KR20040086031A - Light source facility machine, collecting sun light source and utilizing sunlight source as energy - Google Patents

Abstract

PURPOSE: A light source facility machine, collecting a sun light source and utilizing the sun light source as energy is provided to collect the sun light source and to make use of the sun light source as energy through the emission of light, heat generation, and generation of electric power. CONSTITUTION: A light source facility machine collects a sun light source(100) and collects heat. Several light collection mechanisms(120) move along the altitude of the light source by a grid-type ladder(109). East-west rotation parallax rotating mechanisms(112) move and several light collection mechanism pillars(110) and an optical cable-optical fiber(105) multiplicatively collect light source and the light source is collected to a light source collection mechanism(200) and to a light source-temporary storage chamber(205). The light source is transferred to the optical fiber from a light source inlet and outlet(206) of the light source-temporary storage chamber and is temporarily stored in a light source-temporary reservoir(400). The collected light source is transferred to a light source heat mechanism(300) from a light source terminal switch(500).

Description

Light source equipment, which concentrates solar light sources and uses them as energy

The present invention uses a solar light source as a means of emitting light, heat generation, and power generation that can be used for living by condensing the sun and the light source, and more particularly, a light source recruiting box that recruits light sources to a light collecting part and an optical fiber. The present invention relates to a light source equipment machine that uses light as a light source, a light emitting device, a light emitting device, a light emitting device, a light source, a light source, and a light source.

Outside the Earth's atmosphere, the sun-facing side receives about 1.96 cal radiant energy per minute per square centimeter. On Earth, energy is lost due to absorption by water vapor in the atmosphere, reflection by clouds, and scattering, and receives about 1 kal of radiant energy per second per square centimeter.

This is equivalent to 700 W of energy per square centimeter, and if we calculate the solar heat reaching the Earth, we can see that the sun emits 3.90 × 10 ³³ radiant energy in the surrounding space.

In addition, the development of energy using solar energy, such as absorbing the heat energy radiated by the sun and generating power by moving heat engines and generators, or converting it into solar electric energy, using solar cells, or by accumulating solar heat, uses solar heat for heating and hot water devices. The trend is active. However, new technology household products using solar heat, which directly improves the efficiency of living, have not been introduced, and thus, the use of unlimited solar energy resources is not available for versatile use.

The present invention was developed in view of the above circumstances, and it is commercially available in everyday life by emitting light, generating heat, and generating power by using a terminal switch in a light collecting unit for collecting a solar light source, a light source recruiting light source with optical fibers, and a light source for solar energy utilization. The purpose is to provide a light source equipment machine that collects and uses as energy.

Figure 1 is a basic embodiment of the present invention the collective condensing heat commercial apparatus using a light source connected to the light emitting heating means

2 is a structural diagram of a light collector using primary and secondary reflectors, which are light collecting means of the present invention;

3 is a structural diagram of a light concentrator device using parabolic glass hemispheres 1 and 2 as reflectors of the present invention;

4 (a) is a block diagram of a brick-type light concentrating device using a Fresnel lens and a reflecting surface as a light-converging light collecting means of the present invention;

(B) is a structure diagram of a brick-type light condensing device using a double biscuits Fresnel lens and reflecting surfaces 1, 2, which is the light collecting means of the present invention

5 is a structural diagram of a light source short-term collection light collector device which is a storage commercial means of the present invention;

Figure 6 is a light source access control terminal switch structure diagram of the present invention

7 is an embodiment of a light emitting device that is a commercial means of the present invention;

8 is a structure diagram of a light lamp emitting light with the glass tube of the present invention;

9 is a structural diagram of an embodiment used as a commercial neon sign in a translucent box of the present invention

10 is an embodiment structure diagram of a colored glass bead double reflector lamp equipped with a motor of the present invention

11 is an exemplary view showing a state in which a bead-type lamp including a lens, a light emitting glass, a semi-transparent color cover, and a support mirror in a light source of the present invention is disassembled.

12 is a structural view of an embodiment in which the illumination color glass hot air balloon of the present invention is combined and connected

13 is a hot air balloon combining various light emitters of the present invention

14 is a schematic diagram of the electrical conversion device of the light source in the light source dome box of the present invention

<Explanation of symbols for main parts of drawing>

100 Light Source 101 Primary Reflector 102 Secondary Reflector

104 Light Source Guide 105 Fiber Optic 106 Secondary Reflector Mesh

107 Altitude Adjuster 109 Grid Ladder 110 Light Source Collector Columns

112 Parallax Rotator 121 Height and Turn Adjuster 205 Light Source Temporary

300 Light Source Hot Air Balloon 400 Light Source Storage Room 500 Light Source Guide Terminal

600 table lamp 700 silicone box

The present invention will be described in detail with reference to the drawings and symbols as follows.

Referring to the entire process from the heat collector of FIG. 1 to the light source hot air balloon in use and the electric switching device of the light source, FIG. 1 is an exemplary view of collecting and using the solar light source 100 in FIG. 1. By moving the working point of the force 120 to the lattice ladder 109, a plurality of light collectors are moved along the altitude of the light source.

Since the sun moves in parallax, the east-west rotation parallax rotor 112 moves and accordingly raises the altitude (121) (123).

In addition, a plurality of light collector poles 110 and optical cable optical fiber 105 is multi-recruited to be recruited to the light source collector 200 to recruit an infinite light source and the light source temporary storage unit 400 to the light source temporary storage chamber 205. It is transferred to the light source terminal switch 500 to the destination as needed.

From the light source to the hot air balloon 300 in more detail as shown in Figures 2 to 4 is formed as a collector 101 for recruiting the light source 100, Figure 2 is an arrow 106 to the primary reflector 101 The secondary reflector 102 is mounted at the center and the light source 100 is transferred to the light source guide 131 using the lens 130 at the meeting point. The connection between the glass fiber 105 and the light source guide 131 to which the light source is transported is to be engaged with the fixing nut 133 and the connection nut 132.

3 is a structural diagram of a light concentrator device using parabolic glass hemispheres 1 and 2 reflectors, which are the light collecting means of the present invention, in order to guide the light source 100 to the condensing heat guide groove 104, a parabolic glass condenser 140 is used. Several glass concentrators 140, like tiles, are mounted on the outer wall to recruit light sources 100 that are fired and radiated to buildings. The glass collector 140 has a reflective material coated on the parabolic reflecting surface 101 and a reflective material is coded on the front planar central parabolic concave surface 102 so that the light source 100 passed through the glass collector 140 has a light source guide groove ( The light source 100 collected on the glass parabolic reflecting surface 101 and the secondary glass parabolic reflecting surface 102 by 104 is transferred to the glass fiber 105 and is light-heated by the light rod 310 to the reflector glass socket 311. Light 100 will be emitted.

4 (a) is a brick type light collecting device using a double biscuit Fresnel lens and a reflecting surface of the light collecting means of the present invention in pairs;

4 (b) is a structural diagram of a brick-type light collecting device using a double-paired Fresnel lens and reflecting surfaces 1 and 2 which are the light collecting heat means of the present invention, and (b) a light collecting light is collected at a closer distance. Will.

FIG. 4 is a brick-type light condensing and heat collecting device using a light source on the outer wall of the building, and FIG. 4 (a) shows that the light source 100 passes through a Fresnel lens 150 having a secondary reflector (102). The refractive index is refracted by the reflective surface 101 to the brick-type primary reflector 160 at a refractive index.

The reflected heat source is refracted and reflected back to the secondary reflector 102 attached to the Fresnel lens to be recruited to the lens 130 attached to the brick primary reflector 106 and the optical fiber 105 in the guide groove 131. Condensing heat guide nut 108 is connected to the refractive index distance 162 between the lens and the reflector by mounting the connection panel 161 to form a brick-type light collector. 4 (b) is composed of a composite type in which Fresnel lenses 150 and 151 are paired, so that the light source guide groove 104 is collected closer to the brick-type primary reflector 160 to be transferred to the optical fiber 105. Will be.

More specifically, the light source 162 refracted by passing the light source 100 through the Fresnel lens 151 transports the transmissive layer 162 and approaches the secondary Fresnel lens 150 to which the reflector is attached. The brick-shaped primary parabolic reflector 160 is densely refracted and reflected to the secondary reflector 102 attached to the secondary Fresnel lens as the guide lens 104, and the condenser guide nut 107 and the optical fiber 105 Mounting is connected.

4 (a) (b) has described the structure of a batch collecting device for condensing light.

5 is a light source short-term recruiting concentrator device structure that is a storage commercial means of the present invention, the light sources collected from the concentrator 120 to the optical fiber 105 are collected by the light source guide terminal switch 500 and are accumulated and collected again. High density storage at 404.

The place where the light source is temporarily stored and imported, stored and discharged as much as the amount of light required for use. The light source short-term recruitment reservoir 400 is introduced into the short-term recruitment reservoir inlet 407 introduced into the optical fiber 105 and temporarily stored in the large glass reflector 402, and the light source measuring instrument 488 is attached.

Light-heat collection 408 to protect the temporarily stored glass reflector 402 is a gypsum board or synthetic fiber barrel 408 with excellent insulation, between the vacuum or argon between the light source short-term recruitment reservoir 400 ) Is of stainless steel or steel construction.

There is a vacuum or argon 409 between the light source short-term recruitment reservoir 400 and the light heat collection unit 402.

The light source short-term recruitment storage 400 is introduced into the short-term recruitment storage inlet 407 and imported and blocked by the blocking shotter 406 to be stored and discharged 407.

6 is a light source access control terminal switch 500 of the present invention as being guided to the equipment used as a light source access control terminal switch 500 to find a way that the light source introduced into the glass fiber or optical cable path 105 is required. The light source access control terminal switch 500 is formed by coating a reflector mirror on porcelain and glass 502 and 504 on a fireproof material 501 whose structure 501 is well insulated, and thus the terminal outside 501 and the terminal inside 505. Insulation and fire resistance and a reflector, and the terminal hole 503 is a vacuum or a large optical fiber 503.

The optical fiber 105 introduced into the optical cable 520 flows into the inner guide groove 507 from the entrance guide groove 506.

The incoming light energy is dispersed in each direction, and is moved according to the adjustment function of the opening and closing of the light source terminal switch 500.

The light source terminal switch 510 has a light output knob 511, an adjusting wrinkle groove 513, an elastic regulator 512, a reflector adjusting circuit breaker 514, and an adjusting block 515 in the main body 500. It refers to a device that facilitates the transfer by wearing the light source 100 of the optical fiber 105 in the (520) blocking the opening and closing.

FIG. 7 illustrates that the light source 100 introduced into the optical fiber 105 is dispersed into the light source terminal switch 500 to cause a distributed photoelectric light to the light source hot air balloon 301. 311 is a combination of the light reflecting cap 375 and the semi-permeable cap to adjust the brightness of the eye fatigue.

FIG. 8 is a structure of a light lamp emitting light through a glass tube of the present invention, wherein the concave lens 131 distributes light 100 to the optical fiber 105 coming from the optical cable 250 to the light lamp to guide the optical fiber luminescent material 320. The color and lighting material 321 is applied to the outside of the fluorescent material 320 and gold powder, silver powder, cloisonne 315 and the like are included in the luminescent material 320 to make an environmental light. The extra light source 100 is collected into the convex lens 130 in the glimmer 320 socket and used to return to the reverse optical fiber 125.

9 is used as a commercial neon sign in the translucent box of the present invention, a plurality of optical fiber cable 350 is guided to the neon light box, and a plurality of photoelectric light 301 is mounted up and down for each of the several optical fibers. Neon sign light box 330 is the back side is composed of a reflector and the light box translucent surface 325 is to be attached to the translucent advertisement 325.

FIG. 10 is a diagram illustrating an embodiment of a colored glass bead double reflector lamp equipped with a motor of the present invention, in which a motor 610 is built into a table lamp 600 in constructing a table lamp 600 using an optical cable 250 from which a light source is imported. Install the light source temporary reservoir 620 on the imported optical cable 250, install the light source temporary reservoir outlet 615, and insert dozens and hundreds of optical fibers 105 into the installed outlet 615 according to the purpose and design. do.

At the end of the optical fiber 105, various colored glass beads 601 form a variety of colors.

The primary translucent reflector 602 is configured on the front surface of the colored glass beads 601 and the secondary reflector 603 is installed on the rear surface of the glass to illuminate beauty.

In addition, when the electric cord 611 is inserted into the table lamp motor 610, a beautiful table lamp is a series of procedures.

Fig. 11 is a rosary lamp that combines a light source of the present invention with a lens, a luminescent glass, and a semi-transparent color cover support mirror.

The optical fiber 105 in the optical cable 250 is introduced and the light source 100 is dispersed by the light scattering concave lens 131. The rosary lamp 605 is installed as a concave groove, and the rosary lamp 605 is covered with a translucent collar cover 606 and the reflecting cap 607 supports the light and the extra light source is a convex lens 130. Is recruited to the optical fiber 105 in the optical cable 250.

The rosary lamps mounted in this way form various colors and several lamps.

12 is a combination of the illumination color glass hot air balloon of the present invention will be described in detail as follows.

The light source 100 introduced into the optical fiber 105 of the optical cable 250 illuminates the multi-colored fluorescent light, which is made of glass in its structure, and immediately before the light source goes straight, the guiding glass 651 has the shape of the head. Induce straight movement.

As the light source moves, the uneven color colored glass 652, 653, 654, 655 is illuminated. There is a reflector cover 660 that protects the luminescent material above the combined illumination light device 650.

13 is a high temperature heating apparatus combining various light emitters of the present invention.

As the light source transferred to the optical cable 250 flows into the straight guide glass 651, the light source 250 emits high-temperature heat while radiating into the uncovered optical fiber glass tubes 310, 680, 681.

Uncoated light heat rod glass tube 310, 680, 681 The heat engine and the connecting portion has a light inlet 651 and the light outlet 670, and connects the uneven portion 651, 670 and the uneven portion connecting a plurality of hot air balloon There is an optical fiber glass 105, which is used for heating and heating the hot air balloon.

FIG. 14 illustrates an electrical switching device of a light source in a light source box of the present invention in detail by drawing an optical cable 250 in a silicon box 700 as a device for obtaining electricity by recruiting a light source to the silicon box 700. . A guide connector 702 is attached to the silicon box inlet, and an uneven light injector glass 701 is installed to expose the unshielded light glass 710 into the silicon box, and a reflector 711 is attached to the end of the light glass.

A silicon P-type layer 720 is formed next to the wall of the silicon light source box 700, and a silicon n-type 730 layer is grounded with a current line on the back side of the silicon to obtain silicon P-type 720 and n-type 730. The current is recruited to the current line cathode 740 and the anode 741 and the current load 750 is stored for a long term to the storage battery 760.

As described above, the light source equipment that condenses the solar light source and uses it as energy is an invention that is useful for various purposes in daily life, such as recruitment of light sources, flow of energy, equipment, and electricity.

Claims (14)

As a device for condensing the solar light source 100, a plurality of light collectors are mounted as shown in FIG. 1, and the light collectors 120 are arranged on a lattice ladder 109 to move the light collectors along the altitude of the light source. Since the sun moves in parallax, the east-west rotation parallax rotators 121 and 123 move and multiple condenser poles 110 and the optical cable optical fiber 105 are multiplied and recruited to the light source collector 200 and the light source temporary storage chamber 205. . The light source unit 300 and the silicon box 700 are transferred from the light source entrance 206 of the light source temporary storage chamber 205 to the optical fiber 105 and temporarily stored in the light source temporary storage 400, and then, in the light source terminal switch 500. To obtain daily heat sources and electrical energy A light collector using a first and second reflector, which is a light collecting means for collecting light sources, as shown in FIG. 2, is equipped with a secondary reflector 102 at the center of the arrow 106 in the primary reflector 101. The light source 100 is guided to the light source guide 131 using the lens 103 at the gathering point, and the glass fiber 105 and the light source guide 131 are connected to the fixing nut 133 and the connecting nut 132. Devices characterized by being interlocked with Paragraph 2 is used as a light collecting device using a parabolic glass hemisphere 1 and a secondary reflector to increase the cleaning effect of impurities such as dust, and a parabolic glass light collecting unit 140 is used to guide the light source 100 to the light collecting heat guide groove 104. Mount several like tiles on the exterior wall of the building. In the glass hemisphere collector, the reflective material is coded on the parabolic reflecting surface 101 of the glass collector 140 and the reflective material is coded on the parabolic concave surface 102 of the front plane. The light source 100 passed through the glass collector 140 is a light source guide groove 104, and the light source 100 collected on the glass parabolic reflecting surface 101 and the secondary glass parabolic reflecting surface 102 is transferred to the optical fiber 105. And emit light heat and light 100 to the reflector glass socket 311 with a light heat rod 310 The light collecting device is a brick-type light collecting device on the outer wall of the building. In FIG. 4A, the light source 100 passes through the Fresnel lens 150 with the secondary reflector (102) and the light source passes through the brick at refractive index. The heat source reflected on the reflecting surface 101 by the primary reflector 160 and reflected by the second reflector 102 attached to the Fresnel lens is reflexively reflected and attached to the brick primary reflector 160. In the guide groove 131 and the optical fiber 105 and the collecting heat guide nut 108 is connected to the refraction distance 162 between the lens 130 and the reflector 102 by connecting the panel 161 Forming brick collectors In addition, the brick-type light collecting device is provided on the outer wall of the building, and the light source 100 further includes a secondary Fresnel lens 150 in which the light source 100 bisects through the Fresnel lens 151 in FIG. Closer to the secondary Fresnel lens 150 and closer to the secondary Fresnel lens 150, closer to the brick reflector 160, and more closely reflected to the secondary Fresnel lens attached reflector 102, Being guided by the intraocular lens 104 and transported to the optical fiber 105 The light source collected from the light collector 120 to the optical fiber 105 as a light source short-term collection light collector device, which is a commercial means, is collected by the light source guide terminal switch 500 and accumulated and collected again, which is stored in a high-density reflector 404. The light source short-term recruitment reservoir 400 is introduced into the short-term recruitment reservoir inlet 407 introduced into the optical fiber 105, and temporarily stored in the large glass reflector 402, and the light source measuring instrument 488 is attached. The light source short-term recruitment storage 400 and the light heat collection 402 is a short-term recruitment storage is introduced into the retention zone 407 and imported and blocked by the blocking shot 406 to be stored and discharged (407). In Fig. 6, the light source access control terminal switch 500 is guided to the equipment used as the light source access control terminal switch 500 to find the required path for the light source introduced into the glass fiber or the optical cable 105. The terminal switch 500 is formed by coating a reflector mirror on porcelain and glass 502 and 504 on a fireproof material 501 whose structure 501 is well insulated. The reflector and the terminal hole 503 are made of a vacuum or a large optical fiber 503. The optical fiber 105 introduced into the optical cable 520 is introduced into the internal guide groove 507 from the entrance guide groove 506 and the optical energy introduced is distributed in each direction, where the opening and closing of the light source terminal switch 500 is performed. It is transferred according to the adjustment function. The light source terminal switch 510 includes a light outlet knob 511, an adjustment wrinkle groove 513, an elastic regulator 512, a reflector adjustment breaker 514, and an adjustment block 515 in the main body 500. Apparatus for smoothing the transfer and blocking the opening and closing of the light source 100 of the optical fiber 105 in 520 In FIG. 7, the optical fiber 105 includes an inflow and outflow of the inflowing light source 100 into the light source terminal switch 500 to generate a distributed photoelectric light through the light source hot air balloon 301, and a socket between the photoelectric light 301 and the optical fiber cable. 311), a combination of a light reflecting cap 375 and a photoelectric lamp and a translucent cap for controlling the brightness of eye fatigue lamps. 8, the concave lens 131 disperses the light 100 in the optical fiber 105 coming from the optical cable 250 to the optical light, and guides the optical light to the optical fiber luminescent material 320. 320, the color and the lighting material 321 is applied to the outside, and the gold powder, silver powder, cloisonne 315 and the like are included in the interior lighting. In addition, the extra light source 100 is collected by the convex lens 130 in the socket of the luminescent material 320 and is used as the reverse optical fiber 125, and is accumulated again by returning. In FIG. 9, as a commercial neon sign is used in a translucent box, a plurality of optical fiber optical cables 350 are guided to a neon sign, and a plurality of photoelectric lamps 301 are fixed up and down for each of several strands of optical fibers. Neon sign shine box 330 is the back side is composed of a reflector and the shine box translucent surface 325 is to be attached to the translucent advertisement 325. As shown in FIG. 10, the motor-mounted colored glass bead double reflector lamp is an embodiment in which a motor 610 is built in the table lamp 600 in order to construct the table lamp 600 using the optical cable 250 in which the light source is imported. Install the light source temporary reservoir 620 in the optical cable 250, install the light source temporary outlet 615, and insert into the dozens and hundreds of optical fibers 105 according to the purpose and design to the installed outlet 615 and the optical fiber ( 105) At the end of the exposure, various colored glass beads 601 are made in the shape of various colors. In addition, the primary semi-transparent reflector 602 is configured on the front of the colored glass beads 601 and the secondary reflector 603 is installed on the rear to form a table lamp. In FIG. 11, a bead-type illuminator in which a light source is combined with a lens, a luminescent glass, and a translucent color covered mirror, in an embodiment, the optical fiber 105 in the optical cable 250 is introduced and the light scattering concave lens 131 is used as the light source 100. ) Will be distributed. It is installed as a recess of the rosary type lighting 605, and the translucent color cover 606 is covered on the rosary lighting 605, the rear portion of the reflecting cap 607 supports the lighting, and the extra light source is connected to the convex lens 130 Is recruited to the optical fiber 105 in the optical cable 250 In FIG. 12, in the embodiment of the illumination lamp in which the illumination color glass hot air balloon is combined, the light source 100 introduced into the optical fiber 105 of the optical cable 250 illuminates the multi-color fluorescence fluorescent lamp is made of glass. As the light source goes straight, the straight guide glass 651 induces a straight motion for barrel development to the head. As the light source moves, the uneven colored glass 652, 653, 654, 655 shine illumination. Also provided with a reflector cover 660 that protects the luminescent material above the combined illumination luminaire 650. In FIG. 13, in the high temperature heating apparatus embodiment in which various light emitters are combined, the light source transferred to the optical cable 250 flows into the unguided optical fiber glass tubes 310, 680 and 681 while flowing into the straight guide glass 651. Lighting and heating effect while dissipating the heat of the unshielded fiberglass glass tube 310, 680 heat engine and the connection portion has a light inlet 651 and the light outlet 670 and the uneven portion 651 connecting a plurality of hot air balloon ) 670 is used for the heating of the hot air balloon because there is an optical fiber glass 105 connecting the uneven portion. In FIG. 14, an optical cable 250 is injected into a silicon box 700 as a device for obtaining electricity by recruiting a light source to a silicon box 700 as an electric switching device 700 of a light source in a light source set box and guiding the silicon box injection hole. The connection part 702 is attached, and the uneven light injector glass 701 is installed, and there is an uncovered light glass 710 in a silicon box, and the reflector 711 is attached to the end of the light glass. In addition, a silicon P-type layer 720 is formed next to the wall of the silicon grouping box 700, and a silicon n-type 730 layer is grounded with a current line on the back side of the silicon, thereby obtaining a current obtained by the silicon P-type 720 and n-type 730. It is recruited to the current line cathode 740, the positive electrode 741, the long-term recruitment of the current load 750 to the storage battery 760.