KR880002970Y1 - Optical radiator - Google Patents

Abstract

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Description

Optical radiator

1 is a partial front cross-sectional view for explaining an embodiment of an optical radiator according to the present invention.

2 is a partial side cross-sectional view of FIG.

3 is a view showing the relationship between the rotation angle of the transparent plate and the reflection of light in the present invention.

4 is a view showing an example of an elliptical transparent plate in the present invention.

5 is an exploded view for explaining an example in the case where a transparent plate or the like is arranged in a cylindrical body in the present invention.

* Explanation of symbols for the main parts of the drawings

1: optical conductor cable 10: optical radiator

10a: reflective surface 10 ': hole

10 ": slit 11: cylindrical body

12,12 ', 12 ": Rotation axis 13: Transparent body

Half mirror or reflector 13 ₁ ~ 13 ₇ : Transparent plate

15: auxiliary plate 15 ': hole

The present invention relates to an optical radiator for effectively diffusing and radiating light transmitted through an optical conductor cable to the outside of the optical conductor cable.

In recent years, in the era of energy conservation, research and development has been actively conducted on the effective use of solar energy in each area. However, the most effective use of solar energy is solar energy such as thermal energy or electric energy. It is to use as light energy without converting into form energy.

Based on this point of view, the present applicant focuses the sunlight using a lens or the like and introduces it into the optical conductor cable, which is transmitted to any desired place through the optical conductor cable, and the light is emitted from the optical conductor cable at this place. Various proposals have been made for the use of light and other uses, such as photosynthetic light sources in plant cultivation.

In the case where the solar energy is used for cultivation of plants by using the above-described solar energy, light transmitted in the optical conductor cable has directivity, and the end of the optical conductor cable is cut off from this cutting place. In the case of emitting light, the angle of radiation is usually about 46 ° in the case of focused light, which is very narrow and thus only at the end of the optical conductor cable in the case of providing sunlight for use as described above. It is impossible to perform the light illumination as desired by cutting | disconnecting and making it emit light at this cutting place.

Therefore, the present applicant has made various proposals for the optical radiator which can effectively diffuse the light transmitted through the optical conductor cable and irradiate it to the desired range, but the present invention is also part of the invention.

An object of the present invention is to provide an optical radiator that is capable of effectively emitting solar light or artificial light transmitted through an optical conductor cable in this optical conductor cable, which is suitable for planting plants.

An embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a front view illustrating an embodiment of an optical radiator according to the present invention, and FIG. 2 is a side view in which the optical radiator shown in FIG. 1 is rotated by 90 ° with respect to its long axis. An artificial light is introduced and transmitted to the optical conductor cable, and 10 is an optical radiator according to the present invention, and the optical radiator 10 is a cylindrical body 11 of a transparent body and the cylindrical body in the cylindrical body 11. It consists of a transparent plate 13 and the like arranged so that rotational movement is arranged in relation to the axis 12 perpendicular to the long axis of the transparent axis, the transparent plate 13 is rotated at an arbitrary angle about the axis 12 I can do it.

Therefore, while the light emitted from the optical conductor cable 1 into the optical radiator 10 proceeds in the direction of the arrow A, a part thereof is reflected by this transparent plate 13 and a part of the rest is The light transmitted through the transparent plate 13 and transmitted through the transparent plate is reflected by the subsequent transparent plate, and the reflected light is transmitted through the cylindrical body 11 of the transparent body and emitted to the outside.

Each transparent plate 13 can rotate at any angle about the axis 12 as shown in the figure, thereby adjusting the amount of light reflected by each transparent plate 13, and thus, light The light distribution characteristic along the axial direction of this optical radiator 10 of the light emitted from the radiator 10 can be arbitrarily adjusted.

That is, in the city, an example in which _seven transparent plates 13 ₁ to 13 _{7 are} disposed in the cylindrical body 11 is shown. However, as indicated by 13 ₁ to 13 ₆ , the transparent plate is a cylindrical body 11. When it is parallel to the light, the light travels in the cylindrical body 11 in the direction of the arrow A, and when inclined as indicated by 13 ₇ , a part of it is reflected by this transparent plate and the cylinder Emitted from the sieve 11, the amount and the direction of release vary depending on the rotation angle of the transparent plate.

For example, when the optical radiator is used as a light source for photosynthesis in the cultivation of plants, while the plants are small, the upper transparent plates 13 ₁ to 13 ₆ are vertical as shown in the figure. When inclined to the transparent plate (13, ₇₎ of the lower, cylindrical body in the light introduced into the 11's in this my cylindrical body proceeds through the transparent plate (13 ₁ to 13 ₆₎ and the transparent plate (13, ₇₎ It is reflected and emitted out of the cylinder 11 to irradiate the plant.

If the inclined upper reflector is inclined as the plant grows larger, light can always be supplied from above the plant, and a part of the light passing through the inclined transparent plate part is supplied downward, and the light is lowered from the inclined projecting plate. It is reflected and emitted out of the cylinder, but most of the light is reflected from the inclined transparent plate on the upper side, so that a large amount of light is supplied above the plant, and a small amount of light is supplied below, thus cultivating the most efficient plant. You can do it.

3 is a diagram showing the relationship between the inclination angle θ (here, referred to as an eccentric angle on the vertical axis) of the transparent plate and the reflected light. As described above, when θ is 0, most of the light passes through the interval d of the transparent plate portion. As the light is transmitted downward, the light reaching the transparent plate increases as θ increases, and the light is reflected in the substantially horizontal direction when the reflection direction moves upward and the inclination angle θ becomes 45 °.

And when the inclination angle is 45 ° or more, the light reflected by the transparent plate becomes the light from upward to upward, but in the case of growing plants, it is in vain to let the light from downward be insignificant, There is no need to tilt it.

On the other hand, if the transparent plate is a disk having the same diameter as the inner diameter of the cylindrical body, when the transparent plate is inclined at 45 °, there is still a considerable gap between the transparent plate and the inner wall of the cylindrical body. The light is transmitted downward, so that less light is transmitted downward, so that the transparent plate is formed of an ellipse, and as shown in FIG. Only light passing through this elliptic transparent plate is transmitted, so that light transmitted downward can be reduced.

In addition, when it is not necessary to emit light from the lower end of the cylindrical body 11, it is also possible to form the lower end surface of this cylindrical body 11 in the reflecting surface 10a. The light reaching the bottom surface is reflected from the reflecting surface 10a and directed in the direction of arrow B, and is reflected from the back side of the inclined transparent plate in between, and is emitted in the reverse direction to the plant at the rear of the optical radiator. Light is emitted.

In addition, it is also possible to arrange | position a double-sided reflecting plate instead of the lowermost transparent plate, In that case, if this reflecting plate is comprised by ellipse as mentioned above, the space | interval between this reflecting plate and a cylindrical body can be made small, Through this gap, the light leaking downward can be minimized, and the light introduced into the cylinder can be effectively used.

In addition, it is also possible to rotate the transparent plate and the reflecting plate described above to reverse the direction of the inclination. In this way, light can be irradiated to the plant behind the optical radiator.

In addition, it is also possible to change the direction of the rotation axis of the above-mentioned transparent plate respectively, and in this way, light can be emitted over the whole periphery of an optical radiator.

It is also possible to use a half mirror or a double-sided reflecting plate or a combination thereof instead of the above-mentioned transparent plate. In the case of a double-sided reflecting plate, the inclination angle is preferably up to 45 °, in which case the rotational angle of this double-sided reflecting plate is The sum totals 90 degrees.

In the case of using a combination of a double side reflecting plate and a transparent plate or a half mirror, the double side reflecting plate may be arranged to be arranged at one or a plurality of intervals of the transparent plate or the half mirror, and in this case, when the double side reflecting plate is inclined at 45 °. Since the light transmitted from the cylinder is reflected by the reflector and is emitted out of the cylinder, increasing the inclination of the reflector as the plant grows increases the lowest level of light emitted from the optical radiator. You can adjust the height to match.

In addition, although the case where each transparent plate and the half-mirror double-sided reflecting plate were flat was demonstrated, it can be easily understood that these may be formed in arc shape, and may be made to reflect to a convex surface or concave surface.

5 is a view for explaining an example in which the transparent plate, the half mirror, or the double-sided reflecting plate as described above is arranged in the cylindrical body 11, (A) is a partial view of the cylindrical body 11; , (B) is a front view of the circular transparent plate 13, and (C) has a hole 10 'into which the rotating shaft 12 of the elliptical reflector 13 is inserted, and is opposed to the hole 10'. In the side wall, a slit 10 "having a length and a width into which the transparent plate, the half mirror, or the double-sided reflecting plate 13 fits is drilled, and the length and the thickness thereof are the lengths of the transparent plate, the half mirror, or the double-sided reflecting plate. It is longer and wider than its thickness.

Therefore, the transparent plate or the like enters into the cylindrical body through this slit 10 ", and one rotating shaft 12 'fits into the hole 10'.

The other rotary shaft 12 "protrudes from the slit 10", but the rotary shaft 12 "is, for example, an auxiliary plate having a hole 15 'into which the rotary shaft 12" is fitted. The hole 15 'is inserted into the hole 15'. Then, the hole 15 'of the auxiliary plate 15 is positioned to be horizontal to the hole 10', and the auxiliary plate 15 is cylindrical. It is bonded to the outer peripheral surface of 10 and fixed.

In addition, when a transparent plate etc. are arc-shaped, it is natural, but the said slit 10 "is also formed in arc shape.

As apparent from the above description, according to the present invention, it is possible to provide an optical radiator which can freely adjust the irradiated place and can diffuse and emit light with high efficiency.

Claims (1)

The cylindrical body 11 of a transparent body and the cylindrical body 11 are arrange | positioned so that rotational movement is possible centering on the axis | shaft orthogonal to the axis | shaft of this cylindrical body 11, and also the axial direction of the said cylindrical body 11 is carried out. Therefore, in the optical radiator which consists of the several transparent plate 13 arrange | positioned, at least one inner end surface of the said cylindrical body 11 is formed with the reflecting surface 10a, and the said transparent plate 13 The direction of the rotation axis of each is different, and at least one of the transparent plate 13 is an optical radiator, characterized in that the reflecting plate.