RU2715356C1 - Universal solar thermal power plant - Google Patents

Abstract

FIELD: thermoelectric-power industry.

SUBSTANCE: invention relates to heat and power engineering and can be used for utilization of thermal energy of natural sources, namely for direct transformation of solar energy into electric energy under different conditions. Solar thermal power plant comprises a rectangular plane assembled of rectangular sections, each of which is a photo-heat-tube-thermoelectric transducer coated with a waterproofing film, inside which there is a photocell connected by its rear side to a heat-pipe heat exchanger made in the form of a rectangular housing, the cover and bottom of which are coated from the inside with a grate made of strips of capillary material, partially filled with working fluid, in cavity of grate housing, covers and bottom are interconnected by vertical wicks also partially filled with working fluid and coated with cylindrical casings with triangular slots made on their upper and lower ends and attached to cover and bottom of housing.

EFFECT: invention provides efficiency of universal solar thermal power plant.

1 cl, 7 dwg

Description

The present invention relates to a power system and can be used to utilize the thermal energy of natural sources, namely, for direct transformation of solar energy into electrical energy in various conditions.

A heat pipe solar thermal power plant is known, including a pallet with an opening in the bottom, closed on top by a lid made of a material with high thermal conductivity and coated with photocells, the inner side of which is covered with a grid made of strips of porous material, while the opening of the pallet is connected to the upper end of the vertical pipe, the lower end which is plugged, made of material with high thermal conductivity, immersed in soil to a depth of H, in the center of which a lifting pipe is placed, filled with the aforementioned of porous material, the upper and lower ends of the riser pipe recede from the lower end of the vertical pipe and the inner surface of the pallet cover by a distance Δ, forming gaps, the space of which is also filled with porous material in contact with the lower end and the lattice of the upper cover at the top, and the wall of the vertical pipe is made with vertical corrugations, inside each corrugation there are vertical grooves of length L, each of which has a vertical thermoelectric transducer made of dielectric material with high thermal conductivity, in the array of which there is a contour reinforcement consisting of thermionic elements, which are paired wire segments made of different metals M1 and M2, soldered at the ends between themselves so that their junctions are bent at an angle of 90 ⁰ the wire segments are parallel to each other, forming U-shaped rows, the lower extreme wire segments of each pair of U-shaped rows of thermoelectric converters are interconnected by jumpers, each on top a pair of U-shaped rows, are interconnected electrically through the capacitors, the first and the last of which and the photocells are connected to output collectors, storage unit and the consumer [RF patent №2630363, IPC E 04 C2 / 26, 2017].

The main disadvantages of the well-known heat pipe solar thermal power station are its tight binding to a specific area, which sharply limits the range of its use and reduces efficiency.

Closer to the proposed invention is a marching solar thermal power station comprising a carpet (plane) assembled from rectangular sections, each of which is a photothermal converter coated with a waterproofing film, inside which a solar cell is placed attached with its back to the outer side of the thermoelectric converter housing made of a dielectric material with high thermal conductivity, in the array of which contour reinforcement is placed, consisting of thermionic elements representing paired wire segments made of different metals M1 and M2 are soldered at the ends together so that their junctions are bent at an angle of 90 ⁰ and are located near the outer surface of the housing of the thermoelectric transducer parallel to it, without touching it, and the pair of wire segments themselves are parallel to each other, forming U-shaped rows, extreme wire segments of the extreme U-shaped rows of thermoelectric converters and photocells through their terminals in each vertical row of carpet photothermoelectric converters are interconnected in series through electric capacitors, jumpers with output collectors, the output terminals of which, in turn, are connected to the storage unit [RF Patent No. 2622425, IPC E 04 C2 / 26, 2017].

The main disadvantage of the known camp solar thermal power station is the inability to use the heat generated from the solar cells when generating electricity, which reduces its effectiveness.

The technical result of the invention is to increase the efficiency of the universal solar thermal power station.

The technical result is achieved by a universal heliothermal power plant containing a rectangular plane assembled from rectangular sections, each of which is a phototeplotrubnothermoelectric transducer coated with a waterproofing film, inside of which there is a photocell connected by jumpers to collectors of the same charges and connected with its back to a heatpipe heat exchanger made rectangular housing, the cover and the bottom of which are covered inside the grilles th, made of strips of capillary material partially filled with working fluid, in the cavity of the casing of the grill, the lids and bottoms are interconnected by vertical wicks, also partially filled with working fluid and covered with cylindrical casings with triangular slots on their upper and lower ends and attached to the lid and bottom casing, the inner surface of the lid and the bottom of the casing of the heat pipe heat exchanger, covered with a grid, constitute the zone of evaporation and condensation, respectively, and the wicks form a zone transport, flat thermoelectric converters are adjacent to the outside of the bottom of the heatpipe heat exchanger, radiators are pressed to the outside of the heaters, jumpers with collectors of the same charges of flat thermoelectric converters and photocells, in turn, are connected to the storage unit.

In FIG. 1–7, a universal heliothermoelectric power station (UGTES) is presented: in FIG. 1, 2 - general view and section of the UGTES; in FIG. 3.4 - phototeplotrubnothermoelectric transducer (FTTTEP) and its section; in FIG. 5–7 - the main nodes of FTTTEP.

The proposed universal solar thermal power station (UGTES) contains a plane 1 assembled from rectangular sections, each of which is a phototeplotrubnothermoelectric converter (FTTTEP) 2, covered with a waterproofing film 3, inside which a photocell 4 is placed, connected by jumpers 5 to collectors of the same charges 6, 7 with its back to the heat pipe heat exchanger (TTTO) 8, made in the form of a rectangular housing 9, the lid and bottom of which are covered from the inside with a grill 10, made of strips of capillary material partially filled with working fluid, in the cavity of the housing 9 of the lattice 10, the lids and bottoms are interconnected by vertical wicks 11, also partially filled by working fluid and covered with cylindrical casings 12 with triangular slots on their upper and lower ends and attached to the lid and the bottom of the housing 9, and the inner surface of the cover and the bottom of the housing 9, covered with a grill 10, constitute the evaporation and condensation zones 13 and 14, respectively, and the wicks 11 form the transport zone 15, to the outside on the opposite side of the bottom of the TTTO 8 are adjacent flat thermoelectric converters (PTEC) 16 (for example, Peltier elements), to the outside of which are pressed radiators 17, jumpers 5 with collectors of the same charges 6, 7 of thermoelectric converters 16 and photocells 4, in turn, are connected to storage unit (in FIG. 1–7 not shown).

The proposed UGTES is based on the property of solar cells 4, when exposed to sunlight, to convert the perceived solar energy into electrical and thermal energy [A. from. USSR No. 1603152, IPC F24 J2 / 32, 1990]. Moreover, the use of TTTO 8 for cooling photocells 4 allows you to significantly increase the speed of the heat transfer process compared to the speed of a similar process using conventional heat exchangers, due to the high values of the heat transfer coefficient in the processes of evaporation and condensation. [A. N. Planovsky, P.I. Nikolaev. Processes and devices of chemical and petrochemical technology. - M.: Chemistry, 1987, p. 146; VV Kharitonov et al. Secondary heat and energy resources and environmental protection. - Minsk: Ab. school, 1988, p. 106; Heat pipes and heat exchangers: from science to practice. Collection of scientific. labor. M .: - 1990, p. 22]. Since when the upper surfaces of the PTEC 16 are heated, the working fluid vapor condensates in the TTTO 8 and the outer surfaces are cooled by the radiators 17, different temperatures are set on them, as a result of which thermoelectricity appears in the TEC 16 [S.G. Kalashnikov. Electricity. - M: "Science", 1970, p. 502-506]. At the same time, the three-layer layout of FTTTEP 2 (on the top is photocell 4, in the middle is TTTO 8, below is PTEP 16 allows simultaneous heat removal from photocells 4 at high speed and heat PTEP 16 at the temperature they require also at high speed, generating an additional amount electricity.

UGTES works as follows. The number of FTTTEP 2 included in plane 1 is determined depending on the external conditions of the UGTES installation site (space or air space, surface of the earth, water, temperature, type of external soil, snow or ice cover) and the required power. The UGTES assembly is carried out before its placement, after which the plane 1 is oriented at the installation site by sunlight and connected to the consumer (not shown in Figs. 1–7). The installation site of UGTES can be: outer space or air space, the outer surface of the soil, snow, ice or water surface (not shown in Figs. 1–7). At the same time, depending on the installation location, TTTO 8 uses different types of working fluid, namely, in areas of hot climate, you can use ordinary water as a working fluid, in moderate and cold areas - aqueous solutions of diethylene glycol, in air and space - liquid ammonia or aqueous ammonia solutions.

After installing the UGTES, the outer surface of the photocells 4 FTTTEP 2 is heated by the sun's rays, generating electricity, and the lower surface of the photocells 4 is cooled as a result of contact with the cover of the TTTO 8 and heats it, giving off the heat released as a result of the generation of electricity. When heating the lid of the housing 9, the working fluid evaporates in the cells of the grating 10 located in the wicks 11 and the capillary material of the grating 10, which transports the working fluid into the evaporation zone 13 (the inner surface of the cover of the casing 9, located in the cells of the grating 10) through the triangular slots of the cylindrical shells 12, resulting in steam. Moreover, coating with a grating 10 made of strips of capillary material and forming a cell on the inner surface of the lid of the housing 9 prevents the formation of a vapor film on it and thus intensifies the evaporation process. The resulting vapor fills the vapor space of the TTTO cavity 8 and condenses in the condensation zone 14, namely, in the cells of the grating 10 on the inner surface of the bottom of the housing 9 covered by the grating 10, which also reduces the thickness of the condensate film on it and, thus, intensifies the condensation process. The condensate formed is absorbed by the capillary material of the strips of the grill 10 connected to the wicks 11 of the transport zone 15 through the triangular slots on the lower edges of the cylindrical shells 12, it is transported by the wicks 11 to the cover of the housing 9 and distributed through the triangular cuts of the shells 12 by the grill 10 along the inner surface of the housing cover 9, after whereby the cycle repeats. In this case, the process of heat exchange with hot and cold media proceeds at a speed many times higher than the speed of a similar process in conventional heat exchangers, due to the high values of the heat transfer coefficient in the processes of evaporation and condensation. At the same time, the condensation heat of the working fluid is transmitted through the bottom of the housing 9 TTTO 8 is transferred to the PTEC 16, heating them, due to which there is a uniform heating of their inner surface. Since the outer surface of the PTEC 16 is equipped with radiators 17, and the outside temperature of the medium is much lower and equal to t _C , a significant temperature difference is created between the temperature of the outer surface of the TEC 16 t _P and the temperature of the medium (t _P - t _C ), as a result of which the process takes place between them heat transfer. The created temperature difference between the heating and cooling zones in the PTEC 16 causes them to emit electrons and the appearance of thermoelectricity in them. Received electricity in photocells 4 and thermoelectricity of PTEC 16 through jumpers 5 and collectors of the same charges 6, 7 (the location of jumpers 5 and collectors 6, 7 in Figs. 1–7 is shown conditionally) enters the storage unit and to the consumer (in Figs. 1–7 not shown).

At the same time, although the upper surface of the FTTTEP 2 is heated less by sunlight in winter than in the summer, during this period the lower surface of the PTEP 16 cools much more than in the summer due to the lower temperature of the soil surface (snow, ice, water) and therefore, the magnitude of the temperature difference (t _P - t _C ) and the generated thermoelectricity in PTEC 16 can also be significant.

The magnitude of the difference in electric potential at the current outputs of the collectors of the same charges of a phototeplotrubnothermoelectric transducer, the strength of the electric current depend on the duration and intensity of solar radiation, temperature and other characteristics of the external environment, the characteristics and number of solar cells, the working fluid in the heatpipe heat exchanger, the characteristics and number of planar thermoelectric converters and radiators. The resulting electric current can be used to service various technical devices, as well as heating and lighting temporary residential and industrial premises.

Thus, the proposed universal solar thermal power station provides both in summer and winter time, on land, in air or in outer space, the utilization of solar energy, heat and cold of the environment (air or outer space, soil, snow, ice, water) with obtaining electrical energy that can be used to service various technical devices, heating and lighting temporary residential and industrial premises without the expense of fuel, environmental pollution, creating effect and heat radiation, which ultimately increases the efficiency of the power plant.

Claims (1)

A universal solar thermal power plant containing a plane assembled from rectangular sections covered with a waterproofing film, each of which consists of a photothermal converter connected by jumpers to collectors of the same charge and a storage unit, inside which a solar cell and thermoelectric converter equipped with a heat pipe and radiators are located, characterized in that each rectangular section is a phototeplotrubnothermoelectric converter, inside and which is placed between the photocell and the thermoelectric plate, a heatpipe heat exchanger is made in the form of a rectangular plane, the lid and the bottom of the body of which are covered with a grating made of strips of capillary material partially filled with working fluid, in the cavity of the grating of the lid and the bottom are interconnected by vertical wicks, also partially filled with working fluid and covered with cylindrical casings with triangular slots made on their upper and lower hands and attached to the cover and the bottom of the body.

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