model aims to solve the technical problem of providing an anti-dazzle magnetic attraction lamp with a novel structure, which has the characteristics of brightening output and multiple anti-dazzle refraction, and changes the direction of light through a Fresnel light-entering surface transparent lens, collects the light and then outputs the light from the surface of a transparent rhombic crystal in a scattering way, so that the light-emitting rate of the transparent rhombic crystal is effectively increased, the brightness is enhanced, and the light is anti-dazzled again through a secondary anti-dazzle transparent rhombic crystal lens; simple structure, cost of manufacture are low and user experience is good.

In order to achieve the above purpose, the present utility model adopts a technical scheme that an optical transparent lens anti-glare magnetic lamp with a new structure is provided, which comprises:

an anti-glare light-transmitting group,

the lamp body is provided with a containing cavity and an LED light source arranged in the containing cavity, and the LED light source emits light rays which are subjected to repeated light path oscillation refraction of the anti-dazzle light-transmitting group to change the direction so as to be output outwards.

In one or more embodiments of the present utility model, the antiglare transparent group includes a fresnel antiglare transparent light transmission sheet and a secondary antiglare transparent light transmission sheet positioned outside of the fresnel antiglare transparent light transmission sheet; the Fresnel anti-dazzle transparent light-transmitting plate is provided with a Fresnel light-entering surface which faces to the lamp and receives the light of the LED light source, and a transparent rhombic surface which is used for outputting the light emitted by the LED light source after the light enters the Fresnel light-entering surface and is subjected to light path oscillation refraction change direction; the secondary anti-dazzle transparent light-transmitting plate is tightly attached to the surface of the Fresnel anti-dazzle transparent light-transmitting plate.

In one or more embodiments of the present utility model, the lamp body is provided with a limiting groove for the co-placement of the secondary antiglare transparent light-transmitting panel and the fresnel antiglare transparent light-transmitting panel; the secondary anti-dazzle transparent light-transmitting plate receives light output by the surface of the transparent rhombic crystal, and light path oscillation refraction is carried out again to change the direction so as to output the light outwards.

In one or more embodiments of the utility model, the rhombic surface forms uniformly arranged asperities.

In one or more embodiments of the present utility model, the lamp body is provided with a limiting groove for the co-placement of the secondary antiglare transparent light-transmitting panel and the fresnel antiglare transparent rhombic light-transmitting panel.

In one or more embodiments of the present utility model, the transparent rhombic surface forms a uniformly arranged concave-convex shape (or a cone shape or a triangle shape or a hexagon shape or a polygon shape).

In one or more embodiments of the utility model, the secondary antiglare transparent light transmission panel has a uniformly disposed concave light cup surface.

In one or more embodiments of the present utility model, the fresnel anti-glare transparent light-transmitting plate and the secondary anti-glare rhombic transparent light-transmitting plate are made of transparent plastic or transparent soft rubber or transparent glass.

In one or more embodiments of the utility model, the light modifying crystal surface has a uniform arrangement of continuous protrusions or a plurality of planes, including circular or elliptical or polygonal.

In one or more embodiments of the utility model, the lamp body is connected to an electrical coupling block.

In one or more embodiments of the utility model, the lamp body is integrally formed of a metal material or plastic.

In one or more embodiments of the present utility model, two ends of the lamp body are provided with clamping seal heads.

In one or more embodiments of the utility model, the LED light source light forms a plurality of beam angle outputs of 10-90 degrees by means of a Fresnel anti-dazzle transparent light transmission plate and a secondary anti-dazzle transparent light transmission plate.

Compared with the background technology, the utility model has the following effects: by adopting the technical scheme, the anti-dazzle transparent rhombic lens has the characteristics of brightening output and multiple anti-dazzle refraction, light is changed to be concentrated through the Fresnel light-entering surface transparent lens, then the light is diffused and output from the surface of the transparent rhombic, the light-emitting rate of the surface of the transparent rhombic is effectively increased to enhance the brightness, and the anti-dazzle transparent rhombic lens is subjected to secondary anti-dazzle after anti-dazzle; simple structure, cost of manufacture are low and user experience is good, therefore, it has superior performance in technical, practicality and economic aspects.

Drawings

FIG. 1 is a schematic perspective view of an anti-glare magnetic lamp with a novel structure of an optically transparent lens according to an embodiment of the utility model;

FIG. 2 is an enlarged view of FIG. 1 at A;

FIG. 3 is an enlarged view of FIG. 1 at B;

FIG. 4 is a schematic view showing an expanded structure of an anti-glare magnetic lamp with a novel structure of an optically transparent lens according to another embodiment of the utility model;

FIG. 5 is a schematic view showing an expanded structure of an anti-glare magnetic lamp with a novel structure of an optically transparent lens according to another embodiment of the utility model;

FIG. 6 is a schematic diagram showing an expanded structure of an anti-glare magnetic lamp with a novel structure of an optically transparent lens according to another embodiment of the utility model;

FIG. 7 is a schematic diagram of an alternative cellular network in a new structural anti-glare light-transmitting group in accordance with another embodiment of the present utility model;

those skilled in the art will recognize, from the shape, construction and understanding of the arrangements shown in the drawings, the various components of the drawings are not necessarily to scale and the dimensions of the various components and elements of the drawings may be exaggerated or reduced to more clearly illustrate the embodiments of the present utility model described herein.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout.

The orientations shown in the drawings are not to be construed as limiting the specific scope of the utility model, and merely as a reference to the preferred embodiments, variations in the positions or numbers of product components shown in the drawings or structural simplifications may be made.

The terms "connected" and "connected" as used in the specification and illustrated in the drawings refer to the components as being "connected" to each other, and are understood to mean fixedly connected or detachably connected or integrally connected; the connection can be direct connection or connection through an intermediate medium, and a person skilled in the art can understand the connection relation according to specific situations to obtain a screw connection or riveting or welding or clamping or embedding and other modes to replace the modes in different embodiments in a proper mode.

Terms of orientation such as up, down, left, right, top, bottom, and the like, as well as orientations shown in the drawings, may be used for direct contact or contact by additional features between the components; such as directly above and obliquely above, or it merely represents above the other; other orientations may be understood by analogy. The technical scheme and the beneficial effects of the utility model are more clear and definite by further describing the specific embodiments of the utility model with reference to the drawings in the specification.

1-3, however, those skilled in the art will readily appreciate that the detailed description given herein with respect to these figures is for illustrative purposes only and should not be construed as limiting, the present embodiment provides a new configuration of an optical lens anti-glare magnetically attractable lamp that includes an anti-glare light-transmitting group 1 and a lamp body 2, the anti-glare light-transmitting group 1 including a Fresnel anti-glare light-transmitting plate 11 and a secondary anti-glare light-transmitting plate 12 located outside the Fresnel anti-glare light-transmitting plate 11; the lamp body 2 is provided with a containing cavity 21, the Fresnel anti-dazzle light-transmitting plate 11 is provided with a Fresnel light-entering surface 111 which faces towards the lamp and receives the light of the LED light source 3, and a rhombic surface 112 which enables light emitted from the LED light source 3 to enter the Fresnel light-entering surface 111 and then generate light path oscillation, refraction and change direction for outputting; the secondary anti-dazzle light-transmitting plate 12 receives light output by the surface of the rhombic crystal, and light path oscillation refraction changes direction again to output outwards.

The secondary antiglare light-transmitting panel 12 is adhered to the surface of the fresnel antiglare light-transmitting panel. The lamp body 2 is provided with a limit groove 22 in which the secondary antiglare light-transmitting panel 12 and the fresnel antiglare light-transmitting panel 11 are placed together. The rhombic surface 112 forms uniformly arranged concavities and convexities. The secondary antiglare light-transmitting panel 12 has a concave light cup 121 uniformly disposed. The Fresnel anti-dazzle light-transmitting plate 11 and the secondary anti-dazzle light-transmitting plate 12 are made of transparent plastic or transparent soft rubber or transparent glass.

The lamp body 2 is connected to an electrical coupling block 4. The lamp body 2 may be integrally formed of a metal material or plastic. Two ends of the lamp main body 2 are provided with clamping seal heads 5.

The light of the LED light source 3 forms various beam angles of 10-90 degrees to be output by means of the Fresnel anti-dazzle light-transmitting plate 11 and the secondary anti-dazzle light-transmitting plate.

When in installation, the electric coupling block 4 is matched and placed in a guide rail without a main lamp to be connected with electricity, and the LED lamplight source 3 irradiates the Fresnel light inlet surface 111 after being reflected by the reflecting cup (reflecting paper) 6; after the light rays are subjected to vibration refraction and change direction through the Fresnel anti-dazzle light-transmitting plate 11 to perform primary anti-dazzle transmission, the light rays are subjected to anti-dazzle transmission again to the secondary anti-dazzle light-transmitting plate 12, and are brightened and output (various beam angles of 10-90 degrees are formed) from the concave light cup surface 121. The light has the characteristics of brightening output and multiple anti-dazzle refraction, the Fresnel light-entering surface lens is used for enabling the light to change direction and collect light, then the light is diffused and output from the surface of the rhombic crystal, the light-emitting rate of the transparent rhombic crystal surface is effectively increased, the brightness is enhanced, and the light is anti-dazzled and then passes through the secondary anti-dazzle lens; simple structure, cost of manufacture are low and user experience is good, therefore, it has superior performance in technical, practicality and economic aspects.

Fig. 4 to 6 show modifications of the present utility model, and the examples of fig. 4, 5 and 6 are exemplified to illustrate that the combination of the anti-glare light-transmitting group 1 can be a combination of transparent lenses in various forms, but the present utility model is not limited to the above embodiment, so long as the light emitted from the LED light source passes through the anti-glare light-transmitting group to oscillate and refract repeatedly to change the direction to be output to the outside, so that the anti-glare effect can be achieved.

Fig. 7 shows that the new anti-glare light transmission group has an alternative honeycomb net, and the honeycomb net can be combined by a fresnel transparent lens rhomb face combined honeycomb net or a wave lens combined honeycomb net or a strip convex lens group honeycomb net in different implementations.

For purposes of explanation, the foregoing descriptions use specific nomenclature to provide a thorough understanding of the embodiments. However, it will be apparent to one skilled in the art that the specific details are not required in order to practice the embodiments. It will be understood by those skilled in the art that the present utility model is not limited to the particular embodiments described above, but that modifications and substitutions using techniques known in the art on the basis of the present utility model fall within the scope of the present utility model, which is defined by the claims.

Claims (10)

1. An anti-glare magnetic lamp with a novel structure for an optical transparent lens, which is characterized by comprising:

an anti-glare light-transmitting group,

the lamp body is provided with a containing cavity and an LED light source arranged in the containing cavity, and the LED light source emits light rays which are subjected to repeated light path oscillation refraction of the anti-dazzle light-transmitting group to change the direction so as to be output outwards.

2. The new construction of optically transparent lens anti-glare magnetic attraction lamp of claim 1 wherein the anti-glare light transmission group includes a fresnel anti-glare transparent light transmission plate and a secondary anti-glare transparent light transmission plate located outside the fresnel anti-glare transparent light transmission plate; the Fresnel anti-dazzle transparent light-transmitting plate is provided with a Fresnel light-entering surface which faces to the lamp and receives the light of the LED light source, and a transparent rhombic surface which is used for outputting the light emitted by the LED light source after the light enters the Fresnel light-entering surface and is subjected to light path oscillation refraction change direction; the secondary anti-dazzle transparent light-transmitting plate is tightly attached to the surface of the Fresnel anti-dazzle transparent light-transmitting plate.

3. The new-structure optical transparent lens anti-glare magnetic attraction lamp as claimed in claim 2, wherein the lamp body is provided with a limit groove for the co-placement of the secondary anti-glare transparent light-transmitting plate and the fresnel anti-glare transparent light-transmitting plate; the secondary anti-dazzle transparent light-transmitting plate receives light output by the surface of the transparent rhombic crystal, and light path oscillation refraction is carried out again to change the direction so as to output the light outwards.

4. The new construction of optically transparent lens anti-glare magnetic attraction lamp of claim 3 wherein the rhombic surface forms uniformly disposed asperities.

5. The new construction of optically transparent lens anti-glare magnetic attraction lamp of claim 2 wherein the secondary anti-glare transparent light transmission plate has a uniformly disposed concave light cup surface.

6. The new construction of the anti-glare magnetic attraction lamp for optical transparent lenses of claim 5, wherein the fresnel anti-glare transparent light-transmitting plate and the secondary anti-glare transparent light-transmitting plate are made of transparent plastic or transparent soft plastic or transparent glass.

7. The new construction of optically transparent lens anti-glare magnetic attraction lamp of claim 6 wherein the lamp body is connected to an electrical coupling block.

8. The new construction of optically transparent lens anti-glare magnetic attraction lamp of claim 7 wherein the lamp body is integrally formed of a metallic material or plastic.

9. The new construction of optically transparent lens anti-glare magnetic lamp of claim 8, wherein the lamp body has snap-in heads at both ends.

10. The new construction of optically transparent lens anti-glare magnetic attraction lamp of claim 9 wherein the LED light source light forms a plurality of beam angle outputs of 10-90 degrees by means of fresnel anti-glare transparent light transmission panels and secondary anti-glare transparent light transmission panels.