RU144316U1 - LED LIGHTING DEVICE - Google Patents

Abstract

1. An LED lighting device comprising a printed circuit board with LEDs arranged over its entire area and a reflector, characterized in that the LEDs are directed in the opposite direction from the lighting direction of the LED lighting device and shine on the reflector, the light reflected from the reflector passing back through the printed circuit board, which is made in the form of thin strips in such a way that the area of the holes between the strips is at least 95% of the total area of the printed circuit board for reflection through them Nogo reflector from the light flux reflecting surface of the reflector is matt and has a reflectance not lower than 85%, wherein said circuit board lies directly on the transparent glass of the LED lighting device to transfer significant heat capacity at its outer poverhnost.2. The LED lamp according to claim 1, characterized in that the holes for the passage of the light flux reflected from the reflector are made in the form of a circle, or a semicircle, or a square, or a triangle, or a rhombus, or an oval, or a hexagon, or a parallelogram, or a polygon. 3. The LED lamp according to claim 1, characterized in that the printed circuit board is made of aluminum, copper or fiberglass. 4. The LED lamp according to claim 1, characterized in that the reflector is made of metal or plastic with the application of reflective paint. 5. The LED lamp according to claim 1, characterized in that the reflector is made of metal or plastic with high reflective and light-scattering properties. The LED lamp according to claim 1, characterized in that the openings for

Description

The utility model relates to lighting technology, namely to LED lighting devices in which light-emitting diodes are used as light sources.

Currently, various LED light sources are widely used in the market of lighting products, which actively compete with products based on incandescent lamps, fluorescent and halogen lamps. Products based on LEDs and LED arrays are used in various lighting devices (lamps), signaling devices (traffic lights, beacons, direction signs), as well as in various information displays and advertising products.

The use of LEDs in lighting systems has a number of problems associated with the need to remove heat from LEDs, low glare effect, high light output, as well as the difficulty of obtaining the necessary luminous flux diagram.

The prior art LED lighting device, which contains a flat box-shaped housing with a window made of translucent material, LEDs mounted on solid strip-shaped printed circuit boards, electrically connected to each other, distributed over the area of the rear wall of the housing and fastened to it with fasteners, according to of the utility model, the boards are made of foiled textolite, while the electrical connection of the printed circuit boards to each other is made using switching wires (pa entu Russian Federation for utility model 111 248 U, F21S 8/00, 10.12.2011).

Also known is a LED lighting device selected by the authors as a prototype and comprising a housing with a window of translucent material and single LEDs located on the rear wall of the housing. LEDs are distributed evenly over the entire area of the rear wall of the housing and are mounted on printed circuit boards with an aluminum base, fixed in the housing with fasteners. The perimeter of the rear wall is equivalent to the perimeter of the window, the casing is made in the form of a rectangular flat figure with the possibility of installation in the cells of the suspended ceiling (RF patent for utility model 87598 U, H05K 5/00, H01L 33/00, 06/11/2009).

The disadvantages of the known devices are low light output; uncomfortable lighting, expressed by high sharpness of light; low lighting efficiency due to the small area of the window and because of its poor optical properties; as well as poor cooling of the LEDs due to the lack of cooling holes in the housing of LED lamps.

The technical result of the claimed utility model is to achieve a low glare effect, increase light output, increase the uniformity of the light window, increase convection cooling properties.

The technical result is achieved due to the fact that the LED lighting device contains a printed circuit board with LEDs located throughout its area and a reflector, while the LEDs are directed in the opposite direction from the lighting direction of the LED lighting device and shine on the reflector, and the light reflected from the reflector passes back through printed circuit board, which is made in the form of thin strips so that the area of the holes between the strips is at least 95% of the total area of the printed circuit board In order to pass through them the light flux reflected from the reflector, the reflecting surface of the reflector is matte and has a reflection coefficient of at least 85%, while this printed circuit board lies directly on the transparent glass of the LED lighting device to transmit significant thermal power to its external surface.

In a preferred embodiment, the holes for the passage of light reflected from the reflector are made in the form of a circle or semicircle or square or triangle or rhombus or oval or hexagon or parallelogram or polygon.

In a preferred embodiment, the printed circuit board is made of aluminum, copper or fiberglass.

In a preferred embodiment, the reflector is made of metal or plastic with the application of reflective paint.

In a preferred embodiment, the reflector is made of metal or plastic with high reflective and light-scattering properties.

In a preferred embodiment, the holes for the passage of light reflected from the reflector are made in the form of repeating geometric shapes.

The claimed technical solution is illustrated by drawings, where: in FIG. 1, 2 - shows embodiments of the claimed LED lighting device.

The LED lighting device contains a printed circuit board 1 with LEDs 2 evenly distributed over its entire area and a reflector 3. The LEDs 2 are located on the printed circuit board 1 so that the light flux from them is directed in the opposite direction from the direction of illumination of the LED lighting device and shines on the reflector 3, which can be made of metal or plastic with the use of reflective paint or of a material that provides sufficient reflection of light. Reflected from the reflector 3, the light flux passes back through the holes cut out in the printed circuit board 1 (see Fig. 1, 2). Moreover, the printed circuit board 1 is made in the form of thin strips so that the area of the holes between the strips is at least 95% of the total area of the printed circuit board 1 for the light flux reflected from the reflector 3 to pass through them (see Fig. 1). The reflecting surface of the reflector 3 is matte and has a reflectance of at least 85%. In this case, the printed circuit board 1 lies directly on the transparent glass 4 of the LED lighting device for transmitting significant thermal power to the outer surface of the transparent glass 4, the transmittance of which is about 90% (see Fig. 1).

In a preferred embodiment, the holes for the passage of light reflected from the reflector 3 are made in the form of a circle or a semicircle or a square or a triangle or a rhombus or an oval or a hexagon or a parallelogram or polygon.

In a preferred embodiment, the printed circuit board 1 is made of aluminum, copper or fiberglass.

In a preferred embodiment, the reflector 3 is made of metal or plastic with the application of reflective paint or made of metal or plastic with high reflective and light-scattering properties.

In a preferred embodiment, the holes for the passage of light reflected from the reflector 3 are made in the form of repeating geometric shapes.

In the claimed LED lighting device, a low glare effect is achieved due to the fact that the LEDs 2 are not visible to the user, namely, direct light from the LEDs 2 creates a high concentration of light flux over a small area. In this solution, the light from the LEDs 2 is reflected from the matte surface of the reflector 3 and is completely diffused.

The reflector 3 may not be covered with reflective paint in the event that the material itself provides the necessary reflection of light.

Improving the uniformity of the light window is achieved by a combination of uniform distribution of LEDs 2 over the entire area of the circuit board 1 and the scattering properties of the matte surface of the reflector 3.

The increase in light output is achieved through the use of transparent glass 4 with a transmittance of about 90%. In comparison, to diffuse direct light from LEDs 2, it is necessary to use scattering glasses, in which scattering does not occur due to a rough surface, but due to the inclusion of special additives in the composition of the plastic, which reduce the transmittance to 50-70%.

The increase in convection cooling properties is achieved due to the fact that the printed circuit board 1 lies directly on the transparent glass 4 of the LED lighting device and transfers heat well through the specified glass 4 to the lower surface, which in turn has good access to the large amount of air in the room in which it is used LED lighting device.

In the absence of the need for high IP performance, a complete rejection of the protective glass 4 is possible.

Claims (6)

1. An LED lighting device comprising a printed circuit board with LEDs arranged over its entire area and a reflector, characterized in that the LEDs are directed in the opposite direction from the lighting direction of the LED lighting device and shine on the reflector, the light reflected from the reflector passing back through the printed circuit board, which is made in the form of thin strips in such a way that the area of the holes between the strips is at least 95% of the total area of the printed circuit board for reflection through them Nogo light flux from the reflector, the reflector reflecting surface is matt and has a reflectance not lower than 85%, wherein said circuit board lies directly on the transparent glass of the LED lighting device to transfer significant heat capacity on its outer surface. 2. The LED lamp according to claim 1, characterized in that the holes for the passage of light reflected from the reflector are made in the form of a circle, or a semicircle, or a square, or a triangle, or a rhombus, or an oval, or a hexagon, or a parallelogram, or a polygon. 3. The LED lamp according to claim 1, characterized in that the printed circuit board is made of aluminum, copper or fiberglass. 4. The LED lamp according to claim 1, characterized in that the reflector is made of metal or plastic with the use of reflective paint. 5. The LED lamp according to claim 1, characterized in that the reflector is made of metal or plastic with high reflective and light-scattering properties. 6. The LED lamp according to claim 1, characterized in that the holes for the passage of light reflected from the reflector are made in the form of repeating geometric shapes.