RU2575320C2 - Light-emitting system for emission of scattered light - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention is referred to the light-emitting system, which comprises multitude of neighbouring light-emitting devices. Each light-emitting device comprises plate-like light waveguide having the front, rear and end surfaces. The light source is placed near the plate-like light waveguide in such position that scattered light enters the light waveguide and propagates in the main direction parallel to the front surface. The light waveguide comprises three-dimensional surface structure through the front, rear surfaces and one end surface. The controlled light waveguide is controlled against characteristics of output light.

EFFECT: improved uniformity of illumination due to reduced contrast effects as dark lines between bordering surfaces of light waveguides.

7 cl, 9 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a light emitting system comprising a plurality of light emitting devices arranged adjacent to one another, in which each of the plurality of light emitting devices comprises a plate-shaped light guide having a front surface, a rear surface and end surfaces, and one or more light sources arranged in this position with respect to the plurality of light-emitting devices that the emitted light enters into these light guides and propagates in the main propagation direction parallel to the front surfaces, wherein the fibers are configured to direct a portion of the propagating light of these front surfaces.

BACKGROUND

A conventional prior art plate-shaped light emitting device of the above type is called a light guide plate, and it has an end light source and a rear surface that is equipped with a light reflecting and reflective structure that redirects light outward from the front surface of the light guide plate. An example of such a light guide plate is disclosed in US patent application US-2010/0245718. The light source is located at the end surface of the fiber. Due to total internal reflection, light propagates in the main direction of propagation parallel to the front and rear surfaces, which are the main surfaces of this fiber. However, the rear surface of the fiber is equipped with a three-dimensional structure, and more precisely, wedge-shaped sections that prohibit total internal reflection and refract light outward from the front surface of the light guide plate. A reflective layer deposited on the rear surface of this fiber provides such a position that any backward-reflected light is reflected outward through the front surface of the light guide plate. In this prior art example, a light guide plate is used as a backlight device of liquid crystal television screens. This is the usual use of light guide plates, another example is the display of a mobile phone, and in a more general sense, any type of liquid crystal screen, large or small. A three-dimensional structure can also be applied to the front surface, still refracting light outward from the front surface. Examples of three-dimensional structures are bulges, dimples, or dots of white paint. Another type of application is for aesthetic purposes. In the latter case, light guide plates are often used collectively located adjacent to one another in order to form one large light emitting surface.

For many years, great efforts have been made in trying to remove as much light as possible through the front surface while minimizing light losses in other directions.

SUMMARY OF THE INVENTION

In accordance with a first aspect of the present invention, there is provided a light emitting system comprising a plurality of light emitting devices arranged adjacent to each other, in which each of the plurality of light emitting devices comprises a plate-like light guide having a front surface, a rear surface that are major surfaces, and end surfaces. The light-emitting system further comprises one or more light sources arranged in such a position with respect to the plurality of light-emitting devices that the light emitted by one or more light sources enters these plate-shaped light guides and propagates in a main propagation direction that is parallel to the front surfaces. Each of these plate-shaped waveguides is arranged to direct a portion of the propagating light from the front surface. At least a portion of each plate-shaped fiber has a three-dimensional surface structure configured to provide controlled light output through at least one of the end surfaces, where the controlled light output is controlled relative to the characteristics of the output light.

Thus, in accordance with the present invention, light, in addition to the front and rear surfaces, exits through at least one of the end surfaces. The light output is controlled in such a way that the predetermined desired characteristics of the light output, such as brightness, intensity or angular distribution, are achieved. By using the light-emitting devices in accordance with this invention and positioning them so that a light-emitting system is formed, the problem of contrast between adjacent light-emitting devices is solved. In other words, the dark lines between these light emitting devices are completely eliminated or reduced. In the prior art, all efforts were focused on minimizing losses at the ends, and did not even think about the problem of contrast on intermediate surfaces between plate-shaped light-emitting devices. There is nowhere to be disputed regarding an additional controlled light output through at least one end surface. There are no assumptions about taking advantage of the real possibility that part of the light travels to the end surface, while the front surface remains the main surface of the light output.

GB-2436611 uses a plate-like light guide and light exits through the end surfaces. However, light exits only or substantially through the end surfaces, while the main surfaces are coated with a reflective film. The goal is only to create separate light-emitting devices despite the fact that there is no mention of the problems arising from the joint installation of several light-emitting devices. In addition, there are no concepts regarding the implementation of a three-dimensional surface structure to obtain a controlled light output.

A controlled light output through at least one end surface of one light emitting device is used, for example, to provide illumination of surrounding elements, such as a wall or ceiling, thereby creating the desired light impression.

In embodiments of the light emitting system, a three-dimensional surface structure is embodied in the form of protrusions and (or) recesses, which have advantages in terms of controllability of refraction and reflection of light.

In one embodiment of the light emitting system, it is configured to create a lighting environment in the room in which it is used. By the lighting situation, we mean the impression of the light configuration in the room, which, for example, can be obtained by combining light directed to numerous parts of the room through the light output through the front surface, as well as through the end surface.

In one embodiment of the light emitting system, the controlled light output is arranged to illuminate the surroundings of this light emitting system, which is advantageous, for example, for applications in which this light emitting system is used to illuminate a wall or ceiling or any objects in a room.

In one embodiment of the light emitting system, one of the front, rear or end surfaces is equipped with a protrusion having a free end that is inclined with respect to this surface. The angle of inclination is selected so that the light exits through the inclined surface. This embodiment can be used to solve problems associated with light having a more specific orientation, in which at least part of the light output is provided through the inclined free end of this protrusion.

In accordance with one embodiment of the light emitting system, the light emitting devices are adjacent to one another. A typical implementation of this embodiment is the so-called “curtain” with a light input at the upper ends of the strips and a light output at their lower ends, as well as at their longitudinal ends or with combinations with a light output through the front surfaces of these strips.

These and other aspects, features and advantages of the present invention will be apparent and better understood with reference to the embodiments described below.

BRIEF DESCRIPTION OF THE DRAWINGS

Now the present invention will be described in more detail and with reference to the accompanying drawings, in which

figure 1 is a perspective view from above, showing a light emitting device that can be used in a light emitting system in accordance with the present invention;

FIG. 2 is a longitudinal sectional view of the embodiment shown in FIG. 1;

3 to 5 are longitudinal sectional views of parts of other light emitting devices that can be used in a light emitting system in accordance with the present invention;

6 is a top perspective view showing a light emitting device that can be used in a light emitting system in accordance with the present invention;

7 and 8 are front views showing other embodiments of a light emitting system; and

Fig.9 is a perspective view from above, showing a light-emitting device that can be used in a light-emitting system in accordance with the present invention.

DESCRIPTION OF PREFERRED EMBODIMENTS

Referring to FIGS. 1 and 2, the light emitting device 100 comprises a plate-like light guide 102, also called a light guide plate, and a light source 104. The optical fiber 102 is made of conventional material for optical fibers, such as glass or transparent plastic. The waveguide 102 is shaped like a plate and has a front surface 106 and an opposite rear surface 108, these surfaces forming the main surfaces of the fiber 102. In addition, the fiber has a first end surface 110, which is a short end surface, a second end surface 112, opposite the first the end surface 110, the third end surface 114, which is the surface of the long end, and the fourth end surface 116, opposite the third end surface. The light source 104 is adjacent to the first end surface 110 and emits light into the light guide 102 through the first end surface 110. The emitted light propagates essentially in the main propagation direction, which, as shown in FIG. 2, is parallel to the front surface 106. As is well known to specialists in this field of technology, due to a sufficiently small angle of incidence with respect to the front and rear surfaces 106, 108 and with respect to the third and fourth end surfaces 114, 116 of the light guide 102, a complete internal She reflected light. However, the light guide 102 is equipped with a three-dimensional surface structure consisting of protrusions, and more specifically, consisting of white dots of ink 120 deposited on the front surface 106. These dots of ink cause scattering of light rays and prevent total internal reflection. Some light rays will exit through the white paint, others will be reflected back and out from the back surface 108. But the light will also be scattered in other directions, thereby causing it to exit through one or more end surfaces 110, 112, 114, 116. By applying points of paint 120 with a special density, size and position control the characteristics of the light output through various end surfaces to achieve the desired light output. Generally speaking, when using white dots of paint, the light output through the front and rear surfaces 106, 108 will be almost Lambertian, therefore, the light guide 102 seems almost equally bright at any viewing angle. By providing a sufficiently high density of ink points 120 on the front surface 106, a sufficiently high and uniform light output through the front surface 106 is achieved while maintaining the desired light output also through the end surfaces. It should be noted that, if necessary, the light-emitting device may include a reflective layer deposited on the rear surface 108 of the light guide 102. It is possible that additional surfaces may be coated with a reflective layer, except for those that should be used for lighting purposes in a particular application.

According to a possible embodiment of the light emitting device 100, the front surface 106 is provided with cavities instead of protrusions or in combination with protrusions. For example, these depressions are scratches on the front surface 106. By using a laser to burn material from the front surface, these depressions can be applied most precisely so as to direct the scattered light as needed.

According to another embodiment of the light emitting device 300, a three-dimensional microstructure of the protrusions and / or depressions is applied to the front surface 304 of the light guide 302. The term "micro" defines that the individual elements of this structure are much smaller than the aforementioned points of paint or scratches. However, they have a corresponding effect. Many different types of regular predefined microstructures are suitable, such as protruding bulges 306, recesses 406, or wedge-shaped portions 506 (see FIG. 5). The possibilities for changing these structures are vast. They all have their own characteristics of light output in terms of the percentage of light output through each surface, as well as in terms of angular characteristics, that is, the direction of scattered or reflected light relative to the front surface. Other examples of three-dimensional structures are pyramidal depressions, which lead to the exit of light through all surfaces of the fiber.

According to another embodiment of the light emitting device 600, comprising a plate-like light guide 602 and a light source 604 located at the first end surface 606, one of the other surfaces is equipped with a protrusion having a free end that is inclined relative to this surface. More specifically, in the example case, a protrusion 610 is protruded from the second end surface 608 opposite the first end surface 606. This protrusion 610 is elongated and the width of the protrusion 610 is substantially smaller than the rest of the fiber 602. The free end of the protrusion 610 is inclined with respect to the second end surface 608, for example, under 45 °. This causes the light reaching this free end to be reflected by this inclined surface and exit through the side surface of the protrusion. Many other configurations of this protrusion are possible. For example, this protrusion may be made in the form of an arch. In this case, the light on the way to the surface of the inclined end will remain inside this protrusion for as long as the radius of curvature used is large.

The light emitting device of the present invention can be configured to be combined with large structures, which are referred to herein as light receiving systems. In accordance with one embodiment of such a light emitting system 700, it consists of several light emitting devices that are adjacent to one another and form a large rectangular light surface. These light-emitting devices are equipped with three-dimensional structures that in a controlled manner direct light to exit from the end surfaces, at least from those end surfaces that are adjacent to the end surfaces of other light-emitting devices 702. Thus, the boundary surfaces 704 between the light-emitting devices 702 “light up”, which removes or reduces contrast effects, such as dark lines, which would otherwise be visible between these light emitting devices 702.

In another embodiment of the light emitting system 800, it comprises a plurality of strips of light emitting devices 802 arranged side by side with one another and hanging down to form a curtain. Light sources 804 are located at the upper end surfaces of the strips 802, and light is emitted through three-dimensional surface structures through the front surface 806, as well as through the lower end surfaces 808. A light exit through the lower end surfaces 808 illuminates the floor and creates the illusion of sunlight shining through a window from behind the curtains. In addition, light can also be emitted outside through the side surfaces, moreover, with increased brightness in order to enhance the impression of sunlight behind curtain 800.

You can also perform a light-emitting device 900 having a surface structure, which is a combination of a refractive structure 902 of the back surface and a possible reflective layer 904 covering the back surface, as well as an additional structure 906 of the front surface.

It should be noted that the illustrations are significantly increased in terms of the thickness of the light emitting device. In reality, the usual thicknesses are in the range of millimeters, while the fiber often has a thickness of only about one millimeter.

Embodiments of a light emitting device and a light emitting system in accordance with the present invention have been described above as defined in the appended claims. They should be considered simply as non-limiting examples. As will be appreciated by those skilled in the art, numerous changes and alternative embodiments are possible within the scope of the present invention.

For example, as an alternative to the configuration of the light source at the end surface of the fiber in some applications in the fiber, one of the front or rear surfaces can be recessed and the light source can be inserted into the circular sector of the recess or into the entire circular recess.

As for the shape of the fiber, other basic shapes are possible besides the rectangular shape, such as polygonal or circular.

It should be noted that for the purposes of this application and, in particular, with regard to the claims, the word “comprising” does not exclude the presence of other elements or steps, and the singular does not exclude plurality, which is obvious to specialists in this areas of technology.

Claims (7)

1. A light emitting system containing
- a plurality of light-emitting devices located adjacent to each other, in which each of the many light-emitting devices contains a plate-like light guide (102) having front and rear surfaces (106, 108), which are the main surfaces, and end surfaces (110, 112, 114 , 116); and
- one or more light sources (104) located in such a position relative to the plurality of light-emitting devices that the emitted light enters these plate-shaped optical fibers (102) and propagates in the main propagation direction, which is parallel to the front surfaces (106);
in which at least a portion of each plate-shaped fiber (102) comprises a three-dimensional surface structure (118) configured to provide controlled light output through at least one of the front and rear surfaces (106, 108) and at least one of the end surfaces (110, 112, 114, 116), and
in which the controlled light output is controlled with respect to the characteristics of the output light. 2. The light emitting system according to claim 1, in which the light emitting device (802) are in the form of strips and are located side by side with one another. 3. The light emitting system according to claim 1 or 2, wherein for each of the light emitting devices, a controlled light output is provided through at least end surfaces (704) that are adjacent to the end surfaces of adjacent light emitting devices to reduce contrast at the ends of the light emitting devices. 4. The light emitting system according to claim 1, in which the three-dimensional surface structure (118) contains one or more protrusions (120). 5. The light emitting system according to claim 1, in which the three-dimensional surface structure (118) contains recesses (406). 6. The light emitting system according to claim 1, in which the light emitting system is configured to create a lighting environment in the room in which it is used. 7. The light emitting system according to claim 1, in which each of one or more light sources (104) is located at one of the end surfaces of the plate-like fiber (102) to emit light that enters this plate-shaped fiber (102) through this end surface.

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