RU15507U1 - LIGHTING DEVICE - Google Patents

Abstract

1. A lighting device comprising a light guide provided with a diffuse scattering element, one of the ends of which is coupled to a radiation source, characterized in that the second end of the light guide is coupled to an additional radiation source, each of these radiation sources is made in the form of an LED with a polymer lens, hermetically sealed the end of the fiber, made in the form of an optically transparent tube filled with an optically transparent medium, chemically inert to the material of the tube and to the polymer lens, while showing spruce refractive index n of said medium satisfies a relation: n> n; where n is the refractive index of air. 2. The lighting device according to claim 1, characterized in that said tube is made of an elastic polymer material. The lighting device according to claim 2, characterized in that said tube is made of flexible polyvinyl chloride. The lighting device according to claim 1, characterized in that said tube is provided with a radiation reflecting screen. The lighting device according to claim 1, characterized in that the diffuse-scattering element is made in the form of a continuous or intermittent strip of light-scattering paint deposited on the surface of said tube. The lighting device according to claim 5, characterized in that said strip of paint is made monotonously tapering towards the ends of said tube. The lighting device according to claim 1, characterized in that the said tube is filled with liquid with a boiling point exceeding the operating temperature. The lighting device according to claim 7, characterized in that said tube is filled with glycerin. Illuminating

Description

LIGHTING DEVICE

The inventive utility model relates to lighting technology, namely to linear light sources that use light guide elements. Ufsoystvo can be used both as a part of various constructions for displaying information (digital-alphanumeric displays, traffic lights, mnemonic images), as well as in independent constructions such as billboards, signs, schedules, digital and analogue clocks, temperature indicators, directions, turns; for highlighting outlines, various objects, images, scales, paths.

A lighting device is known in the form of a glass gas-filled tube in which a light-emitting gas discharge is generated when connected to a voltage source (see Golovina L.S., Grigoryeva N.V., Progunova G.I., Ryabova V.M. - Reviews on electronic technology.Series 4: Gas-discharge devices abroad, - M., Institute of Electronics.- 1971, issue 1 (272), pp. 5-19).

A well-known lighting device, along with the undoubted advantages, also has disadvantages such as significant dimensions, the need for high voltage supply and metal-intensive starting equipment, the fragility of gas-filled cubes, and a relatively high cost.

A lighting device is known including an optical fiber connected to a light source. In pokriggy fibers, an incision is formed, extending from the surface to the fiber core, through which light energy is emitted in

2 O O O 11 6 1 8 8

MKIB; F21 V8 / 00, O 02 V 6/00

the radial directions of the fiber (see Japanese application No. 61-24685, class G 02 B 6/00, published 1990).

The known lighting device has a complex structure, fiber cuts must be made of a certain depth and placed according to a certain law on the surface of the fiber. The radiation of such a device occurs non-uniformly, since not its entire lateral surface, but its individual points.

A lighting device is known that includes a light source and a light guide rod with a diffuse light-scattering continuous or discontinuous strip. The rod is protected by a transparent tube installed with a gap relative to the surface of the rod (see PCT application No. WO 90105924 according to class G 02 6/00, published in 1990)

The known lighting device has a complicated design, the use of a rod as a light guide narrowing the scope of the device.

A lighting device is known including a rod light guide with a diffusely scattered portion connected to a light source. The diffuse-scattering section is made directly as part of the surface of the fiber, for example, in the form of a polished face parallel to the axis of the fiber (see USSR Author's Certificate No. 1756739 according to class F 21 V 8/00, published on 08.23.1992).

The known lighting device is quite difficult to manufacture and, due to the use of a rigid rod in it, has a limited scope.

The closest set of essential features to the claimed solution adopted for the prototype is a lighting device that includes a distributed system of light sources in the form of a flexible light guide with a radiating side surface, one of the ends of which is coupled to a radiation source (see RF patent No. 2095974 on kya. F 21 V 8/00, published on March 20, 1998).

The prototype lighting device has a relatively high cost, does not provide uniform illumination along the axis of the fiber, has a limited scope, as it is intended only for lighting birds with cage.

The task to which the claimed utility model is directed was to develop such a lighting device that would provide uniform illumination along the axis of the fiber, it was not difficult to manufacture, had a low cost and a wide scope.

The problem is solved in that in a lighting device including a light guide provided with a diffuse scattering element, one of the ends of which is connected to a radiation source, the second end of the light guide is connected to an additional radiation source, each of the radiation sources is made in the form of an LED with a polymer lens, hermetically sealed the end of the fiber, made in the form of an optically transparent tube filled with an optically transparent medium, chemically inert to the tube material and the polymer lens, while refractive index n of said medium udovletvoryaetsootnoscheniyu:

P P1,

where P1 is the refractive index of air.

The tube may be made of an elastic polymer material, for example, of flexible polyvinyl chloride. The tube may be provided with a radiation reflecting screen, and the diffusely scattering element may be in the form of a continuous or intermittent strip of light-scattering paint deposited on the surface of the tube. A strip of paint to improve the uniformity of the glow along the axis of the tube can be made monotonously tapering towards the ends of the tube. The tube may be filled with a liquid having a boiling point higher than the operating temperature, for example glycerin or brake fluid, and may also be filled with a cured epoxy. In the latter case, the diffuse-scattering element can be made in the form of filler particles introduced into the epoxy resin, for example, mica or aluminum dioxide particles. For aligning the brightness of the glow along the axis of the tube, the density of the filler particles in the cured epoxy resin is monotonically reduced towards the ends of the tube.

The conjugation of the second end of the fiber with an additional radiation source provides a higher uniformity of the glow intensity along the axis of the tube, and the implementation of radiation sources in the form of LEDs with a polymer lens makes it possible to obtain the necessary brightness of the glow with less energy and at the same time simplify the tight connection between the tube and the radiation source. The ability to fill the tube with various media expands the field of application of the inventive lighting device, reduces the cost of its manufacture.

The inventive lighting device is shown in the drawings, where:

in FIG. 1 shows a longitudinal section of a lighting device with a tube filled with liquid;

in FIG. 2 - illumination device depicted in fng. 1, when the LEDs are on (arrows indicate the direction of light propagation);

in FIG. 3 is a non-cross-sectional view of the lighting device of FIG. 2 (scale 2: 1);

in FIG. 4 is a longitudinal sectional view of a lighting device with a sponge filled with cured epoxy;

in FIG. 5 - the lighting device shown in FIG. 4, when the LEDs are on (arrows indicate the direction of light propagation).

in FIG. 6 is a cross-sectional view of the lighting device shown in FIG. 5. (scale 2: 1).

The inventive itel device consists of an optically transparent tube 1 made of an elastic polymer material, for example polyvinyl chloride, two semiconductor LEDs 2 with polymer lenses 3, hermetically sealed, the ends of the tube 1 with them. The tube 1 can be given the desired configuration. The tube 1 is equipped with a diffusely scattering element 4, which can be made out, for example, in the form of a deposited surface of a coarse 1 continuous or intermittent strip of light-scattering paint (Fig. 3), or in the form of 5 filler particles distributed in an ontically opaque medium. The LEDs 2 are placed on the crystal holders 6 and are equipped with leads 7 for connection to an electric voltage source (not shown in the drawing). The transparent medium 5 filling 1 tube 1 must be chemically inert with respect to the material of the tube 1 and the polymer lens 3. The refractive index and medium 5 should be larger than the refractive index ni of the air. The tube 1 can be filled as a medium 5 with a liquid with a boiling point exceeding the operating temperature of the device, for example, glycerin, brake fluid (Fig. 1). For alphabetic brightness of the glow along the length of the tube 1, the width of the strip of light-scattering paint used as a diffusely scattering element 4 can be monotonously tapering to the ends of the tube 1. The tube 1 can be filled with cured epoxy resin (Fig. 4), or other materials, having the above-mentioned refractive index p. Tube 1 can be enclosed in an additional light-scattering tube 8, which at the same time protects the device from mechanical damage. In the case of filling tube 1 with cured epoxy resin, filler particles are added to the resin, for example, mica particles or alumina particles serving as diffusely scattering elements 4. Tube 1 can be provided with a radiation shielding screen 9. The color of the light from the lighting device will be determined by the color of the light emitting diodes used .

Lighting device operates as follows. When the terminals 7 of LEDs 2 are connected to an electric voltage source, their radiation focused by lenses 3 propagates through an optically transparent medium 5, experiencing multiple reflections from the boundaries of different media, and when it reaches the diffuse-scattering element 4, it experiences partial and diffuse reflection, as a result what is the emission of light towards the observer and creates a lengthy luminous image. If the diffuse-scattering element 4 is made in the form of novoski along the but forming tube 1, then in this case an additional optical effect arises. Tube 1, filled with medium 5, in the direction perpendicular to its axis, is an optical element - a transparent cylinder and, according to the laws of cylindrical ontrpsy, has focusing properties in this direction. As a result, the diffuse radiation from the diffusely scattering element 4 becomes directed towards the observer, which gives a noticeable gain in the light intensity towards the observer. Directed towards each other, the radiation of two LEDs 2 and the well-chosen geometric dimensions of the diffuse-scattering element 4 make it possible to create a uniformly luminous light element that replaces dozens of point LEDs. When using LEDs 2, it is possible to dock individual lighting devices with practically no gap between their ends, which favorably affects the perception when reproducing alphanumeric information using several lighting devices.

Claims (14)

1. A lighting device comprising a light guide provided with a diffuse scattering element, one of the ends of which is coupled to a radiation source, characterized in that the second end of the light guide is coupled to an additional radiation source, each of said radiation sources is made in the form of an LED with a polymer lens, hermetically sealed the end of the fiber, made in the form of an optically transparent tube filled with an optically transparent medium, chemically inert to the material of the tube and to the polymer lens, while showing spruce refractive index n of said medium satisfies a relation: n> n _1; where n ₁ is the refractive index of air.  2. The lighting device according to claim 1, characterized in that the said tube is made of an elastic polymer material.  3. The lighting device according to claim 2, characterized in that said tube is made of flexible polyvinyl chloride.  4. The lighting device according to claim 1, characterized in that said tube is provided with a radiation reflecting screen.  5. The lighting device according to claim 1, characterized in that the diffuse-scattering element is made in the form of a continuous or intermittent strip of light-scattering paint deposited on the surface of said tube.  6. The lighting device according to claim 5, characterized in that said strip of paint is made monotonously tapering towards the ends of said tube.  7. The lighting device according to claim 1, characterized in that the said tube is filled with a liquid with a boiling point exceeding the operating temperature.  8. The lighting device according to claim 7, characterized in that the said tube is filled with glycerin.  9. The lighting device according to claim 7, characterized in that the said tube is filled with brake fluid.  10. The lighting device according to claim 1, characterized in that the said tube is filled with a cured epoxy resin.  11. The lighting device according to claim 10, characterized in that the diffuse-scattering element is made in the form of filler particles introduced into the epoxy resin.  12. The lighting device according to claim 11, characterized in that the filler particles are made of mica.  13. The lighting device according to claim 11, characterized in that the filler particles are made of aluminum dioxide. 14. The lighting device according to claim 11, characterized in that the density of the filler particles in the cured epoxy resin monotonically decreases towards the ends of the tube.