KR200430489Y1 - Solar photovoltatic power genertion installation - Google Patents

Abstract

The present invention relates to a power generation device using solar light, and a plurality of condensing parts forming a light path with a concave mirror, a convex mirror, and a reflecting mirror so as to focus the sunlight, and solar heat transmitted by the condensing part. A storage tank is formed to connect the light path to the glass partition so that the light path is closed. The heat medium is filled in the storage tank. When the heat medium of the storage tank is evaporated, the heat medium is formed by the pressure difference between the inside and the outside of the storage tank. A storage unit formed at the bottom of the filling tube for filling, a power generation unit formed above the storage tank so as to generate electricity by rotating a power generation turbine by evaporation of the heat medium heated in the storage unit, and the power generation unit The electrolysis of the heat medium using the power generated by driving the power generation turbine to increase the amount of evaporation An inner insulating box is formed on the inside of the book and an inner insulating box is formed on the bottom side of the outer insulating box. One end of the medium supply pipe is fixed inside the inner insulation box of the electrolysis part and the other end, and the other end is fixed to the outer insulation box so that the heat medium is supplied by the hydraulic pressure difference, and the medium when the supplied heat medium reaches a certain level. It is characterized by consisting of a control unit formed a float that can close the supply pipe.

Description

SOLAR PHOTOVOLTATIC POWER GENERTION INSTALLATION

1 is a schematic view showing a power generation device using solar according to the present invention,

Figure 2 is a schematic diagram showing another embodiment of the power generation device using solar according to the present invention,

Figure 3 is a schematic diagram showing another embodiment of the power generation device using solar according to the present invention,

Figure 4 is a schematic view showing another embodiment of the power generation device using solar according to the present invention,

5 is a state diagram of use of the power generation apparatus using solar according to the present invention.

<Description of Symbols for Main Parts of Drawings>

10 condenser 11 concave mirror

12: convex mirror 13: reflector

14 optical path 15 optical fiber

20: storage 21: glass partition

22: storage tank 23: heat medium

24: filling pipe 30: power generation unit

31: power turbine 40: electrolysis unit

41: outer insulation box 42: inner insulation box

43: partition wall 44: anode tube

45 cathode tube 46 lightning rod

47: condensation tube 50: control unit

51: medium supply pipe 52: float

The present invention relates to a power generation device using solar light, and more specifically, by using the radiant energy of the sun, the power generated by turning the power turbine into a steam generated by increasing the temperature of water stored in the storage tank. The present invention relates to a solar power generator that can obtain more electric power by the air pressure of hydrogen and oxygen generated by electrolyzing water using electric power.

In general, solar energy is collected efficiently by moving heat engines and generators to create electrical energy. Solar power is a solar energy source that generates wind in the broad sense and causes meteorological phenomena in the atmosphere to allow water to move. Both hydro and wind power can be referred to as solar power, but most of them refer to the direct generation of solar power.

The photovoltaic power generation method as described above includes a top light focusing method and a parabolic light focusing method.

In the tower condensing method, a water tank is installed on a high tower, and numerous reflectors are installed around the tower to heat the water in the water tank with reflected sunlight. At this time, a turbine is generated by steam generated from the water tank. to be.

In addition, the parabolic condensing method is a method of obtaining steam by installing a conduit through which water flows in the focal position of the parabolic mirror arranged in a line toward the sun.

Another method is the use of solar cells, which are attached to satellites and space probes and play an important role in supplying power to them. Although it has been tested, the efficiency is still low, so it has not reached the level of practical application.

Therefore, the top condensing method or the parabolic condensing method is used, but the structure is complicated and there is a problem in that it is difficult to obtain energy in the winter or rainy season with a small amount of insolation.

The present invention has been devised in view of the above-mentioned problems of the prior art, by using the radiant energy of the sun effectively, the power generated by turning the turbine into a steam generated by raising the temperature of the water stored in the storage tank. More power can be obtained by the air pressure of hydrogen and oxygen generated by electrolyzing water using the above power, and solar energy that can obtain electric energy even when the amount of insolation is low by using lightning or external power generated during the rainy season. The purpose is to provide a power generation device using.

In order to achieve the above object, the present invention forms a concave mirror that is open upward to condense sunlight, and forms a convex mirror near the solar focal point of the concave mirror, and collects sunlight by the convex mirror. A plurality of condensing portions forming a light path for transmitting sunlight by forming a reflector in a bent portion bent at right angles to pass through the light, and the light path is a glass partition so as to transmit the solar heat of the sunlight transmitted by the condensing portion A storage tank is formed to be closed and connected. The storage tank is filled with a heat medium, and when the heat medium of the storage tank is evaporated, a storage part having a filling tube filling the heat medium by a pressure difference between the inside and the outside of the storage tank is formed on the bottom surface. And, by rotating the power turbine by the evaporation of the heat medium heated in the storage unit to generate electricity An external insulation box is formed on the inner side of the storage unit so as to increase the evaporation amount by electrolyzing the heat medium by using the power generation unit formed above the storage tank of the unit and the power generated by driving the power generation turbine of the power generation unit. An inner insulation box is formed inside the outer insulation box and a separation wall is formed inside the outer insulation box to form an anode tube and a cathode tube on both sides of the separation wall; One end of the medium supply pipe is fixed and the other end is fixed to the outer insulated box is supplied with a heat medium by the hydraulic pressure difference, and when the supplied heat medium reaches a certain level consists of a control unit formed a float to close the medium supply pipe It provides a power generation device using solar light, characterized in that.

The power supply of the electrolysis unit is connected to the cathode tube to form a lightning rod so that power is supplied by a lightning strike, and a condenser capable of coagulating the gas generated by the electrolysis unit to a power generation turbine. It provides a power generation device using solar light, characterized in that formed in the optical path of the light collecting portion is an optical fiber.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention as described above in detail as follows.

1 is a schematic view showing a power generation device using solar according to the present invention, Figure 2 is a schematic view showing another embodiment of the power generation device using the solar according to the present invention, Figure 3 is a solar light according to the present invention 4 is a schematic view showing another embodiment of the power generation device used, Figure 4 is a schematic view showing another embodiment of the power generation device using the solar according to the present invention.

As shown therein, the power generation device using the solar light of the present invention forms a plurality of light collecting parts 10 to collect the sunlight.

The condensing part 10 forms a concave mirror 11 in which sunlight is opened upward, and forms a convex mirror 12 near the solar focal point of the concave mirror 11 and the convex mirror 12. Reflector 13 is formed on the bent portion bent at right angles so that the sunlight collected by the light passes, thereby forming an optical path 14 for transmitting sunlight.

As shown in FIG. 4, the light collecting unit 10 may fill the inside of the light path 14 with the optical fiber 15 in a state in which the reflector is excluded.

The storage unit 20 connected to the light path 14 is formed to transmit the solar heat of the sunlight transmitted by the light collecting unit 10.

The storage unit 20 as described above forms a storage tank 22 connected in a state in which the portion connected to the optical path 14 with the glass partition 21 is closed, and the heat medium 23 inside the storage tank 22. ) Is filled and when the heat medium 23 of the storage tank 22 is evaporated, a filling tube 24 filling the heat medium 23 is formed on the bottom surface by a pressure difference between the inside and the outside of the storage tank 22.

In addition, the power generation unit 30 that generates electric power by the air pressure generated by the evaporation of the heat medium 23 heated in the storage unit 20 is formed.

The power generation unit 30 as described above forms a power generation turbine 31 above the storage tank 22 of the storage unit 20.

Electrolysis to increase the evaporation amount of the heat medium by electrolysis of the heat medium (23) by using a direct current conversion of the power generated by driving the power generation turbine 31 of the power generation unit 30 to the direct current converter (60) The part 40 is formed.

The electrolysis unit 40 forms an outer insulation box 41 on the inner side of the storage unit 20 and an inner insulation box 42 on the lower side of the outer insulation box 41. A partition wall 43 is formed inside the outer insulation box 41 to form an anode tube 44 and a cathode tube 45 on both sides of the partition wall.

As shown in FIG. 2, the electrolysis unit 40 forms a lightning rod 46 so that electric power is supplied using a lightning strike, and when the lightning strikes are transferred to the cathode tube 45, the cathode tube 45 and the anode tube ( A potential difference occurs at 44 so that the current amount of lightning is transmitted to the inner insulation box 41 of the electrolysis unit 40, thereby double the electrolysis of the heat medium.

In addition, as shown in FIG. 3, it is also preferable to form a condenser 47 capable of condensing the gas generated by the electrolysis unit 40 in the power generation turbine 31 of the power generation unit 30.

Inside the inner insulation box 42 of the electrolysis unit 40 is formed an adjusting unit 50 for adjusting the heat medium level of the inner insulation box 42 of the electrolysis unit 40.

The control unit 50 is fixed to one end of the medium supply pipe 51 inside the inner insulation box 42 of the electrolytic unit 40 and the other end is fixed to the outer insulation box 41 is a heat medium ( 23 is supplied and is formed as a float 52 that can close the medium supply pipe 51 when the heat medium to be supplied reaches a certain level.

Referring to the operation and effects of the present invention configured as described above are as follows.

First, the solar light is collected through the light collecting unit 10.

The above-mentioned solar light collects sunlight through a concave mirror 11 having a central core and induces solar heat that is collected toward the center of the concave mirror 11 through a convex mirror 12 installed near a focal point where the sunlight is reflected. do.

The induced solar heat is guided through the light path 14 and reflects the sunlight at right angles through the reflector 13.

Such solar light heats the heat medium 23 embedded in the storage unit 20 through the glass partition 21.

When the heating medium 23 is heated and evaporated in this manner, the heat medium 23 is discharged while turning the power generation turbine 31 of the power generation unit 30 formed above the storage tank 22 of the storage unit 20 by the evaporated air pressure. Create

As described above, the electricity generated by the operation of the power generation turbine 31 is transmitted through the anode tube 44 and the cathode tube 45 of the electrolysis unit 40 and is transferred to the anode tube 44 and the cathode tube 45. By the electricity, the cations and anions of the heat medium 23 vaporize as they become neutral elements or molecules.

For example, when water is electrolyzed, it is separated into oxygen and hydrogen and gasified.

Thus, the power turbine 31 can be strongly rotated and more power can be produced.

By electrolyzing water in this way, hydrogen and oxygen can be obtained through condensation tubes, and sodium hydroxide and chlorine gas can be obtained by electrolyzing sodium chloride.

As described above, when it is decomposed by the electrolysis unit 40 and is reduced in the heat insulating body 23, the inner insulating box 42, the float 52 is lowered and the medium supply pipe 51 is opened while the storage tank of the storage unit 20 is opened. The heat medium 23 in the 22 is moved to the inner insulating box 42 through the medium supply pipe 51 of the adjusting unit 50 and filled.

As described above, when the heat medium moves to the inner insulation box 42 or is evaporated by sunlight, and the heat medium 23 decreases in the storage tank 22, the pressure in the storage tank 22 decreases through the filling tube 24. The heat medium 23 is introduced to produce a current through sunlight.

As described above, the present invention effectively uses the radiant energy of the sun to increase the temperature of the water stored in the storage tank to generate electricity by turning the power turbine into steam generated by electrolysis of water using the above power. By using the hydrogen and oxygen generated by the air pressure can be obtained more power, using the lightning or external power generated during the rainy season there is an effect that can be obtained even when the amount of insolation.

Although the present invention has been illustrated and described with reference to certain preferred embodiments, the present invention is not limited to the above-described embodiments and has a general knowledge in the technical field to which the present invention belongs without departing from the spirit of the present invention. Various changes and modifications may be made by the user.

Claims (4)

The concave mirror 11 is formed to be open upward to collect the sunlight, and the convex mirror 12 is formed near the solar focal point of the concave mirror 11 and the sun collected by the convex mirror 12. A plurality of condensing parts 10 having a light path 14 for transmitting sunlight by forming a reflector 13 at a bent portion that is bent at right angles to allow light to pass therethrough; A storage tank 22 is formed so that the light path 14 is closed and connected to the glass partition 21 so as to transmit solar heat transmitted by the condenser 10, and inside the storage tank 22. When the heat medium 23 is filled and the heat medium 23 of the storage tank 22 is evaporated, the filling tube 24 filling the heat medium 23 by the pressure difference between the inside and the outside of the storage tank 22 is formed on the bottom surface thereof. The formed storage unit 20, The power generation unit 30 formed above the storage tank 22 of the storage unit 20 to generate electricity by rotating the power generation turbine 31 by evaporation of the heat medium 23 heated in the storage unit 20. )Wow, An external insulation box on the inner side of the storage unit 20 to increase the evaporation amount by electrolyzing the heat medium 23 using the power generated by driving the power generation turbine 31 of the power generation unit 30. An inner insulating box 42 is formed inside the lower side of the outer insulating box 41 and a separating wall 43 is formed inside the outer insulating box 41 to form anodes on both sides of the separating wall. An electrolysis unit 40 forming a tube 44 and a cathode tube 45, One end of the medium supply pipe 51 is fixed inside the inner insulation box 42 of the electrolysis unit 40 and the other end is fixed to the outer insulation box 41 so that the heat medium 23 is supplied by the hydraulic pressure difference. When the heating medium reaches a predetermined level, the generator using solar light, characterized in that consisting of a control unit 50 formed of a float 52 that can close the medium supply pipe (51). The power generation device using solar light according to claim 1, wherein the power supply of the electrolysis unit (40) is connected to the cathode tube (45) to form a lightning rod (46) so that electric power is supplied by lightning. The method according to claim 1, wherein the condenser 47 capable of condensing the gas generated by the decomposition of the electrolysis unit 40 is formed in the power generation turbine 31 of the power generation unit 30 using solar light Power generation device. The power generation apparatus using solar light according to claim 1, wherein the optical path of the light collecting part is formed inside an optical fiber.

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