RU209334U1 - Vehicle LED Light - Google Patents

Abstract

The utility model relates to lighting engineering, in particular to designs of lighting devices based on light-emitting diodes, mainly intended for use in vehicles. The claimed LED lamp for vehicles contains a housing with holes, a light-conducting layer fixed in the housing, covered with reflective and light-enhancing layers on the reverse side, LEDs with a power source. Moreover, the luminous flux of LEDs is directed to the ends of the light-conducting layer, while the light-conducting material is made of sheet acrylic glass with laser engraving of the reflective surface and milling of the front side, repeating the pattern of the frame holes made of aluminum sheet. The frame holes are made by laser cutting, while the sides of the case are made by bending from a single workpiece. The reflective layer is made of extruded clear acrylic glass. The light-conducting layer, the light-reflecting layer and the light-enhancing layer are fixed and pressed against the frame with a bracket. The technical result is an expansion of the arsenal of technical means that characterize their purpose in the form of an LED lamp for vehicles. 3 w.p. f-ly, 6 ill.

Description

The utility model relates to lighting engineering, in particular to designs of lighting devices based on light-emitting diodes, mainly intended for use in vehicles.

LED lighting devices are widely used due to their inherent advantages - high luminous efficiency, low power consumption, long service life, high level of safety, compactness and low weight, resistance to mechanical stress, light purity, radiation directivity, etc.

A well-known LED ceiling lamp (see RF utility model patent No. 104809, publ. 2011), made in the form of a rectangular flat figure, inside which LEDs with a power source are located on printed circuit boards, the front side of the lamp is made of a translucent material containing light-scattering particles , the opposite side of the luminaire has a reflective coating, the end sides of the luminaire are made of an aluminum profile with radiator cooling fins, printed circuit boards with LEDs located on them are mounted in the profile, connected to each other in an electrical network in a parallel way, the printed circuit boards are fastened together by connectors, while in The locations of the LEDs on the front side of the luminaire have semicircular through holes.

The disadvantage of the lamp is the blinding effect.

The closest technical solution is an LED lamp (see the description of the utility model patent of the Russian Federation No. 123903, publ. 2013), containing a housing with convection grooves cut into it, a light-distributing matrix coated with reflective and light-enhancing layers on the reverse side and a diffuser-diffuser with front side, limited by a circuit board with LEDs, the luminous flux of which is directed to the ends of the matrix, on the ends of the light distribution matrix, a phosphor layer is applied, consisting of regularly alternating sections of red, blue and green phosphors, while the area of \u200b\u200beach section completely covers the light incident on the end of the light distribution matrix the flux of the LED located behind it, and the LEDs located behind the areas with the same color phosphor, are combined into three independent groups, each of which is powered by a separate power supply regulated by a common microprocessor according to a given program, in the center of the panel with a reverse On the other side there is a set of spectrally selective photodetectors.

The disadvantage of this LED device is the low degree of illumination uniformity.

The purpose of developing a technical solution is to create a constructive solution aimed at expanding the functionality and improving the performance of a vehicle luminaire.

The objective of the utility model is to develop a luminaire with reduced weight and size characteristics, to improve the manufacturability of the carrier body, to improve the uniformity of illumination.

The technical result consists in expanding the arsenal of technical means that characterize their purpose in the form of an LED lamp for vehicles.

The technical result is achieved by the fact that the LED lamp for vehicles contains a housing with holes, a light-conducting layer fixed in the housing, covered with reflective and light-reinforcing layers on the reverse side, LEDs with a power source, and the luminous flux of the LEDs is directed to the ends of the light-conducting layer, while the light-conducting material made of sheet acrylic glass with laser engraving of the reflective surface and milling of the front side, repeating the pattern of the holes of the frame made of aluminum sheet. The frame holes are made by laser cutting, while the sides of the case are made by bending from a single workpiece. The reflective layer is made of extruded clear acrylic glass. The light-conducting layer, the light-reflecting layer and the light-enhancing layer are fixed and pressed against the frame with a bracket.

The proposed arrangement of a LED ceiling light for vehicles is explained by the following description of an exemplary construction and figures.

In FIG. 1 shows a sectional view of an LED lamp.

In FIG. 2 shows the LED lamp, callout node And Fig.1.

In FIG. 3 shows the overall layered design of the device.

In FIG. 4 shows the LED lamp, callout node In Fig.3.

Figure 5 shows an example of the housing, front view.

Figure 6 shows the housing, end view.

The LED vehicle luminaire consists of a body (1), a light-conducting layer (2), a reflective layer (deflector) (3), a light-enhancing layer (diffuser) (4), a light source in the form of an LED strip (5), an adhesive layer (double-sided adhesive tape, etc.) (6), brackets (7), self-locking nuts (8).

The body 1 is predominantly made of an aluminum sheet, 1.5-2 mm thick, laser-cut in various patterns. Laser technology ensures the consistency of product quality from batch to batch. The sides of the body 1 are made by bending from a single workpiece. Housing 1, made of aluminum sheet, facilitates the weight and size of the luminaire and allows for a variety of installation.

The light-conducting layer (2) is made of a sheet of acrylic glass, 6-10 mm thick, with a three-dimensional laser engraving of the reflective surface and milling of the front side, repeating the pattern placed on the frame (1). The engraving is not subject to wear, aging or abrasion. The engraving pattern allows the light to be evenly distributed over the surface of the acrylic glass, making it glow over the entire area. The laser engraving pattern allows you to illuminate acrylic glass from any side without compromising the brightness and uniformity of the glow. Uniformity is achieved by deflecting or reflecting the light flux from the rear surface of the lamp, presented in the form of a sequentially placed light-enhancing layer (diffuser) (4) and a reflective layer (deflector) (3).

The light-conducting material in the form of acrylic glass takes on the function of a waveguide (light guide), while at the boundaries of the media, namely in the places of engraving and the glued film - the light-enhancing layer (4), the light flux is refracted.

The advantage of acrylic glass is UV resistance. Also, the material is characterized by increased resistance to mechanical stress, temperature extremes.

The reflective layer (3) is made of optically transparent extruded acrylic glass and has a high (preferably above 80%) diffuse light reflectance. The advantages of this material are low weight, high light transmission, excellent impact strength, resistance to external factors and chemistry.

The light amplifying layer (diffuser) (4) performs the function of spreading the light flux as evenly as possible in all directions. Light amplifying layer (diffuser) (4) can be made of polyethylene terephthalate film.

At the end of the light-conducting layer (2), light is directed from a bright light source - LEDs (5), fixed in the housing. The LED strip (5) is powered through the positive and negative contact wires connected to the power source.

The structure consisting of the light-conducting layer (2), the light-reflecting layer (3) and the light-enhancing layer (4) is pressed against the aluminum sheet (1) by means of a bracket (7) made of, for example, an aluminum sheet. The bracket (7), in turn, is positioned with studs that are pressed into the aluminum frame (1) and fixed with self-locking nuts (8). The LED strip (5) is connected to the bracket (7) by means of an adhesive layer (double-sided tape, etc.) (6).

The utility model works as follows.

The LED strip 5, connected via a power source to a standard electrical network, begins to emit a luminous flux directed deep into the transparent sheet acrylic glass with laser engraving of the reflective surface and milling of the front side. The engraving begins to glow and evenly distribute the light flux over the light-enhancing layer (diffuser) (4), and the reflective layer (deflector) (3) helps to minimize the loss of light flux due to reflection.

The light emitted by the lighting fixture provides substantially uniform illumination of an object at a specified distance from the reflective surface of the lighting fixture's light output.

The application of the claimed utility model also made it possible to ensure manufacturability of the lamp and reduce its cost; provide ease of assembly due to a simple design and manufacturing technology; provide a modern lamp design.

Claims (4)

1. An LED lamp for vehicles, comprising a housing with holes, a light-conducting layer fixed in the housing, covered with reflective and light-reinforcing layers on the reverse side, LEDs with a power source, and the luminous flux of the LEDs is directed to the ends of the light-conducting layer, characterized in that the light-conducting material is made from sheet acrylic glass with laser engraving of the reflecting surface and milling of the front side, repeating the pattern of the holes of the frame made of aluminum sheet. 2. LED lamp for vehicles according to claim 1, characterized in that the frame holes are made by laser cutting, while the sides of the body are made by bending from a single workpiece. 3. An LED vehicle light according to claim 1, characterized in that the reflective layer is made of extruded transparent acrylic glass. 4. The LED vehicle light according to claim 1, characterized in that the light guide layer, the light reflective layer and the light reinforcing layer are fixed and pressed against the frame with a bracket.

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