KR880000117B1 - Optical radiator - Google Patents

Abstract

A light radiator comprises two cylindrical optical rods (1,2) which end parts are engraved with various types, e.g. circular cone. Each top of the engraved form has a flat plane (1a, 2a). A part of light rays guided into the rod (1) are passed through the plane (2a), but the rest of them are reflected on the slope surface (2b) to radiate the light rays with broad radiating angle. The light radiating angle can be varied by changing the sloping angle of (2b).

Description

Optical radiator

1 to 8 are schematic configuration diagrams for explaining the embodiments of the present invention, respectively.

* Explanation of symbols for main parts of the drawings

1, 2 ': optical conductor 3': transparent member

BACKGROUND OF THE INVENTION Field of the Invention The present invention relates to an optical radiator for radiating light transmitted through an optical conductor cable or the like effectively to the outside of the optical conductor cable to emit light, and in particular, at least two lights connected longitudinally with respect to the direction. The inclined surface is provided in the surface connected with this type | mold with a conductor, and light is diffused and radiated in this inclined surface.

In recent years, in the age of sexual energy, active research and development has been conducted on the effective use of solar energy in various fields.However, in order to use solar energy most effectively, solar energy is used as heat energy or electric energy. It does not convert to other forms of energy, but is used as it is as light energy.

Based on this point of view, the present applicant introduces the focused light into the optical conductor cable by using a lens or the like, transmits it to the desired place through the optical conductor cable, and the light in the optical conductor cable at this place. There have already been various proposals for providing lighting to emit light.

However, when using solar energy as described above, the light transmitted in the optical conductor cable has directivity, and when the end of the optical conductor cable is cut off to emit light at this cut portion Since the radiation angle is very narrow, usually about 46 ° in the case of focused light, if the user wants to illuminate the room uniformly by using sunlight for lighting in the room, the end of the optical conductor cable is simply cut off. In other words, it is impossible to achieve satisfactory lighting by causing light to be emitted from this cut portion.

Therefore, the present applicant has made various proposals for the optical radiator which can diffuse the light transmitted in the optical conductor cable effectively and can illuminate a wide range uniformly.

It is made as part of such a proposal of the present invention, and is basically provided with at least two optical conductors connected longitudinally with respect to the traveling direction of light, and forms an inclined surface on the longitudinally connected surface, and through the two inclined surfaces. The light transmitted through the light conductor is diffused to the outside of the light conductor to radiate.

1 is a schematic exploded perspective view for explaining an embodiment of an optical redirector according to the present invention, in which (1) is the first optical conductor, and (2) is longitudinally connected to the first optical conductor. The second optical conductor to be connected, the surface of the first optical conductor 1 is the plane 1a, and the surface of the second optical conductor 2 in the surface of the side connected longitudinally as in the illustrated example Silver is formed in the plane 2a and the inclined surface 2b.

Therefore, when these optical conductors are connected longitudinally, the light transmitted in the direction of the arrow in the optical conductor 1 is partially transmitted through the planar portion 2a of the optical conductor 2 into the conductive material 2. Some of the remaining light is reflected in the direction of the arrow on the inclined surface 2b so that it is effectively diffused and emitted to the outside of the light conductor, and a part of the light is transmitted into the light conductor 2.

Alternatively, by changing the inclination angle 0 of the inclined plane, the direction of light emitted from the light conductor can be changed. When 0 = 45 °, in the case of parallel light, the light can be emitted in a direction perpendicular to the light conductor. In the case of focused light, it can be emitted with a fairly wide angle.

In addition, by changing the area ratio between the plane 2a and the inclined surface 2b, it is possible to change the ratio of the amount of light emitted and the amount of light transmitted to the light conductor of the next stage.

FIG. 2 is a schematic exploded perspective view for explaining another embodiment of the present invention. In this embodiment, as shown in the drawing, the second light conductor 2 is disposed on the surface of the focusing end side of the first light conductor 1. The plane 1a and the inclined surface 1b which are mutually compensated with respect to the plane 2a and the inclined surface 2b of the () are formed, and are transmitted from the first optical conductor 1 through the planes 1a and 2a. A part of the light is transmitted to the second light conductor 2 and at the same time, the inclined surfaces 1b and 2b reflect a part of the remaining light to be emitted outside the light conductor, and then the remaining light is emitted again. In this case, when the first optical conductor 1 and the second optical conductor 2 are connected longitudinally, the center of the unit is very convenient.

In this case, if the connection surface of the first optical conductor 1 and the connection surface of the second optical conductor 2 are completely compensated for each other, reflection on the inclined surface is eliminated. It is better to form a translucent film on the inclined surface of the photoconductor, but it is generally good to make the inclined surface of the first photoconductor and the inclined surface of the second photoconductor to be in close proximity to each other. There is a gap between the inclined planes of the conductors, so that some of the light transmitted from this inclined plane can be reflected and emitted.

FIG. 3 is a schematic exploded perspective view for explaining another embodiment of the present invention, which shows the inclined surface of the second optical conductor ₂ as two sides of (2b ₁ ) (2b ₂ ) as shown. And diffuses and emits the light transmitted in the photoconductor 1 in two directions.

4 is a schematic exploded perspective view for explaining another embodiment of the present invention, and this embodiment shows the second optical conductor 2 on the side of the connection end side of the first optical conductor 1 as shown. The inclined surfaces 1b ₁ and 1b _{2 are} formed to engage the inclined surfaces with each other so as to compensate each other with the inclined surfaces 2b ₁ and 2b ₂ . The connection between the conductor 1 and the second optical conductor 2 becomes easy.

In addition, in the embodiments shown in FIGS. 3 and 4, the case where the inclined surfaces 2b ₁ and 2b ₂ have the same area has been described. However, if necessary, one side is made wider and the other side is made narrower. It is also possible to emit a large amount of light on the other side and a small amount on the other side, and in the extreme case, it is also possible to emit only one side as indicated by arrow (A) of FIG. It is also possible to transmit light in the direction of the second photoconductor 2, as indicated by arrow B.

6 is a schematic exploded perspective view for explaining another embodiment of the present invention, wherein (1) is a first optical conductor, (2) is a second optical conductor, and (3) is a transparent member. In this embodiment, as shown in the drawing, the grooves 2c are provided on one or both contact surfaces (the surfaces of the optical conductors 2 in the drawing) of either the optical conductors 1 and 2, and the two grooves 2c. The transparent member 3 can be inserted into the inserting material.

This transparent member 3 formed the plane 3a and the inclined surface 3b as shown in the drawing, so in this embodiment, a part of the light transmitted in the direction of the light conductor 1 is used for the plane portion 3a. Is transmitted to the light conductor 2, and a part of the remaining light is reflected from the inclined surface 3b to be emitted to the outside of the light conductor, and a part of the rest is transmitted to the light conductor 2.

In this embodiment, the amount of light emitted from the inclined surface 3b can be arbitrarily set by adjusting the depth at which the transparent member 3 is inserted.

In addition, in this embodiment, the light in the direction of the first optical conductor 1 is emitted as part of it is reflected in the direction of the arrow A on the inclined surface 3b of the transparent member 3, and the second optical conductor Part of the light in the direction of (2) is emitted by being reflected in the direction of the arrow (B) in the inclined portion (3b) of the transparent member 3, according to this embodiment, no matter in which direction It is a good thing.

FIG. 7 is a view showing another embodiment of the transparent member 3 shown in FIG. 6, and the transparent member 3 has formed two inclined surfaces 3b ₁ and 3b _{2 as} shown. Therefore, the ratio of light can be changed by adjusting the degree of insertion or reflecting the light transmitted from the direction of the optical conductor 1 in two directions as indicated by the arrow A. In the case of can be emitted only in one direction.

In the case of this embodiment only, the light transmitted in the direction of the second light conductor ₂ is reflected by the two inclined surfaces 3b ₁ and 3b ₂ as indicated by the arrow B and returned to the original direction. When the transparent member is used, light in the direction of the light conductor 2 cannot be emitted.

In addition, although the example which used two optical conductors with respect to each Example of this invention was demonstrated above, this invention is not limited to the said Example, For example, the connection surface containing the inclined surface as mentioned above is provided. It is also possible to connect various types, and in such a case, the transparent member 3 shown in FIG. 7 is returned as shown in FIG. 8 so that the light of the optical conductor n at the final stage can be returned to the original direction. It is also possible to release more effectively.

Only in this case, the planar portion 3a of the transparent member 3 needs to be a reflecting surface. As apparent from the above description, according to the present invention, the light transmitted through the light conductor can be effectively diffused to the outside of the light conductor and emitted by the simple configuration.

Claims (4)

At least two optical conductors connected longitudinally with respect to the propagation direction of light, wherein the surface of one optical conductor is flat and the surface of the other optical conductor is inclined. Light radiator, characterized in that the surface containing. An optical radiator comprising at least two optical conductors connected longitudinally with respect to the traveling direction of light, wherein the surfaces of the positive conductors are inclined surfaces that compensate for each other on the surfaces connected by the species. At least two optical conductors connected longitudinally with respect to the propagation direction of light, wherein the grooves are connected to each other in the longitudinal direction to form grooves in at least one optical conductor surface, and the grooves in the axial direction of the optical conductor. A light lattice, characterized in that a transparent body forming an inclined surface with respect to the surface is inserted in an insertable manner. The optical radiator of claim 3, wherein the transparent body is formed after the inclined surface to form a horizontal plane orthogonal to the axis of the light conductor.

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