RU2306587C1 - Lighting system - Google Patents

Abstract

FIELD: optics.

SUBSTANCE: lighting system comprises, at least, one radiation source, light-conductive layer and an array of light-emitting elements, positioned on the light-conductive layer. Light-emitting elements are made in form of truncated pyramids, lesser bases of which are positioned on the upper surface of the light-conductive layer with creation of optical contact, and side edges of light-conductive elements provide for reflection of light, entering through the base, in a direction which is normal to upper surface of light-conductive layer, while pyramids are made polygonal, greater bases of pyramids are adjacent to each other along perimeter, while the generating line of the side edges is a quadratic curve.

EFFECT: increased efficiency.

14 cl, 3 dwg

Description

The invention relates to the field of optics, namely to lighting systems, and can be used to illuminate liquid crystal (LCD) displays.

In general, the LCD backlight device operates as follows: the light coming from the light source enters the light guide plate, which provides uniform illumination and limits the angular aperture of light, and after the light guide plate passes through, the light is projected onto the surface of the LCD panel. The light guide plate, as a rule, includes a light guide layer and optical output elements located thereon. The uniformity of illumination and the limitation of the angular aperture of light are obtained due to the corresponding geometry and location of the light guide layer and light output elements.

A known lighting system (see US Patent Application Laid-open No. 2001/0053074 [1]), which includes a light source, a light guide layer and an array of light output elements located on the light guide layer, the light guide layer and light output elements are made of optically transparent material, and the light-output elements are made with rounded side faces and flat in places of contact with the light guide plate. The disadvantage of the plate is that to ensure uniformity of illumination of the LCD panel, the distance between the cylindrical light-output elements varies along the surface of the plate, resulting in bright stripes with different distances between them appear on the inner surface of the LCD panel. So that this does not worsen the uniformity of illumination of the LCD panel, the distances between such strips should be significantly less than the pixel size. This means that the light-output elements must be small in size, which creates a number of difficulties in the production of such a scheme.

Closest to the claimed invention is a lighting system described in US patent No. 5396350 [2], which includes a radiation source, a light guide layer and an array of light output elements located on the light guide layer, the light guide layer and light output elements made of optically transparent material, the light guide layer has an upper surface, a lower surface and two side surfaces located opposite each other, and the light output elements are made in the form of prisms, The larger bases of which are located on the upper surface of the light-conducting layer with the formation of optical contact, the side faces of the light-output elements provide reflection of the light entering through the base, in accordance with the condition of total internal reflection in the direction of the upper surface of the light-conducting layer. The light-output elements made in the form of prisms are arranged with equal steps on the surface of the light guide plate and allow the radiation to be output from the light guide layer, as well as somewhat restrict the angular aperture of the light entering the LCD panel. This lighting system is selected as a prototype of the claimed invention.

The disadvantage of the prototype is the lack of uniformity of illumination at the output of such a lighting system due to the presence of gaps between the large bases of the prisms, and also due to the fact that such a solution does not provide means to ensure uniform illumination over the entire surface of the lighting system - light-emitting elements of the same shape are arranged with the same pitch independently from a distance to a light source. In addition, the light reflected from the flat side surfaces of the light-emitting elements, in this case, the prisms, passes without additional restriction of the output angular aperture, since the angular aperture at the exit is practically determined by the range of angles of propagation of radiation inside the light guide plate for which the condition of total internal reflection is satisfied , that is, such a lighting system does not allow a high degree of collimation of light at the output.

The objective of the claimed invention is the creation of a lighting system with increased uniformity of illumination and improved collimation of light at the output.

The problem is solved by developing such a design, which includes at least one radiation source, a light guide layer and an array of light output elements located on the light guide layer, the light guide layer and the light guide elements made of optically transparent material, the light guide layer has a top surface , the lower surface and two side surfaces, the upper surface and the lower surface are made with the possibility of re-reflection of the radiation entering the light guide the supply layer from the side of the transparent side surface, onto the smaller bases of the light output elements, the light output elements being made in the form of truncated pyramids, the smaller bases of which are located on the upper surface of the light conductive layer to form an optical contact, and the side faces of the light output elements reflect light entering through the base, in the direction normal to the upper surface of the light guide layer, the pyramids being polygonal, adjacent to the large bases of the pyramids to each other on the perimeter, the side faces forming the line is a curve of second order.

The technical result of the claimed invention is to increase the uniformity and degree of collimation of light by changing the shape of the light-output optical elements and their location.

For a better understanding of the present invention, the following is a detailed description thereof involving graphic materials.

Figure 1. Scheme of the lighting system (side view), made according to the invention.

Figure 2. The scheme of the lighting system (side view, fragment), made according to the invention.

Figure 3. Placement of light output elements (top view).

Consider an example of a lighting system, shown in figure 1 and figure 2. The lighting system 1 includes a radiation source 2, a light guide layer 3, and an array of light output elements 4 located on the light guide layer 3. The light guide layer 3 and the light output elements 4 are made of optically transparent material. The light guide layer has an upper surface 5, a lower surface 6 and side surfaces 7 and 8, which are located opposite each other. The lateral surface 8 of the light guide layer in one embodiment of the invention can be made reflective. The light guide elements 4 are made in the form of truncated pyramids, smaller bases 9 of which are located on the upper surface 5 of the light guide layer 3 with the formation of optical contact with this layer.

At the base of the light output elements lies a polygon, for example a rectangle or a hexagon (see Figure 3). Large bases of 10 pyramids are adjacent to each other around the perimeter, which eliminates the gaps between the bases and allows you to get uniform lighting at the output of the claimed lighting system. The side faces 11 of the light output elements 4 are made based on the condition of total internal reflection for the rays coming from the light guide layer 3, in addition, the side edges 11 of the light output elements 4 are bent, in one embodiment of the invention, the line of the side faces is a parabola, which allows to increase degree of collimation of light.

Light enters the light guide layer 3 through the side surface 7 and propagates in the light guide plate in accordance with the condition of total internal reflection. Rays falling on the smaller bases 9 of the light-output elements 4 exit the light-conducting layer 3. The lateral faces 11 of the light-output elements 4 reflect the rays passing through the smaller bases 9 in a direction perpendicular to the upper surface 5 of the light-conducting layer 3, while ensuring collimation of the outgoing light. The bases 9 and 10 of the light-emitting elements 4 are flat and parallel to each other.

A uniform distribution of light at the exit of the light-output elements is achieved by changing the parameters of the light-output elements along the surface of the light-conducting layer, namely, by changing the ratio of the areas of the large and small bases of the light-output elements 4 on the surface of the light-conducting plate, and to maintain uniform illumination at the output of the lighting system, the area of the large base of the light-output element remains constant. The ratio of the areas of the large and small bases of the light output elements decreases with increasing distance from the light output element to the radiation source. The dependence of this relationship on the distance to the light source can be either linear, or non-linear, or stepwise.

In one of the experimental embodiments of the invention, the lighting system has two radiation sources, in this case, the side surfaces are optically transparent and made of optically transparent material, and the lighting system has plane symmetry.

The described embodiment of the invention was set forth to illustrate the present invention, therefore, it should be clear to those skilled in the art that various modifications, additions and substitutions are possible without departing from the scope and meaning of the present invention as claimed in the appended claims.

Claims (15)

1. A lighting system including at least one radiation source, a light guide layer and an array of light output elements located on the light guide layer, the light guide layer and the light output elements are made of optically transparent material, the light guide layer has an upper surface, a lower surface, and two lateral surfaces, the upper surface and the lower surface are made with the possibility of re-reflection of radiation entering the light guide layer from the side of the transparent lateral surface to the smaller bases of the light-output elements, the light-output elements made in the form of truncated pyramids, the smaller bases of which are located on the upper surface of the light-conducting layer with the formation of optical contact, and the side faces of the light-output elements reflect the light entering through the base in the direction normal to the upper the surface of the light guide layer, the pyramids being polygonal, the large bases of the pyramids adjacent to each other around the perimeter, while the line of the side faces is a second-order curve. 2. The lighting system according to claim 1, characterized in that one of the side surfaces of the light guide layer is made reflective. 3. The lighting system according to claim 1, characterized in that the lower and upper surfaces of the light guide layer reflect light due to the effect of total internal reflection. 4. The lighting system according to claim 1, characterized in that the lighting system has a plane of symmetry, and both side surfaces of the light guide layer are optically transparent and are designed to introduce radiation. 5. The lighting system according to claim 1, characterized in that the base of the pyramids of the light-output elements is made in the form of a hexagon. 6. The lighting system according to claim 1, characterized in that the base of the pyramids of the light-output elements is made in the form of a rectangle. 7. The lighting system according to claim 1, characterized in that the light-emitting elements are made on a substrate of optically transparent material. 8. The lighting system according to claim 1, characterized in that the upper and lower surfaces of the light guide layer are parallel to each other. 9. The lighting system according to claim 1, characterized in that the lower surface of the light guide layer is inclined relative to the upper surface of the light guide layer. 10. The lighting system according to claim 1, characterized in that the generatrix line of the side faces of the light output elements is made in the form of a parabola. 11. The lighting system according to claim 1, characterized in that the ratio of the areas of the large base of the pyramids and the small base of the pyramids of the light output elements varies depending on the distance between the light output element and the light source, and the area of the larger base for the entire array of light output elements remains constant. 12. The lighting system according to claim 11, characterized in that the area ratio decreases with the removal of the light-emitting element from the radiation source. 13. The lighting system according to item 12, wherein the area ratio decreases linearly with the removal of the light output element from the radiation source. 14. The lighting system according to claim 12, characterized in that the area ratio decreases non-linearly with the removal of the light-emitting element from the radiation source. 15. The lighting system according to claim 12, characterized in that the area ratio decreases stepwise with the removal of the light-emitting element from the radiation source.

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