WO2011040829A1 - Light-emitting diode lighting device - Google Patents

Abstract

The invention relates to lighting engineering, and more specifically to light-emitting diode lighting devices, and can be used for indoor and outdoor localized and general lighting. The technical result of the invention consists in reducing the overall height of the light-emitting diode lighting device, increasing the luminance of the light-reflecting element and extending the range of possible uses for the light-emitting diode light sources, including light-emitting diodes with a wide angular light exit opening. The light-emitting diode lighting device comprises a profiled, cylindrical light-reflecting element; light-emitting diodes arranged along said light-reflecting element and having a maximum luminous flux directed along a line connecting the ends of the profile of the light-reflecting element, and a reflector, which is arranged along said light-reflecting element in such a way as to enable some of the luminous flux of the light-emitting diodes to be reflected onto the cylindrical surface of said light-reflecting element. The profile of the cylindrical surface of the light-reflecting element is designed in accordance with the mathematical expression given in the description, the surface of the light-reflecting element is in the form of a Lambertian surface or is equipped with a luminophore coating, and the surface of the reflector is mirror-coated.

Description

 LED lighting device

• Field of technology.

 The invention relates to lighting engineering, namely, to lighting devices with semiconductor radiation sources and can be used for indoor and outdoor local and general lighting.

 • The prior art.

 It is known to use reflected light from LEDs to illuminate objects. In particular, a garden lamp is known, which contains an LED emitter, opposite which a flat reflector is installed, which distributes the light flux reflected from its surface to the illuminated object (application JN ° DE102005053304, IPC F21V7 / 05, published April 10, 2008).

 A disadvantage of the known solution is the location of the emitter, the optical axis of which is directed almost perpendicular to the reflective surface. This arrangement of these elements determines the essential dimensions of the device. In this case, a part of the light flux directed to the axis of the device is lost.

 Known LED lighting system for street lighting, having a radiation source in the form of LEDs, located opposite the source profiled reflector, the surface of which has a coating that converts the wavelength of incident radiation and reflects it on the illuminated object (application JY ° WO2008103379, IPC F21V7 / 22; published on 28.08 .2008).

 The design of the known solution is more rational. The profiled surface allows you to control the direction of reflected light. However, as well as the above analogue,

DEPARTMENT OF JUSTICE AND EAST (R EQUALED 26) the location of the radiation sources opposite the reflector is the reason for the increased size of the lighting device.

 A known luminaire with LEDs containing a plurality of linearly located light sources, each of which creates a luminous flux directed to the solid angle имеющий, a reflector having a profiled surface mounted so that the entire light flux emitted by the LEDs into the solid angle Θ illuminates the entire surface of the reflector (application H ° \ ¥ O0071930, IPC H01L33 / 00; F21S8 / 04, published 30.11.2000).

 The placement of light sources so that the light flux directed to the solid angle Θ illuminates the entire surface of the reflector prevents the possibility of reducing the height of the lamp. As follows from the description and drawings, the size of the reflector area illuminated by each of the LEDs should correspond to the angular aperture of the light radiation. Thus, the solid angle Θ of the light emission of the LEDs, the direction of their optical axis and the position of the reflector in space are interconnected. Any change in the direction of the optical axis of the LED relative to the surface of the reflector will lead to the loss of part of the light flux. It should be noted that the above condition imposes a limitation on the possible choice of the type of LED. For example, the most effective of the created LEDs, characterized by a large angular aperture of radiation, become obviously unsuitable for a known device. The consequence of this mutual spatial arrangement of the elements of the device is the impossibility of minimizing the overall height of the lamp.

 Similar disadvantages have an LED lamp containing a reflective element, including two symmetrical reflective surfaces and a line of LEDs,

SUBSTITUTE SHEET (RULE 26) placed along the plane of symmetry (application Ns WO 2007 | 054889, MKI F21V 7/00, published May 18, 2007).

 Known decision on application jNs WO0071930 made in. as a prototype, since it has the greatest number of features similar to the invention.

^' ' Disclosure of the invention.

 The technical result of the invention is to reduce the overall height of the LED lighting device; increasing the brightness of the reflective element; expanding the range of possible use of LED light sources, including LEDs with a wide angular aperture of radiation.

 LED lighting device is characterized by the following set of essential features:

 An LED lighting device comprising a profiled cylindrical reflective element; LEDs arranged along said reflective element, the maximum luminous flux of which is directed along the line connecting the ends of the profile of the reflective element; a reflector placed along said reflective element with the possibility of reflecting part of the light flux of the LEDs on the cylindrical surface of said reflective element.

 As additional features characterizing some particular cases of the embodiment of the invention, increasing the efficiency of the device, or enhancing the achieved technical result, it is necessary to indicate the following features:

 -profile of the cylindrical surface of the reflective element is made according to the mathematical expression:

 R (a) = Ro 1 - s i n (a), where

SUBSTITUTE SHEET (RULE 26) R (a) is the polar radius of the point on the profile located under the corner and degrees to the polar axis,

 Ro - profile width, in units of length;

 95 - the cylindrical surface of the reflective element is a scattering surface (Lambert surface);

 - the cylindrical surface of the reflective element is provided with a phosphor coating;

 -the surface of the reflector is made mirrored;

The 100-reflective element is equipped with a second line of LEDs located on the other side of the profile opposite the first line of LEDs.

 The relatively close distance of the LEDs to the surface of the reflective element increases its illumination and, as a result, the brightness of the light flux reflected from the Lambert surface. The latter is also true with respect to the surface of a reflective element provided with phosphor particles.

 An indication that the maximum luminous flux of the LEDs PO has a direction along the line connecting the ends of the profile of the reflective element, it should be understood that the angle between this line and the direction of the aforementioned maximum of the luminous flux cannot be more than 90 °. Although the optimum direction is the maximum luminous flux coinciding with the optical 1 15 axis of the LED.

 The symmetrical placement of the LEDs on both sides of the profile of the reflective element allows you to increase the brightness of the light flux emitted by the surface and increase its uniformity.

 120 'List of graphic materials.

SUBSTITUTE SHEET (RULE 26) The invention is characterized by the following graphic materials:

 figure 1 shows a cross section of the device;

 figure 2 shows an option for sharing four

125 devices shown in figure 1.

 The LED lighting device shown in figure 1 contains a profiled cylindrical reflective element 1, light diodes 2 placed along it, the optical axis O-O of which is directed along the line connecting the ends of the profile

130 of the reflective element, a reflector 3 mounted along the reflective element 1 with the possibility of reflection of part of the light flux of the LEDs 2 on the cylindrical surface 4 of the reflective element 1. The radius vector Ro in the case shown exactly coincides with the axis O-O,

135 determines the height and width of the profile of the reflective device, made in accordance with the above mathematical expression. The dashed line in figure 1 shows the angle of emission of the LED equal to Ψ. Half of the light flux of the radiation of the LED 2 at an angle Ψ falls on a cylindrical surface 4

140 of the light emitting element 1. In this case, the second half of the light flux generated by the LED 2 is reflected from the reflector 3, the surface of which is made with a high reflection coefficient, and is directed to the cylindrical surface 4. Thus, the entire surface 4 is summed

145 the luminous flux created by the LED 2, regardless of the absolute value of the aperture of the radiation angle Ψ of the LED, while increasing the illumination of the surface 4 and increasing its luminosity.

SUBSTITUTE SHEET (RULE 26) LED lighting device may be used 150 in the form of various options, including two or more single devices, shown in figure 1., depending on the need.

 The embodiment shown in FIG. 2 is notable for the symmetrical placement of two pairs of I and II devices, the LED lines 2 being located on adjacent surfaces of a pair of 155 reflective elements 1. It should be noted that in a configuration of four combined devices, the technical result of the invention will also be achieved by arranging the rulers LEDs with equal pitch.

 For the useful use of the part of the light flux of 160 LEDs 2 located at the boundaries of the extended reflective element 1, the end surfaces of the latter (not shown in the drawings) can be made with reflective or light-scattering properties, and the surfaces themselves must have through holes for intensifying heat exchange.

165 'The best version of the device.

 LED lighting device is designed to create local indoor and outdoor lighting. It is clear that for specific operating conditions, different device options will be optimal. So, for indoor lighting optimal

170 is the use of the device as a ceiling lamp similar to that shown in FIG. 2. The dimensions of such a lamp can be adapted for specific purposes, for example, to create a popular standard ceiling lighting device with a 595x595 mm plan size.

 175 For local outdoor lighting, a single-section device, for example, placed on a pole and oriented along the pedestrian zone, will be sufficient. To create a standardized

SUBSTITUTE SHEET (RULE 26) surface illumination and taking into account the height of the suspension, the device can be equipped with two rows of light-emitting diodes.

'' Industrial applicability

 The invention can be implemented by known means, therefore, its use should not cause difficulties for a specialist. The design of the components of the lighting device is easily amenable to automatic production.

SUBSTITUTE SHEET (RULE 26)

Claims

Claim.  1. LED lighting device containing a profiled cylindrical reflective element; LEDs arranged along said reflective element, the maximum luminous flux of which is directed along the line connecting the ends of the profile of the reflective element; a reflector placed along said reflective element with the possibility of reflecting part of the light flux of the LEDs on the cylindrical surface of said reflective element. 2. LED lighting device according to paragraph 1, characterized in that the profile of the cylindrical surface of the light according to mathematical expression:

 (a) is the polar radius of a point on the profile located at an angle of a degrees to the polar axis,  Ro - profile width, in units of length.  3. The LED lighting device according to paragraph 1, characterized in that the cylindrical surface of the reflective element is a scattering surface.  4. The LED lighting device according to paragraph 1, characterized in that the cylindrical surface of the reflective element is provided with a phosphor coating. SUBSTITUTE SHEET (RULE 26) 5. The LED lighting device according to paragraph 1, characterized in that the reflector surface is mirrored.  6. The light-diode lighting device according to paragraph 1, characterized in that it contains two rows of light-emitting diodes placed opposite each other along the reflective element. SUBSTITUTE SHEET (RULE 26)