KR940005969B1 - Light guidance system - Google Patents

Abstract

The apparatus for guiding the light flexibly with the optical fiber as well as controlling the light quantity arbitrarily includes a convex lens (L1) placed at the window side where the sun shines, another convex lens (L4) placed at the room side, concave lens (L2,L3) converting the refractive/parallel light to the parallel/refractive one, and a light pathway (P) guiding the parallel light.

Description

Parallel light induction device

1 is a schematic configuration diagram of the present invention.

2 is an exemplary operation state of the present invention.

* Explanation of symbols for main parts of the drawings

L ₁ , L ₂ , L ₃ , L ₄ : Lens P: Light transmitting device

The present invention relates to an induction apparatus for guiding outside parallel light, such as sunlight, to the inside of a building, a basement, or a vehicle. In general, in order to transfer parallel light away from a straight line in the direction of light, a reflector or a right angle prism (total reflection prism) must be used. Even in this case, the amount of refracted light is limited to the area of the reflector or the refractive surface of the right angle prism. In other words, the amount of light can not be transmitted and can not be out of the range of the refracted luminous straight line is difficult to use extremely limited.

The present invention can be adjusted arbitrarily without using a reflector or a right angle prism as described above, and in particular, the refractive path is not to be a straight line to increase the convenience and variety of use.

The convex lens L ₁ is applied to the parallel light portion of the external irradiation, and the concave light beam passing the convex lens L _{1 at the} position before the parallel light passes through the convex lens L ₁ and focuses again is concave so as to be parallel light. lens (L ₂₎ the location, and the negative lens (L ₂₎ back to the negative lens to form a cylindrical optics (P) at the rear end (L ₃₎ and joined one behind the negative lens (L ₃₎ is parallel light scattered rays by The convex lens L ₄ is formed at the rear of the concave lens L ₃ so as to be possible.

When explaining the operation principle, operation effect and industrial use of the present invention as described above, visible light irradiated from the outside (including reflected light reflected from an object) is convex when passing through the convex lens L ₁ as shown in FIG. The lens L ₁ is brought into focus (not shown). In this case, when the concave lens L ₂ is positioned near the focal point, the visible light is changed into parallel light after passing through the concave lens L ₂ . Of course, the light rays made of parallel light are very visible rays because they are the entire visible light passing through the convex lens L ₁ .

The concentrated light group passes through the light-transmitting device P composed of an optical fiber through which the light beams can pass, and then reaches the concave lens L ₃ again, and the parallel light becomes a focal point (not shown) of the concave lens L ₃ . Spread outward to the center and pass through the convex lens (L ₄ ) installed behind it, and passes through the state changed to parallel light again.

Therefore, the device of the present invention, for example, if the convex lens (L ₁ ) is installed in the window irradiated with sunlight and the convex lens (L ₄ ) is installed on the wall of the basement, the convex lens (L ₄ ) installed in the basement in the window The light emitted from the installed convex lens (L ₁ ) is emitted to illuminate the same light as the sunlight in the basement, and to be able to take a look at the scenery outside, especially the light transmitting device (P) to the optical fiber, etc. Since the optical fiber can be bent at an arbitrary angle during construction, it can be used even when the concave lens L ₂ and the concave lens L ₃ are not straight lines, and the present invention provides a convex lens L ₁ . It can be installed at any point where sunlight is irradiated, and the convex lens (L ₄ ) where illumination light is emitted can be freely installed at any point where sunlight does not reach, so it can be widely used in a construction requiring sunlight. Of course, by installing the convex lens (L ₁ ) in the rear of the car, the driver can sit and check the rear clearly, and the inside of the curved state such as human organs can be seen from the outside (in this case, the convex lens (L) ₁ ) A separate light emitting device may be required for the shear, so that it can be widely applied to the medical field.

Therefore, the present invention applying the optical theory has a very useful advantage in industry.

Claims (1)

Concave lens provided with convex lens (L ₁ ) in the outside-illuminated parallel light part and refracted light passing through convex lens (L ₁ ) at the position before the parallel light is focused to pass through the convex lens (L ₁ ). (L ₂₎ the location, and the negative lens (L ₂₎ cylindrical optics back to the negative lens forming the (P) at the rear end (L ₃₎ and joined one after the dispersed light beam by a concave lens (L ₃₎ parallel to the light Parallel light guide device comprising a convex lens (L ₄ ) in the rear of the concave lens (L ₃ ) so that it can be.