RU95793U1 - LIGHT PLANE ENERGY-SAVING - Google Patents

Abstract

 1. The lamp is flat energy-saving, including a flat lighting fixture, which includes an optical device in the form of a transparent rectangular panel, an LED emitter adjacent to the end of the lamp, while the front side of the panel is a light-emitting surface, and separate optically inhomogeneous elements are made on its opposite side , the combination of which scatters toward the frontal surface the light flux emitted from the panel end that propagates inside it due to the effect of total internal reflection, characterized in that the armature additionally includes a secondary power source for the LEDs, and the set of scattering elements is made in the form of a matrix of polymer inclusions containing photoluminophore fillers in the polymer, which additionally emit light, changing the color rendering of the LEDs. ! 2. The lamp according to claim 1, characterized in that the surface of the carrier matrix is made reflective, and the power source contains a planar transformer. ! 3. The lamp according to claim 1, characterized in that the fillers additionally use photoluminophores from the class of phosphors with a afterglow of at least 1 hour! 4. A luminaire according to any one of claims 1 or 3, characterized in that the matrix base is made of transparent material and mounted on a mirror surface of the plate included in the fixture and placed on the side of the panel opposite its front surface, protected by an impact-resistant transparent coating.

Description

The invention relates to devices for the internal lighting of a human environment.

It is known (US 7473022 B2, Jan. 6, 2009 - analogue and prototype) that for illumination of interior use flat lamps, which use an optical device in the form of a transparent panel with an end LED backlight. The operation of such luminaires is based on the phenomenon of total internal reflection of light in the panel and its scattering on optically inhomogeneous elements of the scattering and reflective matrix. Matrix elements are obtained by engraving with a mechanical cutter or laser.

The disadvantage of these devices is the impossibility of changing the color rendering of LEDs or converting the ultraviolet and visible blue parts of the emission spectrum of the cheapest LEDs into visible light of a satisfactory color perception for the human eye.

The technical result of the proposed model is to expand the color gamut of light emission from luminaires using an additional emitting matrix of photoluminophore diffusers, including those with a long afterglow to provide emergency lighting.

The specified technical result is achieved by the fact that the luminaire includes flat lighting fixtures, including an optical device in the form of a transparent rectangular panel, to the end of which there is an LED emitter, one front side of the panel is a light-emitting surface, and on the opposite side it is made separate optically heterogeneous elements, the combination of which (matrix) scatters towards the light-emitting surface the light flux radiated from the end of the panel, propagating inside it due to the effect of total internal reflection. Unlike the prototype, the reinforcement additionally includes a flat secondary LED power source, which includes a planar transformer, and the set of scattering elements is made in the form of a matrix of polymer inclusions containing photoluminescent fillers in the polymer, which additionally emit, changing the color rendering of the LEDs, due to the photoluminescence effect . In this case, the surface of the supporting matrix base can be made reflective or the matrix base can be made of transparent material and mounted on the mirror surface of the plate included in the reinforcement and placed on the side of the panel opposite its front surface.

This is also achieved by the fact that, in addition, photophosphors from the phosphorus class with a afterglow of at least one hour are used as fillers in the matrix, providing emergency lighting.

The luminaire can be used in a floor-mounted version with appropriate transparent protection of the front surface, for example, in the form of shock-resistant glass.

As an example, figure 1 schematically shows the main functional parts of an energy-saving flat fireproof vacuum-free lamp in the form of a transparent rectangular panel of polycarbonate (1), to the end of which there is an LED emitter (2), the front side of the panel is a light-emitting surface (3) , and on its opposite side there are individual optically inhomogeneous elements (4), the combination of which partially diffuses the light flux radiated from the end of the panel and supplement flaxly radiates towards the frontal surface. A flat secondary LED power supply (5) is built into the lamp. The matrix of scattering elements is made in the form of polymer inclusions (4) containing fillers in the polymer composition in the form of photoluminophores based on garnet of the general formula A ₃ B ₅ O ₁₂ : M, where A is yttrium, gadolinium or lutetium, B is aluminum or gallium, M - cerium, europium or chromium or mixtures thereof, changing the color rendering of the LEDs in the direction of amplification of the yellow-green part of the spectrum, which is most favorably perceived by the human eye.

Claims (4)

1. The lamp is flat energy-saving, including a flat lighting fixture, which includes an optical device in the form of a transparent rectangular panel, an LED emitter adjacent to the end of the lamp, while the front side of the panel is a light-emitting surface, and separate optically inhomogeneous elements are made on its opposite side , the combination of which scatters toward the frontal surface the light flux emitted from the panel end that propagates inside it due to the effect of total internal reflection, characterized in that the armature additionally includes a secondary power source for the LEDs, and the set of scattering elements is made in the form of a matrix of polymer inclusions containing photoluminophore fillers in the polymer, which additionally emit light, changing the color rendering of the LEDs. 2. The lamp according to claim 1, characterized in that the surface of the carrier matrix is made reflective, and the power source contains a planar transformer. 3. The lamp according to claim 1, characterized in that the fillers additionally use photoluminophores from the class of phosphors with a afterglow of at least 1 hour 4. A luminaire according to any one of claims 1 or 3, characterized in that the matrix base is made of transparent material and mounted on a mirror surface of the plate included in the fixture and placed on the side of the panel opposite its front surface, protected by an impact-resistant transparent coating.