KR880002124Y1 - Structure to fit the lighting collect edge of optical conductor onto the focus of the lens - Google Patents

Abstract

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Description

Structure for adjusting the light receiving end of the light conductor to the focus position of the lens

1 is an overall perspective view showing one example of a solar collector as an example of a device to which the present invention is applied.

2 is a configuration diagram for explaining an embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

1: Machine 2: Head

3: capwool 10: solar collector unit

11 lens group 12 solar direction sensor

13: support frame 14: rotating shaft

16 support arm 17 rotation axis

21 lens 22 light conductor

22a: light receiving end 23: protective support member

23a, 23b: adhesive injection hole 24: sleeve

25 support plate 25a hole in support plate

The present invention relates to a structure for precisely introducing light focused by a lens into a light conductor, and more particularly, to a structure for precisely positioning a light receiving end of a light conductor at a focal position of a lens.

1 is a schematic perspective view showing one example of a solar collector as an example of a device to which the present invention is applied, wherein (1) is a cylindrical gas part, and (2) is a dome-shaped head of a transparent body. The cap shroud 3 for a solar collector is comprised by this, and in the use state, the solar collector apparatus part 10 is accommodated in this cap shroud 3 like FIG. The photovoltaic collector unit 10 includes a plurality of lens groups 11 for focusing sunlight, a photovoltaic direction sensor 12 for detecting the direction of the sun, and a support frame integrally protecting and supporting them. (13), a first rotating shaft 14 for rotating the support frame 13, a supporting arm 16 and a supporting arm 16 for supporting the rotating shaft 14 freely. A second rotary shaft 17 or the like for rotating the shaft about an axis orthogonal to the first rotary shaft 14, and the solar direction sensor 12 detects the direction of the sun. The detection signal controls the first rotation axis 14 and the second rotation axis 17 so that the lens always faces the direction of the sun, and receives the sunlight focused by each lens at the focal position of the lens. It is introduced into an optical conductor cable (not shown) with the ends arranged, and the optical conductor cable Through the block it is to be transmitted to any desired place.

In the solar collector as described above, each lens group 11 is composed of a plurality of lenses 21 having a diameter of several centimeters, and the sunlight focused by each lens 21 is collected for each lens. Although it is supposed to be introduced into one optical conductor (optical fiber), in order to efficiently introduce the sunlight focused by each lens into the optical conductor, the light receiving end of the optical conductor must not be accurately positioned at the focal point of the lens. In particular, in the case of using a plurality of lenses as described above, it is very difficult to determine the position and to perform maintenance thereafter.

The present invention has been made in view of the above circumstances, and in particular, in the solar collector using a plurality of lenses as described above, a structure for accurately positioning the light receiving end of the light conductor at the focal position of the lens It is about.

2 is a configuration diagram for explaining an embodiment of the present invention, in which 21 is a lens for focusing sunlight, and 22 is a lens for introducing sunlight focused by the lens 21. It is an optical conductor (optical fiber), 23 is a protective support member for protecting this optical conductor 22, and 24 is this optical conductor 22 in the light receiving end side of the said optical conductor 22. As shown in FIG. And a sleeve for fixing the optical conductor 22 to the protective support member 23 while being integrally attached thereto, and 25 is a support plate for supporting the lens 21 and the protective support member 23 described above. The support plate 25 forms a hole 25a on the optical axis of the lens 21.

In addition, the protective support member 23 has a hole 23a for injecting an adhesive for adhering the protective support member 23 to the support plate 25 and the sleeve 24 described above. A hole 23b for injecting an adhesive for adhering to 23 is formed. In order to adjust the light receiving end 22a of the light conductor 22 to the focal position of the fence 21, first, the protective support member 23 is moved in a plane perpendicular to the paper surface, Align the center of the optical conductor 22, and in this state, the adhesive is injected into the adhesive injection hole 23a of the protective support member 23, and the protective support member 23 is adhesively fixed to the support plate 24, and then Move the light conductor 22 in the Z-axis direction to align the light receiving end surface 22a of the light conductor to the focal position of the lens 21, and in this state, the adhesive injection hole 23b of the protective support member 23; The adhesive is injected to fix the sleeve 24 to the protective support member 23.

In order to center the center of the lens 21 and the center of the photoconductor 22, when the lens 21 is a Fresnel lens, the photoconductor 22 is located at the center of the pattern of the Fresnel lens with the naked eye. In general, the light exit end side of the photoconductor 22 is introduced into a photometer or the like, and a parallel beam such as a laser beam is applied to the lens 21 in the direction of an arrow A, and the protective support member ( 23) is moved to a plane perpendicular to the surface of the paper as described above to find the position where the indication of the photometer is maximum, and injecting the adhesive into the hole 23a at the position, the protective support member 23 is supported by the support plate 25. The position in the Z-axis direction of the light conductor 22 is then determined.

Positioning of the optical conductor 23 in the Z-axis direction is performed as described above, after fixing the protective support member 23 to the support plate 25, and then moving the optical conductor 22 in the Z-axis direction. The position where the instruction is maximized is found, and the adhesive is injected into the hole 23b at the position to fix the sleeve 24 integrally formed with the optical conductor 22 to the protective support member 23.

As apparent from the above description, according to the present invention, the light receiving end surface of the light conductor can be accurately and reliably positioned at the focal point of the lens by a simple structure. In addition, after adhesion, each part is integrated integrally, and subsequent maintenance and management are unnecessary.

Claims (1)

A lens 21 for focusing light, an optical conductor 22 having a light receiving end 22a arranged at a focal position of the lens 21, and a hole coaxial with an optical axis of the lens 21. In the formation of the support plate 25 and the protective support member 23 for protecting the optical conductor 22 so as to be movable in the axial direction of the optical axis, a hole coaxial with the optical axis of the focusing lens 21. In the hole 25a of the support plate 25 forming the light guide, the protective support member 23 is provided with the support plate (to adjust the light receiving end 22a of the light conductor 22 to the focal position of the lens 21). 25) and injection holes (23a) and (23b) for injecting an adhesive liquid into the photoconductor (22), wherein the light receiving end of the photoconductor is adapted to the focal position of the lens.