KR101015440B1 - Transmission device of solar light - Google Patents

Abstract

The present invention relates to a solar transmission apparatus, according to an aspect of the present invention is used in a solar transmission system that the concentrated solar light is transmitted through the optical fiber to be used as an energy source, one end is supported and the other end is extended outward A condensing body having an arm and a plurality of mirror assemblies which are provided in plurality and individually coupled to an upper side of the arm and are configured to reflect sunlight and collect in one direction, the mirror assembly reflects the sunlight to the upper side. Reflecting portion is provided, there is provided a solar transmission apparatus characterized in that the coupling portion is provided on the lower side coupled to the ball joint form.

Solar light, condensing, mirror assembly, latent heat tank

Description

Transmission device of solar light

The present invention relates to a solar transmission apparatus, and more particularly, to a solar transmission apparatus capable of increasing the condensing efficiency, providing a condensing device that is easy to maintain, and efficiently utilizing the condensed sunlight.

The solar condensing system refers to a system that introduces insufficient natural light using various equipment in a room where natural light is difficult to enter. It is a renewable energy system using solar light that emits enormous energy. It is an application technology that can prevent global warming by making fossil fuel use and make an absolute contribution to energy saving.

The solar transmission system is configured to first collect the sunlight, then transmit the concentrated sunlight through the optical fiber, and use the transmitted sunlight to be used for lighting. The light collecting device used in the light collecting system is controlled by a light sensor to collect sunlight most efficiently, and is configured to automatically track the movement of the sun.

The sunlight collected in the optical fiber can be transported far away through the inside of the optical fiber. In general, the optical fiber is used in the form of an optical cable tied to seven cores. The optical cable is used to have a diameter of about 9mm, and can be freely wired inside the building, so that solar light can be introduced anywhere.

Although the solar light condensing system is a technology that uses eco-friendly renewable energy, the possibility of power generation is very high, but there are still many problems to be improved. Conventional mining systems using natural light are large-scale condensing systems installed on the roof or walls of buildings. Such large-scale condensing systems are expensive, extremely low in efficiency compared to installation costs and scale, and difficult to control. There is this. In addition, the light collecting device used in such a conventional light collecting system is difficult to manufacture, and it is expensive to maintain the device. In addition, there is a limit in efficient mining and there is a problem that the proper utilization of energy is not made.

The present invention has been made to solve the problems described above, an embodiment of the present invention is to provide a mining device that can increase the mining efficiency and easy maintenance, and that the efficient use of the mined sunlight Related.

One preferred embodiment of the present invention is used in a solar transmission system in which the concentrated solar light is transmitted through an optical fiber to be used as an energy source, and a condensing body having an arm that is supported at one end and extends outward, Is provided is coupled to the upper side of the arm individually, and includes a plurality of mirror assembly configured to reflect the sunlight to collect in one direction, the mirror assembly is provided with a reflector for reflecting the sunlight on the upper side, the arm and ball Provided is a solar transmission device, characterized in that the coupling portion is provided to be coupled in the form of a joint.

According to an embodiment of the present invention as described above, first, by using a plurality of mirror assemblies made separately in order to reflect the sunlight to collect into the optical fiber, each of the mirror assemblies can be individually adjusted to the solar light to the optical fiber Can be efficiently concentrated.

Second, the mirror assembly is coupled to the condensing body in the form of a ball joint, so that the mirror assembly can be easily adjusted, and only a part of the mirror assembly can be replaced, thereby reducing maintenance costs.

Third, it is possible to effectively use the sunlight by storing the heat obtained from the sunlight through the latent heat tank and using it for heating.

1 is a schematic diagram showing a solar transmission apparatus according to an embodiment of the present invention.

The solar transmission apparatus 1 according to the preferred embodiment of the present invention is used in a solar transmission system in which concentrated sunlight is transmitted through an optical fiber 100 and used as an energy source, one end of which is supported and the other end of which is directed to the outside. A condensing body 10 having an arm 11 formed to extend; And a plurality of mirror assemblies 20 which are provided in plural and are individually coupled to the upper side of the arm 11 and are configured to reflect sunlight and collect in one direction.

Sun light collected through the mirror assembly 20 is collected through the optical fiber 100 provided above the center of the arm 11.

The solar transmission apparatus 1 of the present invention is a device used in a solar transmission system used to use solar energy as an alternative energy. The solar transmission apparatus 1 may concentrate solar energy and be used for lighting, heating, etc. in a building. In particular, the lighting system using solar light can provide a comfortable and healthy light environment that is difficult to obtain by artificial lighting, and can be used for all lighting facilities such as offices, commercial buildings, houses, museums, exhibition halls, and the like.

In transmitting the collected solar light, the concentrated high-density light can be transmitted through the medium of the glass fiber.

The condensing body 10 includes the arm 11 having one end supported and the other end extended outward. It is necessary to configure the solar light to be concentrated at a high density prior to the transmission of the sunlight, and the condensing body 10 together with the mirror assembly 20 is used here.

The arm 11 may be supported by the mirror assembly 20, and may be formed in various forms to efficiently collect light through the mirror assembly 20, and may be rotatable at various angles. The arm 11 extends from the center to the outside, and the mirror assembly 20 is coupled to the entire arm 11. The arm 11 may be integrally formed, but preferably, a plurality of arms 11 may be arranged in various forms. Each arm 11 is formed to form the same plane, the shape on the top view may be formed in the shape of a circle, cross, polygon, and the like.

The mirror assembly 20 is provided in plurality, and is individually coupled to the upper side of the arm (11). A reflection portion is formed on the upper side of the arm 11 to be described later, and the incident sunlight is reflected to concentrate on the condenser lens 30. The mirror assembly 20 is not coupled in a fixed form on the upper side of the arm 11, but is coupled in a rotatable form so as to adjust a reflection angle of sunlight.

In the solar light transmitting apparatus 1 of the present invention, in order to reflect sunlight and concentrate the light into the optical fiber 100, rather than using a single integrally formed reflector, the mirror is formed in a relatively small size and individually coupled. By using the assembly 20, the concentration of sunlight can be made more easily, and the manufacturing cost by the mold can be greatly reduced compared to the integral reflector, and it is easy to change and can be replaced individually. The cost of maintenance can be reduced.

The optical fiber 100 is formed at a point spaced upward from the center of the condensing body 10.

2 (a) and 2 (b) are a cross-sectional view and a perspective view showing a mirror assembly used in the solar transmission apparatus according to another embodiment of the present invention.

In the solar transmission apparatus 1 according to the preferred embodiment of the present invention, the mirror assembly 20 is provided with a reflector 21 reflecting sunlight on the upper side, and the arm 11 and the ball on the lower side. The coupling part 22 is coupled to form a joint is provided.

The mirror assembly 20 is coupled to the upper surface of the condensing body 10 and reflects sunlight to gather into the optical fiber 100. The reflector 21 reflects sunlight on the upper side and the lower side. The coupling part 22 coupled to the arm 11 constituting the condensing body 10 is formed.

The reflector 21 is formed in a wide plate shape as a whole, and as described later on the upper side of the reflector 21, aluminum is coated by vapor deposition so that sunlight is reflected.

The coupling portion 22 is a portion that is coupled to the arm 11, the arm 11 is coupled in the form of a ball joint. The coupling part 22 is formed in the shape of a ball as shown in FIGS. 2 (a) and 2 (b), and the arm 11 having a groove formed so that the coupling part 22 can be inserted snugly. ) Can be combined. Alternatively, the arm 11 and the coupling portion 22 may be formed by changing the shape of each other. Hereinafter, a description will be given based on the former form, that is, the coupling portion 22 is formed in a ball shape.

The coupling part 22 is formed in a ball shape, and is formed downward from the reflecting part 21. The coupling part 22 is formed at the center of the mirror assembly 20, and is formed in the shape of a complete sphere except for the part connected to the reflecting part 21.

The receiving portion 19 is formed on the arm 11 to allow the coupling portion 22 to be inserted and fixed. The receiving portion 19 is formed so that the inner surface is in close contact with the coupling portion 22. The accommodating portion 19 is formed to a depth enough to cover the coupling portion 22 to a degree slightly higher than the length from the bottom to the center when the coupling portion 22 is inserted therein. In addition, the accommodating portion 19 is not formed in a continuous edge of the edge, it is made of a cut and divided form. Accordingly, when the coupling portion 22 is inserted into or withdrawn from the accommodation portion 19, the accommodation portion 19 can be easily elastically deformed, and the mirror assembly 20 is the arm 11. It is easily combined and separated at.

In the solar transmission apparatus 1 according to the preferred embodiment of the present invention, the reflector 21 is formed by depositing aluminum in a concave shape on its upper side.

In the mirror assembly 20, the reflector 21 has a shape in which a central portion thereof is slightly concave. The reflector 21 is formed by depositing aluminum on the upper surface.

The reflector 21 may be formed in a concave shape to increase the degree of condensing of the reflected sunlight and to obtain a high density of sunlight. An upper surface of the reflector 21 is formed with a coating surface by aluminum deposition to reflect sunlight. As will be described later, the uv epoxy is first applied to the reflector 21, and aluminum is deposited thereon.

Meanwhile, the aluminum deposition is performed in a vacuum state to increase the reflectance. According to the degree of vacuum, the reflectance of the coating film on which aluminum deposition is made is increased, and the deposition is performed at a high degree of vacuum for excellent reflection characteristics.

3 is a view illustrating a process of forming a mirror assembly used in the solar transmission apparatus according to another embodiment of the present invention.

In the solar transmission apparatus 1 according to the preferred embodiment of the present invention, the mirror assembly 20 has a body forming step (s1) of forming a body of the mirror assembly 20 by injection molding, and an upper surface thereof is curved. Mold processing step (s2) for processing the mold formed by the, epoxy coating step (s3) for applying uv epoxy on the mold, epoxy curing step (s4) for curing the uv epoxy on the body formed in the body forming step (s1) ), A separation step (s5) for separating the mold, and a deposition step (s6) for depositing aluminum on the upper surface of the uv epoxy.

The mirror assembly 20 is formed through the body forming step (s1), mold processing step (s2), epoxy coating step (s3), epoxy curing step (s4), separation step (s5), and deposition step (s6). do.

The body forming step (s1) is a step for forming the overall shape of the head assembly, so that the overall shape including the coupling portion 22 is formed by injection molding.

In the mold processing step (s2) it is to determine the degree of curvature of the uv epoxy applied to the upper surface of the mirror assembly 20. The upper side surface of the mold (c) used in the mold processing step (s2) is protruded convex upward, the reflection portion 21 of the mirror assembly 20 is formed corresponding to the shape of the protruding surface. Therefore, by adjusting the degree of curvature of the upper side of the mold (c) used in the mold processing step (s2) it is possible to change the curvature of the reflecting portion (21). The degree of curvature of the reflector 21 needs to be changed and used according to the size, use, etc. of the light concentrating device used. In this case, the reflector 21 does not change the entire mirror assembly 20. It can be replaced by adjusting the curvature of the epoxy to be applied to, thus, can be easily changed and can be expected to reduce the cost.

In the epoxy coating step (s3), uv epoxy is applied to the upper surface of the mold (c) formed in the mold processing step (s2), and then the epoxy curing step (s4).

In the epoxy curing step (s4), the injection molding formed in the body forming step (s1) is bonded to the upper side of the applied uv epoxy so that the surface corresponding to the reflecting portion is downward to cure. When curing is completed after a certain time, the injection is separated from the mold (c).

In the deposition step (s6), aluminum deposition is performed on the upper surface of the uv epoxy coating, and the deposition is performed in a vacuum state as described above.

4 (a) is a front view showing a light collecting body used in the solar transmission apparatus according to another embodiment of the present invention, Figures 4 (b) and 4 (c) are respectively shown in Figure 4 (a) Is a side view and a state of use of the condensing body.

In the solar light transmitting apparatus 1 according to the preferred embodiment of the present invention, the condensing body 10 includes a base 12 forming a bottom, a shaft 13 straightly formed upward from the base 12, and A first motor 14 coupled to an upper side of the base 12 to axially rotate the shaft 13, and an arm support rotatably coupled to an upper end of the shaft 13 to support the arm 11. A frame 15 coupled to the shaft 13 or the arm support frame 15 such that the arm support frame 15 is rotatable about an axis perpendicular to the longitudinal direction of the shaft 13. It consists of two motors (16).

The condensing body 10 is a configuration for condensing in the solar transmission device 1 of the present invention, the arm 11 constitutes a part. The condensing body 10 is made so that the overall direction is changeable according to the position of the sun to enable efficient condensing.

The base 12 forms a lower end of the condensing body 10 and supports the condensing body 10. The base 12 is fixedly installed at the place where the solar transmission apparatus 1 of the present invention is installed.

The shaft 13 is coupled to the upper side of the base 12, it is formed straight up. The shaft 13 forms a central portion of the condensing body 10, and is rotated about an axis perpendicular to a surface on which the condensing body 10 is installed. The first motor 14 is fixedly coupled to the base 12 to axially rotate the shaft 13 and eventually rotate the arm. The first motor 14 is directly connected to the shaft 13 and rotates the shaft 13.

The arm support frame 15 is coupled at the top of the shaft 13. The arm support frame 15 is rotatably coupled at the upper end of the shaft 13. One end of each of the plurality of arms 11 is connected to the arm support frame 16. The arm 11 is formed to move together with the arm support frame 16, the arm support frame 16 is rotated together when rotating. The arm support frame 16 is not fixedly coupled to the shaft 13, but is rotatably coupled to the axis perpendicular to the longitudinal direction of the shaft 13.

The second motor 16 is coupled to the shaft 13 or the arm support frame 15, so that the arm support frame 15 is rotated relative to the shaft 13. When the second motor 16 is coupled to the shaft 13, the rotation axis of the second motor 16 is coupled to the arm support frame 15, the second motor 16 is the arm support When coupled to the frame 15, the rotation axis of the second motor 16 is made to be coupled to the shaft (13). The latter case is shown in Figs. 4 (a) to 4 (c).

The second motor 16 is directly connected to the shaft 13 or the arm support frame 15, and rotates the arm support frame 15.

The arm 11 is rotatable clockwise or counterclockwise when viewed in plan view by the driving of the first motor 14, and the arm 11 is driven by the driving of the second motor 16. Axial rotation is possible with the axis perpendicular to the shaft 13 as the axis. Therefore, by configuring the condensing body 10 as in the present invention, the mirror assembly 20 coupled to the arm 11 can be adjusted to always face sunlight, thereby enabling efficient condensing.

The solar transmission apparatus 1 according to the preferred embodiment of the present invention further includes a latent heat tank 30 for storing and re- supplying heat energy transferred from the optical fiber 100 so that heat exchange with air or water occurs. Is done.

Concentrated sunlight is transmitted to the optical fiber 100, and the optical fiber 100 is connected to the latent heat tank 30. The concentrated solar light is maintained at a high temperature, and the latent heat tank 30 enables the solar light to be used not only for lighting but also for heating or cooking food. The latent heat tank 30 may be connected to a heat pipe to exchange heat with air or water, and may be used for heating a building or supplying hot water.

1 is a schematic diagram showing a solar transmission apparatus according to an embodiment of the present invention,

2 (a) and 2 (b) are a cross-sectional view and a perspective view showing a mirror assembly used in the solar transmission apparatus according to another embodiment of the present invention,

3 is a view showing a process of forming a mirror assembly used in the solar transmission apparatus according to another embodiment of the present invention,

4 (a) is a front view showing a light collecting body used in the solar transmission apparatus according to another embodiment of the present invention, Figures 4 (b) and 4 (c) are respectively shown in Figure 4 (a) Is a side view and a state of use of the condensing body.

Explanation of symbols on the main parts of the drawings

1: solar transmitter 10: condensing body

11: arm 12: base

13: shaft 14: first motor

15: arm support frame 16: the second motor

19: receiving portion 20: mirror assembly

21: reflection portion 22: coupling portion

30: latent heat tank

100: optical fiber s1: body forming step

s2: mold processing step s3: epoxy coating step

s4: epoxy curing step s5: separation step

s6: deposition step c: mold

Claims (6)

It is used in a solar transmission system in which concentrated solar light is transmitted through an optical fiber and used as an energy source, A condensing body having one end supported and the other end extending outward; And It is provided in plurality and coupled to the upper side of the arm individually, and includes a plurality of mirror assembly configured to reflect the sunlight to be collected in one direction, The mirror assembly is provided with a reflecting portion for reflecting the sunlight on the upper side, the lower side is provided with a coupling portion coupled to the arm and ball joint form, characterized in that the solar transmission device. delete The method of claim 1, The reflector is a solar transmission apparatus, characterized in that the upper side is formed by depositing aluminum in a concave form. The method of claim 1, The mirror assembly may include a body forming step of forming a body of the mirror assembly by injection molding, a mold processing step of processing a mold having an upper surface curved, an epoxy coating step of applying uv epoxy on the mold, and the body forming. Epoxy curing step of curing the uv epoxy on the body formed in the step, the separation step of separating the mold, the solar transmission device, characterized in that formed by the deposition step of depositing aluminum on the upper surface of the uv epoxy. The method according to any one of claims 1, 3 or 4, The condensing body may include a base forming a bottom, a shaft straight up from the upper side of the base, a first motor coupled to the upper side of the base to rotate the shaft, and rotatably coupled to an upper end of the shaft. And a second motor coupled to the arm support frame for supporting the arm and coupled to the shaft or the arm support frame to enable the arm support frame to rotate in a direction perpendicular to the longitudinal direction of the shaft. Solar transmitter. The method according to any one of claims 1, 3 or 4, And a latent heat tank for storing and re- supplying heat energy transferred from the optical fiber to exchange heat with air or water.

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