JP2011087416A - Solar thermal power generator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a heat collecting solar thermal power generator generating power by collecting solar heat in a thermoelectric generating element that converts heat into power. <P>SOLUTION: The solar thermal power generator obtains power by collecting the solar heat using a thermoelectric generator for converting the solar heat into the power and a reflecting panel. The solar thermal power generator includes a heat collector for collecting the solar heat by the reflecting panel. The heat collector is formed of a thermoelectric transducer and a cooler. In the solar thermal power generator, the cooler is mounted on a surface opposite to the surface facing the reflecting panel of the heat collector, and the cooler is formed of a cooling pipe. In the solar thermal power generator, a heat-transport medium is circulated and flows in the cooling pipe, and the heat-transport medium is circulated and flows by a pump from a cooling storage tank. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a heat collection type solar thermal power generation apparatus that collects solar heat and generates power in a thermoelectric generation element that converts heat into electric power.

  When power is generated using sunlight, since solar rays contain heat rays, solar thermal power generation devices that use the heat rays have been developed in the past. The conventional solar thermal power generation apparatus is configured by arranging thermoelectric power generation elements in a flat plate shape to constitute a power generation panel module, and arranging a large number of the power generation panel modules facing the sun. Therefore, in this type of power generation system, a power generation panel module is spread over the entire surface that receives sunlight.

  Therefore, for example, the invention described in Patent Document 1 has a configuration including valve means for keeping the cooling water surface of the cooling water tank of the thermoelectric generator constant. The invention described in Patent Document 2 has a configuration in which only part of the light is incident on the solar cell, so that all the sunlight does not enter the solar cell. The invention described in Patent Document 3 is also provided with means for generating a magnetic field in a predetermined gap of the thermoelectric generator. Furthermore, the invention described in Patent Document 4 also includes a hollow pipe for the heat exchange layer of the thermoelectric generator. In addition, although the invention described in Patent Document 5 describes a solar / heat combined power generation device, the solar cell directly irradiated with solar heat is limited to a compound solar cell, so the cost of the device There was a problem that became high.

Japanese Patent Application Laid-Open No. 05-343751 JP 11-31835 A Japanese Patent Laid-Open No. 08-46246 JP 2001-153470 A Japanese Patent Laid-Open No. 10-110670

  In the conventional solar thermal power generation apparatus and the solar power generation apparatus described above, there is a problem that sufficient efficiency for obtaining target power is not obtained. Further, if sufficient electric power is obtained, the apparatus becomes large and the cost increases.

  Further, as described in Patent Documents 1 to 5, if an attempt is made to obtain sufficient efficiency for obtaining the target power in each device, the size of each device increases, and the cost is still unsolved. There are actual technical issues to be addressed.

  The present invention has been made based on the above technical background, and an object of the present invention is to provide a heat collecting power generation apparatus that collects solar heat and generates power in a thermoelectric power generation element that converts heat into electric power. It is what.

  In order to achieve the above object, the invention of claim 1 is directed to a thermoelectric generator that converts solar heat into electric power, and a solar thermal power generation device that obtains electric power by concentrating solar heat using a reflective panel. The thermoelectric generator that collects heat is provided, the thermoelectric generator is formed of a thermoelectric conversion element and a cooling unit, and a cooling unit is provided on a surface of the condensing unit that is opposite to the surface facing the reflective panel. The cooling part is formed by a cooling pipe, and a heat transport medium is circulated and flown inside the cooling pipe. The heat transport medium is circulated and flowed through the cooling pipe by a pump from a cooling storage tank. It is characterized by being.

  A second aspect of the present invention is the solar thermal power generation apparatus according to the first aspect of the present invention, wherein the cooling pipe is made of metal.

  A third aspect of the invention is a solar thermal power generation apparatus according to the first or second aspect of the invention, wherein the heat transport medium is made of water.

  According to this invention, electric power can be obtained when the thermoelectric generator that converts solar heat into electric power concentrates the solar heat with the reflection panel.

  Further, as in the invention of claim 2, the cooling pipe is made of metal, so that the configuration of the entire apparatus can be simplified.

  And as invention of Claim 3, since the said heat transport medium is comprised with water, the cost for cooling is reduced.

It is the perspective view and partial enlargement which show the typical structure which shows the whole image of this invention. It is a sectional side view which shows typically the condensing panel and condensing part of this invention. It is a graph which shows the basic characteristic of the polyethyleneglycol used by this invention.

  Embodiments of the present invention will be described below with reference to the drawings. The power generation apparatus of the present invention is configured to convert solar heat into electric power, and is particularly configured to efficiently generate power by concentrating heat on a power generation unit that converts heat into electric power. Thermoelectric conversion is configured by a TEG (thermoelectric generator). And the heat collection with respect to an electric power generation part may be performed by reflection, or may be performed by refraction. The reflection panel for collecting heat by the former reflection may be a large number of plane mirrors, or may be a parabolic reflection mirror or a semi-cylindrical reflection mirror. When collecting heat by the latter refraction, for example, a lens such as a Fresnel lens may be used.

  The first embodiment will be described with reference to FIG. 1. A thermoelectric generator 2 is disposed at a focal position by a reflective panel 1 having a parabolic cross-sectional shape. And this TEG3 is arrange | positioned in the position of the focus of the reflective panel 1 so that it may heat-collect in TEG (Thermoelectric generator) 3 (henceforth TEG3) which is a thermoelectric conversion element which comprises this thermoelectric generation part 2. Yes. The relative position between the reflective panel 1 and the TEG 3 is preferably fixed, and the thermoelectric generator 2 is supported by a frame 4 that supports the reflective panel 1. Here, TEG3 is composed of bismuth tellurium as its material.

  The reflection panel 1 is arranged so as to face the sun, so that the installation angle is adjusted by a tracking device (or a heliostat) (not shown) so as to follow the movement of the sun. Moreover, since the angle of the reflective panel 1 is sequentially changed so as to track the sun, the heat collection state with respect to the TEG 3 is always maintained. However, since it is possible to generate heat at an approximate focus of solar heat without always collecting solar heat accurately, strict adjustment of the reflective panel 1 is not necessary.

  The reflection panel 1 has a so-called semicylindrical shape in which a large number of parabolic reflectors 1a are arranged in the longitudinal direction and extend. A pipe 5 connected to the TEG 3 which is a thermoelectric conversion element is disposed on the surface of the reflective panel 1 on the side where the sunlight is reflected and irradiated along the longitudinal direction of the reflective panel 1. The pipe 5 is composed of a flexible metal (for example, copper) pipe or a plastic pipe. The pipe 5 is filled with water (cooling water) or cooling liquid (not shown) so that it can circulate and flow.

  A cold storage material for cooling the water filled so as to be able to circulate and flow in the pipe 5 is sufficiently stored in the cooling storage tank 6. The cooling storage tank 6 is formed with fins 7 to enhance the cooling effect. The cooling water is configured to circulate and flow in the pipe by, for example, the electric pump 8. The pipe | tube arrange | positioned in this cooling storage tank 6 is comprised with the metal pipe (for example, copper pipe). The cold storage material is formed of PEG (polyethylene glycol) described later. In particular, this cold storage material is formed using PEG # 1000. Although the cooling storage tank 6 is arranged near the reflection panel 1 in the drawing, it is actually arranged at a position shielded from direct solar heat.

  When the thermoelectric generator 2 is shown in an enlarged view of the same figure, a TEG 3 that is a thermoelectric conversion element is arranged on the lower surface of the thermoelectric generator 2, that is, the focal direction of the reflective panel 1. And let the upper side part which is a side surface opposite to TEG3 which is the lower surface of the thermoelectric generation part 2 be the cooling pipe 9. FIG. The cooling pipe 9 is made of metal (for example, copper). The cooling water is configured to circulate and flow inside the cooling pipe 9.

  The operation of the thermoelectric generator having the above configuration will be described. The TEG 3 is arranged below the thermoelectric generator 2, that is, in the focal direction of the reflective panel 1. The TEG 3 on the lower side surface of the thermoelectric generator 2 and the cooling pipe 9 on the opposite side surface cause a temperature difference by circulating the cooling water therein. At this time, it is necessary to change (accelerate) the flow rate of the cooling water for cooling the TEG 3 having a higher temperature by the electric pump 8. And electric power generate | occur | produces by the Seebeck effect by the temperature difference of TEG3 which is the lower surface of the thermoelectric generation part 2, and the cooling pipe 9 which is the opposite side surface. And the cooling storage tank 6 may cool the cool storage material with which the inside is filled through the fin 7 etc. in the time slot | zone when solar heat is not irradiated, for example, at night.

  Next, a second embodiment is shown. The second embodiment will be described with reference to the drawing (FIG. 1) or FIG. 2 of the first embodiment. The second embodiment is an example in which the TEG 3 constituting the thermoelectric generator 2 is collected by the reflection panel 1 having a parabolic cross section as shown in FIG. The TEG 3 is arranged at the position. The relative positions of the reflective panel 1 and the TEG 3 are preferably fixed, and the thermoelectric generator 2 is also supported by the frame 4 that supports the reflective panel 1.

  The reflection panel 1 is arranged so as to face the sun, so that the installation angle is adjusted by a tracking device (or a heliostat) (not shown) so as to follow the movement of the sun. Moreover, since the angle of the reflective panel 1 is sequentially changed so as to track the sun, the heat collection state with respect to the TEG 3 is always maintained.

  The reflection panel 1 has a so-called semicylindrical shape in which a large number of parabolic reflectors 1a are arranged in the longitudinal direction and extend. The TEG 3 is disposed at the focal position of the reflection panel 1 on the surface on the side where the solar heat is reflected and irradiated along the longitudinal direction of the reflection panel 1. And the cooling pipe 9 is arrange | positioned in the position used as the opposite side surface of the TEG3. As described above, the cooling pipe 9 is composed of a metal (for example, copper) pipe. The inside of the cooling pipe 9 is filled so that cooling water or cooling liquid (not shown) can circulate and flow.

  A cool storage material for cooling the water filled so as to be able to circulate and flow in the cooling pipe 9 a is sufficiently stored in the cooling storage tank 6. The cooling storage tank 6 is formed with fins 7 to enhance the cooling effect. The pipe | tube arrange | positioned in this cooling storage tank 6 is comprised with the metal pipe (for example, copper pipe). The cooling water is configured to circulate and flow in the cooling pipe 9a by the electric pump 8, for example. The cooling storage tank 6 is arranged near the reflection panel 1 in the drawing, but is actually arranged at a position shielded from direct sunlight.

  When the cooling pipe 9 is shown in FIG. 2, the TEG 3 is arranged on the lower side of the cooling pipe 9 constituting the thermoelectric generator 2, that is, on the focal direction of the reflection panel 1. And the cooling pipe 9 which is the side opposite to the TEG 3 of the thermoelectric generator 2 is configured such that the cooling water circulates and flows through the inside 9a.

  The operation of the power generation device having the configuration of the second embodiment will be described. For example, the cooling water is forcibly circulated and flowed by, for example, the electric pump 8 provided at one end of the pipe 5 extending from the cooling storage tank 6. As described above, the circulating and flowing cooling water needs to change (fasten) the flow rate of the cooling water for cooling by the electric pump 8 with respect to the TEG 3 having a higher temperature. Then, the cooling water flows through the inside 9 a of the cooling pipe 9, thereby cooling the TEG 3 that is a heat conversion element by irradiation of solar heat from the reflective panel 1 and the cooling pipe 9 on the opposite side. Electric power is generated by the Seebeck effect due to the temperature difference between the lower surface (TEG 3) and the upper surface (cooling pipe 9) of the thermoelectric generator 2.

  A table of basic characteristics of PEG (polyethylene glycol) is shown in FIG. Of the PEG shown in this figure, PEG # 1000 mainly constitutes the regenerator material of the present invention.

  DESCRIPTION OF SYMBOLS 1 ... Reflection panel, 2 ... Thermoelectric generator, 3 ... TEG, 4 ... Frame, 5 ... Pipe, 6 ... Cooling storage tank, 7 ... Fin, 8 ... Electric pump, 9 ... Cooling pipe.

Claims (3)

In a solar power generation device that obtains electric power by concentrating solar heat with a reflective panel, and a thermoelectric generator that converts solar heat into electric power,
The thermoelectric generator that collects solar heat by the reflective panel is provided, and the thermoelectric generator is formed of a thermoelectric conversion element and a cooling unit,
A cooling part is provided on the surface opposite to the surface facing the reflection panel of the light collecting part, the cooling part is formed by a cooling pipe, and a heat transport medium is circulated and flown inside the cooling pipe,
The solar thermal power generation apparatus, wherein the heat transport medium is configured to circulate and flow in the cooling pipe by a pump from a cooling storage tank.   2. The solar thermal power generation apparatus according to claim 1, wherein the cooling pipe is made of metal.   The solar thermal power generation apparatus according to claim 1, wherein the heat transport medium is made of water.

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