KR20150135587A - Solar Concenstrator for photovoltaic lighting, sterilization and thermoelectric generator - Google Patents

Abstract

A solar concentrator is disclosed. The solar concentrator according to the present invention comprises: a concave mirror-type focusing reflector for reflecting sunlight so that incident sunlight is concentrated in a point; a cold mirror which performs the functions of transmitting infrared rays of the sunlight reflected from the focusing reflector and reflecting sunlight other than the infrared rays, and is installed in a focus part of the focusing reflector; a lens assembly for transmitting the sunlight reflected from the cold mirror with an optical cable; a thermoelectric generator for generating electricity by using high temperature of the infrared sunlight transmitted from the cold mirror; and an optical cable which is connected to the lens assembly to transmit the collected sunlight. According to the present invention, sterilization and disinfection effects by ultraviolet rays can be provided by intensively providing only ultraviolet rays through a single solar concentrator; a visible light can be transmitted to shaded areas in daytime for lighting; and the electricity can be simultaneously generated or selectively provided.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a solar concentrator for photovoltaic lighting, sterilization and thermoelectric power generation,

The present invention relates to a solar concentrator, and more particularly, to a solar concentrator using an optical fiber cable system, a solar concentrator for sterilizing and disinfecting sunlight using ultraviolet rays, and a thermoelectric generator using a high- To an integrated solar concentrator.

Recently, interest in environmentally friendly renewable energy is increasing. Accordingly, a large number of devices for collecting sunlight to be used for lighting in a building or for producing electricity using sunlight and solar heat have been developed.

Among the conventional technologies for using solar light, there is a problem in that the solar module is made by using silicon to obtain DC electricity, and then converted to AC electricity and used again as electric lighting, the efficiency is lowered and many industrial wastes are made from silicon material .

Recently, there are many places that require electric lighting in shaded areas such as buildings, tunnels, and basements in the days when the sun is in the sun, and there is a lot of interest in the functions of sunlight, which is a growth light source having many functions such as vitamin D synthesis. Efforts are being made worldwide to develop and commercialize a solar lighting system that can be freely used by mining without conversion and transferring it to a necessary place.

On the other hand, in the electric power generation technology using solar light, when both ends of two metals or semiconductors having low thermal conductivity have a large temperature difference, a lot of researches on thermoelectric power generation using a seebeck effect in which heat is generated . However, when a heater is used as a heat source for heating one end to a high temperature, there is a disadvantage that the energy consumption for using the heater is larger than the amount of the thermoelectric power, and the thermoelectric power generation using the geothermal heat and the waste heat as the heat source is being studied.

Korean Patent No. 10-1093773 discloses a technique for collecting sunlight and transferring it to an optical fiber bundle and obtaining electricity through solar cell power generation using a solar cell, There is a problem that the power generation efficiency is lowered because the solar cells are arranged around the solar cell and power is generated without condensing sunlight. In addition, there is a problem in that the solar cell can not generate power through condensation due to heat.

Korean Patent Publication No. 10-1983-009506 discloses a technique of combining a light collecting device for collecting sunlight into a light conductor cable and a device for receiving solar light to generate sunlight, The device does not generate sunlight through condensation, but installs solar cells by the area where sunlight enters, and uses only solar light received therefrom, resulting in a problem of low power generation efficiency.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art and satisfy socially required matters.

The present invention can be used as a light source without directly converting the sunlight collected through the sunlight condensing device into electricity, so that it is possible to provide solar light to a shade area inside the building or underground To provide the technology.

The present invention also provides a technique capable of providing a function of separately collecting only ultraviolet rays of sunlight and illuminating the sunlight where necessary to sterilize and disinfect.

The present invention also provides a technique for collecting sunlight in an infrared region not used for illumination and disinfection and collecting sunlight in one place to generate electricity.

According to an aspect of the present invention, there is provided a solar concentrator comprising: a concave mirror-type focusing mirror for reflecting sunlight so that incident sunlight is collected at one point; A cold mirror installed at a focal point of the focusing mirror, a lens assembly for transmitting sunlight reflected from the cold mirror to an optical cable, a lens assembly for transmitting the sunlight reflected from the cold mirror to the optical cable, A thermal power generator for generating electric power by using the high temperature of the infrared sunlight transmitted through the cold mirror, and an optical cable connected to the lens assembly for transmitting the focused sunlight.

Preferably, a through hole is formed in the central portion of the center axis of the focusing mirror for transmitting the condensed sunlight and for installing the lens assembly and the optical cable.

The lens assembly may include at least one of a convex lens, a plano convex lens, a concave lens, a plano concave lens, a ball lens, a half-ball lens, Ball Lens, refracts and compresses incident sunlight using the lens, and transmits the refracted and compressed light to the optical cable.

In one embodiment, the lens assembly includes at least one lens coupling portion for fixing the lens, and an optical cable connector in which an optical cable insertion port is formed to connect the optical cable.

In one embodiment, the lens assembly includes a filtering mirror installed on the surface of the incident sunlight to filter ultraviolet rays, an ultraviolet light collector for condensing the ultraviolet light reflected through the filtering mirror, The filtering mirror may be installed at a predetermined angle in a direction perpendicular to the incident sunlight so that reflected ultraviolet rays are not directed in the direction of the cold mirror.

In another embodiment, the thermoelectric device includes a thermoelectric element provided on the opposite side of the focusing mirror based on the cold mirror, wherein the thermoelectric element and the cold mirror are positioned between the focus of the focusing mirror and the focusing mirror The thermoelectric element converts solar energy into electrical energy through thermal power generation using infrared rays that are focused through the cold mirror.

On the other hand, one end of the thermoelectric element includes a heating part heated by infrared rays transmitted from the cold mirror, and the opposite end may include a cooling fin, a cooling pipe, or a ceramic heat radiating material. The cold mirror has a surface of any one of a parabolic surface, a spherical surface, a hyperboloid surface, and an elliptical surface, and condenses reflected or transmitted light.

Preferably, the focusing mirror has a surface of any one of a paraboloid, a spherical surface, a hyperbolic surface, and an elliptical surface, and collects the reflected light.

The solar concentrator according to the present invention having the above-described structure solves various problems of the related art solar photovoltaic power generation and solar photovoltaic lighting technology, and has various functions such as solar light illumination, sterilization using sunlight, It can be installed in a narrow space by integrating with a device, and has an effect of being excellent in installation space efficiency.

In addition, a concave mirror type reflector is employed in place of the large-diameter lens in the primary sunlight condensing, which is more economical than the lens-type light collecting method.

In addition to the basic effect of reducing electricity use nationwide by replacing the daytime electric lighting used in a building or a shade area such as a large building, a subway, a parking lot, a hospital, a school, or the like, It is possible to provide a sterilizing and disinfecting effect by ultraviolet rays by providing only ultraviolet rays intensively, and it is also possible to provide visible light rays to the illuminated area in the daytime shaded area and simultaneously generate electricity or selectively provide There is an excellent effect.

In addition, the present invention is economical because it can realize high efficiency by using only a minimum thermoelectric element, can generate electricity without a separate heat source, and can supply electricity as well as general electricity using thermoelectric inversion, The solar tracking device necessary for use of the solar concentrator can be driven without external electric power, and thus the solar concentrator which can be driven by itself without external power can be constituted.

In addition, there is an advantage that ultraviolet rays that are enough to replace an electric sterilizing sterilizer among the incident sunlight can be separately filtered and collected, and then it can be provided at a place where sterilization and disinfection of ultraviolet rays such as a restaurant and a hospital are required. There is also an effect that can be utilized in the tanning apparatus.

In addition, according to the use of the solar concentrator, the present invention can transmit sunlight separated by an optical fiber, in particular, SOF (Silica Optical Fiber) or GOF (Glass Optical Fiber) have.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a solar light condensing device using a conventional Fresnel lens. FIG.
2 is a view showing a conventional solar concentrating apparatus using two concave mirrors.
3 is a view showing a configuration of a conventional solar light condenser of the present applicant.
4 is a diagram showing the configuration of a second light collecting part of the solar light condenser shown in Fig.
5 shows a configuration of a solar light condenser according to the present invention.

The following detailed description of the invention refers to the accompanying drawings, which illustrate, by way of illustration, specific embodiments in which the invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the invention. It should be understood that the various embodiments of the present invention are different, but need not be mutually exclusive. For example, certain features, structures, and characteristics described herein may be implemented in other embodiments without departing from the spirit and scope of the invention in connection with an embodiment. It is also to be understood that the position or arrangement of the individual components within each disclosed embodiment may be varied without departing from the spirit and scope of the invention. The following detailed description is, therefore, not to be taken in a limiting sense, and the scope of the present invention is to be limited only by the appended claims, along with the full scope of equivalents to which such claims are entitled, if properly explained. In the drawings, like reference numerals refer to the same or similar functions throughout the several views.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a solar light condensing device using a conventional Fresnel lens. FIG.

Referring to FIG. 1, a sunlight condensing apparatus 10 using a fresnel lens includes a frame 11 having two fan-shaped shapes facing each other and a pair of upper and lower arcs of the frame 11, A fresnel lens 12 and a side high reflective film 13 attached to the inside of the two fan-shaped portions, and integrates sunlight through the fresnel lens 12. [

This condensing device 10 uses a Fresnel lens 12 as a method of sunlight mining and minimizes the spherical aberration and chromatic aberration of the lens so as to integrate sunlight into a single optical fiber having a center diameter of 1 mm in diameter . However, since the size of the lens for receiving the sunlight is limited to 95 mm in diameter, there is a problem that the required brightness can be satisfied only by using a plurality of lenses.

2 is a view showing a conventional solar concentrating apparatus using two concave mirrors.

2, the sun light condensing device 20 using two concave mirrors is configured so that the sunlight coming from the sun through the main reflector (concave mirror) 21 and the sub-reflector (concave mirror) 22 passes through the optical fiber 24 And reflects the light to the focused light collecting part (23).

Specifically, when the sunlight is incident on the main reflector 21, the light collecting device 20 firstly reflects the light to the inside, that is, the concave surface, and the sunlight, which is firstly reflected according to the curvature of the concave surface, When the concave surface is formed so as to face the main reflector, the primary reflected sunlight is again reflected twice.

In such a light concentrating apparatus using concave mirrors, since the size of incident sunlight is too large, it is necessary to use a plurality of strands of optical fibers, thereby causing light loss in the light collecting portion.

3 is a view showing a configuration of a conventional solar light condenser of the present applicant.

3, a solar concentrator (Application No. 10-2008-0057734) filed on June 19, 2008 by the present applicant has a convex mirror 31, a second convex mirror support 32, a concave mirror A second condensing unit including a convex lens 33, a ball lens 34, a condenser support 35 and an optical fiber 37, and a second condensing unit including an infrared optical filter 38, A mirror fixing plate 39, and an optical filter housing 40.

3 uses a concave mirror 36 having a radius of curvature of 500 mm and a secondary convex mirror 31 having a radius of curvature of 50 mm to condense sunlight. The sunlight is first reflected by the concave mirror and condensed on the convex mirror. The convex mirror is positioned in front of the focal plane of the concave mirror, and the light reflected back by the convex mirror is incident on the convex lens 33 of the second light condensing portion 50 in parallel. The light incident on the convex lens 33 is designed to enter the ball lens 34 beyond the focal plane of the convex lens 33. The size of the sunlight finally condensed by the ball lens 34 becomes 1.5 mm in diameter and can be incident on one strand of the optical fiber.

The solar concentrator of FIG. 3 minimizes the loss of the condensed sunlight by condensing the condensed light onto a single optical fiber of 1.5 mm in diameter using the convex lens 33 and the ball lens 34. As a result, compared with Japan's lens-focused type mining method, it is possible to obtain about twice the area of large-area mining. In comparison with the reflection type convergence type of the United States, by condensing the light onto one optical fiber, So that more efficient optical transmission is possible. The light passing through the optical fiber is filtered by infrared light filter to be used for illumination.

4 is a diagram showing the configuration of a second light collecting part of the solar light condenser shown in Fig.

The second condensing section 50 includes an optical fiber 37, a convex lens 41, a condenser housing 42, a ball lens 43, and a fiber optic support base 44.

3 comprises a concave mirror 36 having a radius of curvature of about 500 mm and a convex mirror 31 having a radius of curvature of about 50 mm. The sunlight is reflected by the concave mirror 36 and condensed on the convex mirror 31. The convex mirror 31 is positioned before the focal plane of the concave mirror 36 and the light reflected back by the secondary mirror is incident on the convex lens 33 of the second light collecting unit with the same size as the convex lens 36 . The light incident on the convex lens 33 passes through the focal plane of the convex lens 33 and enters the ball lens 34. The size of the sunlight finally condensed by the ball lens 34 is 1.5 mm in diameter It is possible to make it incident on one strand of the optical fiber. The diameter and the radius of curvature may have a size within an error range of +/- 10% in the diameter and radius of curvature described above.

5 shows a configuration of a solar light condenser according to the present invention.

Referring to FIG. 5, a solar concentrator 60 according to the present invention includes a focusing mirror 61, a fixing portion 62, a cold mirror-thermoelectric device assembly 70, and a lens assembly 80.

The cold mirror-thermoelectric module assembly 70 includes a cold mirror 71 and a heat generator 72. The lens assembly 80 includes an optical cable connector 83, an optical cable insertion portion 84, a filtering mirror And includes a lens coupling portion 89 including an ultraviolet light condensing portion 85, an ultraviolet light condensing portion 86, an optical cable 87, an ultraviolet light cable 88, and a ball lens 81 and a convex lens 82.

The focusing mirror 61 is a concave mirror type device for reflecting sunlight so that incident sunlight can be collected at one point. This focusing mirror has a surface of any one of paraboloid, spherical, hyperbolic, and elliptical, and collects it in one place of reflection.

The fixing portion 62 is a device for fixing and fixing the lens assembly 80 and the cold mirror-thermoelectric element assembly 70 together.

The cold mirror-thermoelectric element assembly 70 is a coupling device for transmitting infrared rays among the sunlight condensed by the focusing mirror 61, reflecting the remaining sunlight, and thermally generating electricity using transmitted infrared rays. The cold mirror-thermoelectric element assembly 70 is preferably positioned between the focusing mirror 61 and the focal point of the focusing mirror.

The lens assembly 80 is fixed to the central portion of the condensation mirror 61 of the focusing mirror 61, condenses the collected sunlight to one point and transmits it to the optical cable, separates ultraviolet rays from the sunlight, .

The cold mirror 71 functions to transmit infrared rays of sunlight reflected by the focusing mirror 61 and to reflect sunlight other than infrared rays toward the lens assembly 80. The cold mirror 71 is provided at the focal point of the focusing mirror 61.

The heat generator 72 functions to generate electricity through heat generation by using the high temperature of the infrared sunlight transmitted through the cold mirror 71.

On the other hand, the thermoelectric device 72 includes a thermoelectric element, which is provided on the opposite side of the focusing mirror 61 with respect to the cold mirror 71, passes through the cold mirror 71, And converts solar energy into electrical energy through thermoelectric power generation. One end of the thermoelectric element includes a heating part which is heated by infrared rays transmitted from the cold mirror 71. The other end of the thermoelectric element is cooled by one of air cooling, water cooling and oil cooling, and thermoelectric power is generated by the temperature difference between the both ends . The opposite end of the thermoelectric element may include a cooling fin or a cooling pipe or a ceramic heat-radiating member.

The cold mirror 71 has a surface of any one of a paraboloid, a spherical surface, a hyperboloid, and an elliptical surface and functions to condense sunlight reflected or transmitted.

Referring again to FIG. 5, a center hole of the focusing mirror 61 is provided with holes for transmitting the condensed sunlight and for installing the lens assembly 80 and the optical cables 87 and 88.

5, the lens coupling portion 89 of the lens assembly 80 functions to fix the ball lens 81 and the convex lens 82 in a fixed manner. However, the lens assembly 80 also refracts and compresses incident sunlight through proper combination of a convex lens, a convex lens, a concave lens, a flat concave lens, a ball lens, and a half ball lens, It can be transmitted by cable. 5, sunlight passing through the convex lens 82 and the ball lens 81 is condensed at the end of the optical cable 87 and is transmitted through the optical cable 87. [

The lens assembly 80 includes an optical cable connector 83 formed with an optical cable insertion port 84 for connecting the optical cable. The filtering mirror 85 of the lens assembly 80 is a mirror that functions to filter ultraviolet rays of sunlight reflected by the cold mirror 71 and incident on the lens assembly 80. The filtering mirror 85 can be made to reflect only ultraviolet rays by applying ultraviolet ray coating or the like on the surface thereof. The ultraviolet light condensing unit 86 collects the ultraviolet light reflected by the filtering mirror 85 and transmits the condensed ultraviolet light to the ultraviolet light cable 88. On the other hand, the filtering mirror 85 is preferably installed at a predetermined angle in a direction perpendicular to the incident sunlight so that the reflected ultraviolet rays are incident on the other direction without being directed toward the cold mirror. When the filtering mirror 85 is slightly twisted as described above, it is advantageous to separately treat the ultraviolet rays by preventing reflected ultraviolet rays and incident sunlight from overlapping each other.

Referring to FIG. 5 again, the solar light condensing device moves along the sun with the aid of the developed external device (for example, a solar tracking device), makes it perpendicular to the incident direction of sunlight, , The sunlight reflected by the focusing mirror 61 having the surface of the ellipsoidal surface and the hyperbolic surface can be focused at the focus. The lens assembly 80 is coupled to the central passage of the reflector and the cold mirror thermoelectric device assembly 70 is positioned between the focus of the focusing mirror 61 and the focusing mirror 61 coaxially with the lens assembly 80 The lens assembly 80 and the cold mirror-thermoelectric element assembly 70 are coupled by the fixing portion 62. The sunlight reflected by the focusing mirror 61 is used for infrared light of the infrared band and illumination and disinfection and sterilization for heating the thermoelectric element by the cold mirror 71 of the cold mirror thermoelectric element assembly 70 To be separated into the remaining solar bands. The sunlight in the infrared band of the sunlight separated by the cold mirror 71 proceeds as it is to the focal point of the focusing reflector 61 and is integrated in the thermoelectric element to realize the high efficiency thermoelectric power generation and the remaining visible ray and ultraviolet ray band are reflected by the cold mirror 71, and proceeds to the lens assembly 80 coupled to the central passage of the focusing mirror 61. In this lens assembly 80, ultraviolet rays for use in sterilizing and disinfecting sunlight reflected by the cold mirror 71 through a specially coated filtering mirror 85 are separated from each other, and then separated by a separate optical cable 88 And transmits the visible light to another optical cable 87 so as to compress the visible light. The filtering mirror 85 is composed of a coating lens or a mirror and is disposed inside the lens assembly 80 so that the visible light band passes through the sunlight and the ultraviolet light band is reflected. The visible light having passed through the filtering mirror 85 is compressed and transmitted through the optical cable 87 connected to the optical cable connector 83. The separately separated ultraviolet light is transmitted to the ultraviolet light cable 88 through the ultraviolet light concentrator 86 Each reaching a different survey area for that purpose and allowing the blind to blink.

The material of the focusing mirror 61 may be a general mirror material such as iron, aluminum, glass, or polycarbonate. The case material of the lens assembly 80 and the cold mirror-thermoelectric conversion element assembly 70 may be iron, stainless steel, steel, aluminum and other ferrous and non-ferrous metals and metal alloys, or may be a plastic having a high softening temperature. The lenses 81 and 82 of the lens assembly 80 use BK7, quartz, ruby, sapphire, fused silica, S-LAH79, LaSFN9, and other materials having high temperature stability.

The solar concentrator according to the present invention having the above-described structure solves various problems of the related art solar photovoltaic power generation and solar photovoltaic lighting technology, and has various functions such as solar light illumination, sterilization using sunlight, It can be installed in a narrow space by integrating with a device, and has an effect of being excellent in installation space efficiency.

In addition, a concave mirror type reflector is employed in place of the large-diameter lens in the primary sunlight condensing, which is more economical than the lens-type light collecting method.

In addition to the basic effect of reducing electricity use nationwide by replacing the daytime electric lighting used in a building or a shade area such as a large building, a subway, a parking lot, a hospital, a school, or the like, It is possible to provide a sterilizing and disinfecting effect by ultraviolet rays by providing only ultraviolet rays intensively, and it is also possible to provide visible light rays to the illuminated area in the daytime shaded area and simultaneously generate electricity or selectively provide There is an excellent effect.

In addition, the present invention is economical because it can realize high efficiency by using only a minimum thermoelectric element, can generate electricity without a separate heat source, and can supply electricity as well as general electricity using thermoelectric inversion, The solar concentrator necessary for use of the solar concentrator can be driven without external electricity, and thus, a solar concentrator which can be driven by itself without external power can be constituted.

In addition, there is an advantage that ultraviolet rays that are enough to replace an electric sterilizing sterilizer among the incident sunlight can be separately filtered and collected, and then it can be provided at a place where sterilization and disinfection of ultraviolet rays such as a restaurant and a hospital are required. There is also an effect that can be utilized in the tanning apparatus.

In addition, according to the use of the solar concentrator, the present invention can transmit sunlight separated by an optical fiber, in particular, SOF (Silica Optical Fiber) or GOF (Glass Optical Fiber) have.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, Those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims.

Therefore, the spirit of the present invention should not be construed as being limited to the above-described embodiments, and all of the equivalents or equivalents of the claims, as well as the following claims, I will say.

60: Photovoltaic blader 61: Focusing reflector
62; Fixing 70: Cold Mirror - Thermoelectric Device Assembly
71: Cold Mirror 72: Heat Generation Device
80: lens assembly 81: ball lens
82: convex lens 83: optical cable connector
84; Optical cable insertion part 85: Filtering mirror
86: Ultraviolet light concentrator 87: Optical cable
88: ultraviolet optical cable 89: lens coupling part

Claims (10)

A concave mirror type focusing mirror for reflecting the sunlight so that incident sunlight can be collected at one point;
A cold mirror installed at a focal point of the focusing mirror for transmitting infrared rays of sunlight reflected by the focusing mirror and reflecting solar rays other than the infrared rays;
A lens assembly for transmitting sunlight reflected by the cold mirror to an optical cable;
A thermal power generator for generating electricity using the high temperature of the infrared sunlight transmitted through the cold mirror; And
An optical cable coupled to the lens assembly for transmitting focused sunlight;
And a plurality of light collectors. The method according to claim 1,
And a through hole is formed in the central part of the center axis of the condensing reflector for transmitting the condensed sunlight and for installing the lens assembly and the optical cable. 3. The method of claim 2,
The lens assembly may include at least one of a convex lens, a plano convex lens, a concave lens, a plano concave lens, a ball lens, a half ball lens, ), And refracts and compresses incident sunlight using the lens to transmit the sunlight to the optical cable. The method of claim 3,
The lens assembly
At least one lens coupling portion for fixing the lens; And
An optical cable connector having an optical cable insertion port for connecting the optical cable;
≪ / RTI > The method of claim 3,
The lens assembly includes:
A filter mirror installed on the surface of the incident sunlight to filter ultraviolet rays by using a UV coating;
An ultraviolet light collector for condensing the ultraviolet light reflected through the filtering mirror;
An ultraviolet optical cable for transmitting the ultraviolet light;
Further comprising:
Wherein the filtering mirror is installed at a predetermined angle in a direction perpendicular to the incident sunlight so that reflected ultraviolet rays are not directed toward the cold mirror. The method according to claim 1,
The thermoelectric device includes a thermoelectric element provided on the opposite side of the focusing mirror based on the cold mirror,
Wherein the thermoelectric element and the cold mirror are positioned between the focal point of the focusing mirror and the focusing mirror,
Wherein the thermoelectric conversion element converts solar energy into electric energy through thermal power generation using infrared rays that have been focused through the cold mirror. The method according to claim 6,
And one end of the thermoelectric element is heated by infrared rays transmitted through the cold mirror, and the other end of the thermoelectric element is cooled by one of air cooling, water cooling and oil cooling so that the thermoelectric power is generated by the temperature difference between the both ends . 8. The method of claim 7,
And the opposite end of the thermoelectric element comprises a cooling fin or a cooling pipe or a ceramic heat-radiating member. The method according to claim 1,
Wherein the cold mirror has a surface of any one of a paraboloid, a spherical surface, a hyperbolic surface, and an elliptical surface, and condenses reflected or transmitted light. The method according to claim 1,
Wherein the focusing mirror has a surface of any one of a paraboloid, a spherical surface, a hyperbolic surface, and an elliptical surface, and collects the reflected light.

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