KR101204595B1 - Apparatus of summing or distributing solar - Google Patents

Abstract

The present invention relates to a solar light distribution device, comprising: a housing, a plurality of input optical fibers coupled to one side of the housing to radiate sunlight into the housing, and coupled to one side of the housing and irradiated into the housing; An output optical fiber for outputting sunlight and a coating material having a high reflectivity, which is formed inside the housing and is disposed between the input optical fiber and the output optical fiber and allows the sunlight irradiated from the input optical fiber to reach the output optical fiber. It is characterized by including a light reflecting canal. In addition, the solar light distribution device according to the present invention may further include an optical path changing device. Accordingly, the solar light can be integrated or distributed by the combination using the solar light distribution device. And, by using a light path changing device of the photovoltaic distribution device according to the present invention to convert a portion of the sunlight to the photovoltaic device to transform the solar light into heat or electricity, and a portion of the remaining sunlight to reach the illumination optical fiber As a result, the sunlight reaching the illumination optical fiber is transmitted to the illumination to enable light of a house, a living room and the like, and sunbathing in the room.

Description

Apparatus of summing or distributing solar}

The present invention relates to a solar light distribution device, and more particularly, by combining or distributing the sunlight collected by the solar light concentrator, utilizing a portion of the sunlight as a light in a space that does not receive sunlight or electric energy A photovoltaic distribution device for use in production.

Recently, efforts to reduce the use of fossil fuels have been made globally due to cost and pollution problems. As a result, the Tokyo Protocol has been initiated and CO2 transactions are in full swing. In line with these times, development of alternative energy or energy reduction technologies using solar energy is being made.

On the other hand, in line with the low carbon green growth policy, technology that converts alternative energy using solar energy into electricity or heat by using photovoltaic mining technology, and also directly mines sunlight and uses it as lighting and growth light, has led to the rapid development of economic society. It is emerging as an alternative to compensate for the lack of sunshine due to environmental pollution, high-rise and high density of buildings.

In particular, due to the increase in population and the development of construction technology, the size of buildings is getting bigger and the underground structures are getting deeper. In addition, basements, underground malls, underpasses, underground and corners of buildings, and trailing areas have little sunlight and rely on electric lighting.

In other words, sunlight can not only replace the function of lighting that a light bulb has, but also acts as a living light source and performs self-cleaning such as sterilization, disinfection, drying and deodorization. And there is a need for a device that is used as lighting to enable the sun and the like in the room more.

The present invention is to solve the above-mentioned problems of the prior art, by combining or distributing the sunlight collected by the solar light concentrator, to utilize a portion of the sunlight as the illumination of a space that does not receive sunlight or to produce electrical energy It is an object of the present invention to provide a solar photo-distribution apparatus that can be used for

Another object of the present invention is to provide a photovoltaic distribution device that controls the distribution of sunlight to utilize a portion of sunlight as the illumination of a space that does not receive sunlight or to produce electrical energy.

According to the present invention, the object, a plurality of input optical fibers coupled to one side of the housing to irradiate the sunlight into the housing, and the solar light coupled to one side of the housing and irradiated into the housing output An output optical fiber which is formed inside the housing, and which is formed inside the housing, is disposed between the input optical fiber and the output optical fiber and has high reflectivity to allow the sunlight irradiated from the input optical fiber to reach the output optical fiber. A light reflection canal coated with me; And an optical path changing device arranged on an optical path of light output from the output optical fiber and changing a path of a part of the light on the optical path.

Here, the deposition agent is characterized in that any one of gold, platinum, silver, aluminum, rhodium, stainless, titanium.

In addition, the object according to the present invention, the housing; A plurality of input optical fibers coupled to one side of the housing to irradiate sunlight into the housing; An output optical fiber coupled to one side of the housing and outputting sunlight irradiated into the housing; A spherical lens disposed adjacent to the input optical fiber corresponding to each of the input optical fibers, and configured to irradiate solar light output from the input optical fiber in parallel; An aspherical lens for converging irradiating parallel sunlight emitted from the spherical lens; And a collimating lens disposed adjacent to the output optical fiber to allow sunlight irradiated from the aspherical lens to reach the output optical fiber.

The apparatus may further include an optical path changing device arranged on the optical path of the light output from the output optical fiber to change a path of a part of the light on the optical path.

The optical path changing device may include a main body to which one end of the output optical fiber is coupled; A light control lens disposed adjacent to one end of the output optical fiber and configured to converge or parallelly irradiate light emitted from the output optical fiber; And a beam splitter for changing a path of a part of light on an optical path that passes through the light control lens.

The optical path changing device may further include an optical path control unit configured to move the beam splitter to turn on or off a path change of a part of the light, wherein the optical path control unit is coupled to one end of the beam splitter to the beam splitter. A beam splitter shaft for allowing rotatable; An electromagnet portion coupled to the other end of the beam splitter to rotate the beam splitter by an electromagnetic force when a power is applied; A spring coupled to one end of the beam splitter and the other end coupled to the main body to reposition the beam splitter when the power ratio of the electromagnet portion is not applied by an elastic force; It characterized in that it comprises a switch for turning on or off the power to the electromagnet.

Since the solar light distribution device according to the present invention having the configuration as described above can combine and distribute the sunlight focused by the solar light concentrating device, it is possible to deliver appropriate sunlight to the illumination by the combination using the solar light distribution device. In this way, the optical fiber can be saved and the cost can be reduced, thereby expanding the market.

In addition, by the optical path changing device of the photovoltaic distribution device according to the present invention, a portion of sunlight reaches the photovoltaic device when desired, and a portion of the remaining sunlight reaches the illumination optical fiber, thereby reaching the illumination optical fiber. The sunlight is transmitted to the light, allowing the lighting of houses, living rooms and the like and the sun in the room. In addition, the solar light reached to the photovoltaic device can be transformed into heat or electricity.

1 is a schematic view showing a photovoltaic power generation and photovoltaic lighting system using a solar light distribution device according to the present invention,
Figure 2 is an exploded perspective view showing a first embodiment of a solar light distribution device according to the present invention,
3 is a conceptual diagram showing the integration of sunlight using the first embodiment of the solar light distribution device according to the present invention,
4 is a conceptual diagram showing the distribution of sunlight using the first embodiment of the solar light distribution device according to the present invention,
5 is a conceptual diagram illustrating the distribution of sunlight using a first embodiment of a plurality of solar sum distribution apparatus according to the present invention,
6 is a perspective view showing a second embodiment of a solar light distribution device according to the present invention,
Figure 7 is an exploded cross-sectional view of the AA line of the solar light distribution device according to the present invention of Figure 6,
8 is a conceptual diagram showing a collimating lens of the second embodiment of the solar light distribution device according to the present invention,
9 to 10 are views showing the concept of the optical path changing device of the solar light distribution device according to the present invention,
11 is a view showing a light path control unit of the solar light distribution device according to the present invention,
FIG. 12 is a cross-sectional view illustrating a line BB of the solar light distribution device according to the present invention of FIG. 11.

Hereinafter, with reference to the accompanying drawings will be described in detail embodiments according to the present invention. Here, in describing the embodiments according to the present invention, the same reference numerals are used for the same components, and description thereof may be omitted as necessary.

In general, solar light is mainly used in a solar cell apparatus that converts solar energy directly into electricity using a solar cell. Here, the photovoltaic device uses solar energy by directly converting sunlight into electrical energy as a method of producing electricity using solar energy and driving a generator by a heat engine using solar heat.

And, apart from the above-mentioned solar light is a solar light that can transmit light using an optical fiber capable of long-distance transmission of a large amount of focused light by focusing the sunlight with high efficiency using the solar light concentrator (2) Also used as a system.

1 is a schematic view showing a photovoltaic power generation and photovoltaic lighting system using a photovoltaic distribution system according to the present invention. Referring to Figure 1, the photovoltaic distribution device (1, 1a) according to the present invention is a solar light to generate heat or electricity using the sunlight focused by the solar light collecting device (2) for collecting sunlight It is used for the power generator 3 and the illumination 4 using natural light. Here, the sunlight used as the lighting (4) can not only replace the function of the light of the light bulb, but also acts as a live light source, and performs a self-cleaning action such as sterilization, disinfection, drying and deodorization. It can be used to light the house, living room and the like and to sunbathe indoors.

Hereinafter, the photovoltaic power distribution device 1, 1a according to the present invention for transmitting sunlight to the photovoltaic device 3 and the lighting 4 will be described in detail.

First Embodiment

2 is an exploded perspective view showing a first embodiment of a solar light distribution device according to the present invention, Figure 3 shows incorporating sunlight using the first embodiment of the solar light distribution device according to the present invention. 4 is a conceptual diagram illustrating the distribution of sunlight using the first embodiment of the solar light distribution device according to the present invention, and FIG. 5 is a first view of the plurality of solar light distribution devices according to the present invention. It is a conceptual diagram which shows the distribution of sunlight using an Example.

2 to 5, the solar light distribution device 1 according to the present invention includes a housing 10, an input optical fiber 20, an output optical fiber 30, and a light reflection canal 40. It includes.

2, the housing 10 is formed by a combination of the upper housing 11 and the lower housing 12. In addition, the housing 10 further includes an input optical fiber coupling hole 13 to which the input optical fiber 20 is coupled and an output optical fiber coupling hole 14 to which the output optical fiber 30 is coupled.

Here, the input optical fiber 20 is coupled to one side of the housing 10, that is, the input optical fiber coupling hole 13 to irradiate the solar light focused by the solar light concentrator 2 into the housing 10.

In addition, the output optical fiber 30 is coupled to one side of the housing 10, that is, the output optical fiber coupling hole 14 and receives the solar light output into the housing 10 by the input optical fiber 20 to distribute the solar sum Output to the outside of the device (1).

In addition, the light reflection canal 40 is formed inside the housing 10. That is, the light reflection channel 40 is disposed between the input optical fiber 20 and the output optical fiber 30 to reflect and transmit the sunlight output from the end of the input optical fiber 20 in order to transmit to the output optical fiber 30. The inner surface of the light reflection canal 40 is coated with a deposition agent having a high reflectance. Here, the deposition agent may be selected from any one of gold, platinum, silver, aluminum, rhodium, stainless, titanium. In addition, the deposition agent is not limited to the above-described examples and may be coated by other high reflectance materials.

Referring to FIG. 3, the solar light is integrated, and the sunlight output from the two input optical fibers 20 is reflected by the light reflection channel 40 and input to the end of the output optical fiber 30. Herein, the solar light is output through the two input optical fibers 20 as an example, but the present invention is not limited thereto, and the sunlight may be output through the plurality of input optical fibers 20, and the plurality of input optical fibers ( 20 may be installed at an appropriate position of the housing 10 so that sunlight can be transmitted to the output optical fiber 30.

4 illustrates a process in which sunlight is distributed by changing the positions of the input optical fiber 20 and the output optical fiber 30 of the solar light distribution device 1 according to the present invention as described above. The solar light output from 20 is reflected by the light reflection channel 40 and input to the ends of the two output optical fibers 30. Therefore, when the sunlight output from one input optical fiber 20 is 100%, the sunlight transmitted by the two output optical fibers 30 becomes 50%, respectively. Referring to FIG. 5, the plurality of photovoltaic distribution devices 1 according to the present invention including two output optical fibers 30 distribute 100% of sunlight to eventually output 12.5% of sunlight. . In addition, by inverting the combination with reference to the one shown in FIG. 5 using the solar light distribution device 1 according to the present invention, it is possible to derive the integration of sunlight. And, by adjusting the number of the input optical fiber 20 and the output optical fiber 30 of the solar light distribution device 1 according to the present invention it is possible to output the appropriate sunlight by integrating or distributing sunlight in various ways.

Second Example

6 is a perspective view showing a second embodiment of the solar light distribution device according to the present invention, Figure 7 is an exploded cross-sectional view showing a second embodiment of the solar light distribution device according to the present invention, Figure 8 is a present invention Is a conceptual diagram showing a collimating lens of a second embodiment of a solar sum distribution apparatus according to the present invention.

Hereinafter, a solar light distribution device 1a according to a second embodiment of the present invention will be described with reference to the accompanying drawings. In addition, in the description of the solar sum distribution device 1a according to the second embodiment of the present invention, the same components as described above may be omitted using the same reference numerals.

6 to 8, the solar light distribution device 1a according to the present invention includes a housing 10a, an input optical fiber 20, an output optical fiber 30, and a light reflection canal 40a. And a collimating lens 50, an aspherical lens 51 and a spherical lens 52.

6 to 7, the housing 10a includes an input optical fiber fixing housing 15, an output optical fiber fixing housing 16, an aspherical lens fixing housing 17, a spherical lens fixing housing 18, and an output collimating lens fixing housing. (19). In addition, the housing 10a further includes an input optical fiber coupling hole 13a to which the input optical fiber 20 is coupled, and an output optical fiber coupling hole 14a to which the output optical fiber 30 is coupled.

Here, the input optical fiber 20 is coupled to the input optical fiber coupling hole (13a) provided on one side of the housing (10a), that is, the input optical fiber fixing housing 15 to collect the sunlight focused by the solar light collecting device (2) It is irradiated into the housing 10a.

In addition, the spherical lens 52 is disposed adjacent to the input optical fiber 20 corresponding to each of the input optical fibers 20. Therefore, the sunlight output from the input optical fiber 20 is irradiated in parallel while passing through the spherical lens 52. The spherical lens 52 is installed and fixed to the spherical lens fixing housing 18.

In addition, the aspherical lens 51 is installed in the aspherical lens fixing housing 17, and the aspherical lens 51 receives solar light irradiated in parallel through the spherical lens 52 and converges to the collimating lens 50. Investigate Thus, sunlight is input to the collimating lens 50 without loss.

In addition, the collimating lens 50 is disposed adjacent to one end of the output optical fiber 30 so that the sunlight irradiated from the input optical fiber 20 reaches the output optical fiber 30. That is, the collimating lens 50 is installed in the collimating lens fixing housing 19 so that the sunlight irradiated from the input optical fiber 20 reaches the output optical fiber 30.

Referring to FIG. 8, the collimating lens 50 has one side formed as a hemisphere so that all the sunlight is irradiated to the output optical fiber 30. Thus, sunlight irradiated through the collimating lens 50 reaches the output optical fiber 30 without loss.

In addition, the output optical fiber 30 is coupled to one side of the housing 10a, that is, the output optical fiber coupling hole 14a provided in the output optical fiber fixing housing 16, and is output into the housing 10a by the input optical fiber 20. The received solar light is output to the outside of the solar light distribution device 1a.

Therefore, the sunlight output through the input optical fiber 20 is sequentially passed through the spherical lens 52, the aspherical lens 51, the collimating lens 50 is input to the output optical fiber 30 is output to the outside.

6 to 7, four input optical fibers 20 may be coupled to the input optical fiber coupling hole 13a. Therefore, sunlight emitted from the four input optical fibers 20 passes through the spherical lens 52, the aspherical lens 51 and the collimating lens 50 sequentially and is input to the end of the output optical fiber 30. Here, the solar light is output through the four input optical fibers 20 as an example, but is not necessarily limited to this, sunlight can be output through the plurality of input optical fibers 20, and a plurality of input optical fibers ( 20 may be installed at an appropriate position of the housing 10a so that sunlight can be transmitted to the output optical fiber 30.

On the other hand, Figures 9 to 10 is a view showing the concept of the optical path changing device of the solar light distribution device according to the present invention, the solar light distribution device (1, 1a) according to the present invention is a light path changing device 60 ) May be further included. Here, the optical path changing device 60 is disposed on the optical path of the light output from the output optical fiber to change the path of a part of the light on the optical path.

The light path changing device 60 includes a main body 61, a light control lens 62, and a beam splitter 63. Here, one end of the output optical fiber 30 is coupled to one side of the main body 61. Then, the light control lens 62 is disposed adjacent to one end of the output optical fiber 30 so that the light irradiated from the output optical fiber 30 is converged or parallelly irradiated. For example, the collimating lens 50 illustrated in FIG. 8 may be used as the light control lens 62.

In addition, the beam splitter 63 changes a path of a part of sunlight on the optical path that passes through the light control lens 62. 9 to 10, FIG. 9 is a view illustrating a state in which the beam splitter 63 is turned off, and sunlight passing through the light control lens 62 reaches the photovoltaic device optical fiber 80. . Here, the sunlight reaching the power generation device optical fiber 80 is transferred to the photovoltaic device 3 to generate heat or electricity. In addition, collimating 50a is further installed adjacent to the photovoltaic device optical fiber 80 so that the sunlight passing through the light control lens 62 reaches the photovoltaic device optical fiber 80 without loss.

FIG. 10 is a view showing a state in which the beam splitter 63 is turned on. The beam splitter 63 causes a part of the sunlight passing through the light control lens 62 to reach the photovoltaic device optical fiber 80, and the rest A portion of the sunlight is allowed to reach the illumination fiber 90. Here, the sunlight reaching the illumination optical fiber 90 is transmitted to the illumination (4) to enable the light of the house, living room, and the like, the sun in the room. In addition, collimating 50b is further provided adjacent to the illumination optical fiber 90 so that the sunlight passing through the light control lens 62 reaches the illumination optical fiber 90 without loss.

FIG. 11 is a view showing a light path control unit of a solar light distribution device according to the present invention, and FIG. 12 is a cross-sectional view showing a line B-B of the solar light distribution device according to the present invention of FIG.

Hereinafter, the optical path controller 70 for controlling the beam splitter 63 of the optical path changing device 60 to turn on or off the path change of a part of the light will be described.

The light path changing device 60 may further include a light path controller 70.

11 to 12, the optical path controller 70 may further include a beam splitter shaft 71, an electromagnet portion 72, a spring 73, and a switch 74.

Here, the beam splitter shaft 71 is axially coupled to one end of the beam splitter 63 and mounted to the main body 61. Therefore, the beam splitter 63 can be rotated corresponding to the main body 61 by the beam splitter shaft 71.

In addition, the electromagnet portion 72 is coupled to the other end of the beam splitter 63 so that the beam splitter 63 rotates by the electromagnetic force when the power is applied to change the path of part of the sunlight passing through the light control lens 62. Let's do it. Accordingly, the beam splitter 63 rotated by the electromagnet portion 72 when the power is applied causes the portion of the sunlight passing through the light control lens 62 to reach the photovoltaic device optical fiber 80, and the portion of the remaining sunlight. To reach the illumination optical fiber 90.

In addition, one end of the spring 73 is coupled to the beam splitter 63, the other end is coupled to the main body (61). Accordingly, when the power supply of the electromagnet portion 72 is not applied, the spring 73 returns the beam splitter 63 to its original position by the elastic force, that is, turns off the path change of a part of the light so that all the sunlight passes through the light control lens 62. The solar cell optical fiber 80 is reached.

The switch 74 turns the electromagnet portion 72 on or off.

While the invention has been shown and described with reference to certain preferred embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments. Those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope of the appended claims, The genius will be so self-evident. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1 solar power distribution device 2 solar light concentrator
3: solar power device 4: lighting
10, 10a: housing 20: input optical fiber
30: output fiber 40, 40a: light reflection channel
50: collimating lens 60: optical path changing device
70: optical path control unit 80: photovoltaic device optical fiber
90: illuminated optical fiber

Claims (6)

A housing;
A plurality of input optical fibers coupled to one side of the housing to irradiate sunlight into the housing;
An output optical fiber coupled to one side of the housing and outputting sunlight irradiated into the housing;
A light reflection canal formed inside the housing and coated with a high reflectance deposition agent disposed between the input optical fiber and the output optical fiber to allow sunlight irradiated from the input optical fiber to reach the output optical fiber;
And an optical path changing device arranged on an optical path of light output from the output optical fiber to change a path of a part of the light on the optical path. The method of claim 1,
The deposition agent is any one of gold, platinum, silver, aluminum, rhodium, stainless, titanium. A housing;
A plurality of input optical fibers coupled to one side of the housing to irradiate sunlight into the housing;
An output optical fiber coupled to one side of the housing and outputting sunlight irradiated into the housing;
A spherical lens disposed adjacent to the input optical fiber corresponding to each of the input optical fibers, and configured to irradiate solar light output from the input optical fiber in parallel;
An aspherical lens for converging irradiating parallel sunlight emitted from the spherical lens;
And a collimating lens disposed adjacent to the output optical fiber to allow sunlight irradiated from the aspherical lens to reach the output optical fiber. The method of claim 3,
And an optical path changing device arranged on an optical path of light output from the output optical fiber to change a path of a part of the light on the optical path. 5. The method of claim 4,
The optical path changing device
A main body to which one end of the output optical fiber is coupled;
A light control lens disposed adjacent to one end of the output optical fiber and configured to converge or parallelly irradiate light emitted from the output optical fiber;
And a beam splitter for changing a path of a part of light on an optical path that passes through the light control lens. The method of claim 5,
The optical path changing device further includes an optical path control unit which moves the beam splitter to turn on or off a path change of a part of the light.
The light path control unit
A beam splitter shaft coupled to one end of the beam splitter to enable the beam splitter to rotate;
An electromagnet portion coupled to the other end of the beam splitter to rotate the beam splitter by an electromagnetic force when a power is applied;
A spring coupled to one end of the beam splitter and the other end coupled to the main body to reposition the beam splitter when the power ratio of the electromagnet portion is not applied by an elastic force;
And a switch for turning the power on or off in the electromagnet unit.

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