RU2615243C2 - Solar power station - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: solar power station includes concetrators, a tracking system and photodetectors in the focal region of each concetrators based on concentrator solar cells with p-n junctions. Each photodetector is designed in the form of sections of a solid matrix of sequentially commuted miniature solar cells with diode structures and double-sided work surface, planes of the p-n junctions of the diode structures are parallel to two of the four side faces and perpendicular to the working surface of the photodetector, the midsection plane and the focal plane of the concentrator. The photodetector is installed in the transparent envelope for solar radiation and is provided with a device for heat removal, the transparent envelope comprises a homogenizer of concentrated solar radiation in form of a rectangular-sectioned rod of optically transparent material, the cross-sectional dimensions of the homogenizer are commensurable with the dimensions of the working surface of the photodetector, and the length of the rod is in 2-10 times greater than the size of the working surface of the photodetector. The device for heat removal is designed in the form of thin plates made of thermally conductive material connected to the current leads of each section of solid matrix by soldering or welding parallel to the plane of the p-n junctions of the diode structures, the size of the sections between the plates of the heat exchanger is 4-20 mm and the total area of the heat exchanger plates during the natural cooling is equal to the area of the midsection of the concentrator.

EFFECT: reduction of power losses and increase of efficiency and service life of the solar power station.

5 cl, 4 dwg

Description

The invention relates to the field of conversion of solar energy into electrical and thermal, primarily to the design of solar power plants with concentrators.

Known solar photovoltaic station containing a concentrator based on concentric Fresnel lenses, a biaxial tracking system for the sun and photodetectors based on cascade heterostructure planar solar cells with a one-sided working surface. The solar power plant has the following characteristics: concentration coefficient 385, electric power 5.75 kW, solar radiation conversion efficiency taking into account the efficiency of the concentrator and inverter 23.5%, cost 9.3 USD / W. The plane of the photodetectors and pn junctions of the photodetectors are parallel to the plane of the Fresnel lens and perpendicular to the optical axis of the concentrator and the concentrated flux of solar radiation. The cost of a photodetector is $ 13 per 1 cm of photodetector area (Photon International, July 2008, p. 15).

A disadvantage of the known power plant is the high complexity of manufacturing and the high cost of photodetector materials containing gallium, germanium and other expensive materials.

Known solar photovoltaic station containing a concentrator with a midsection surface, which receives solar radiation, a biaxial tracking system and radiation photodetectors based on cascade heterostructured solar cells based on semiconductors A _III B _V. The concentrator contains a square paraboloidal mirror, a Cassegrain counter-protector and a pyramidal optical element made of glass, on the lower base of which there is a cascaded heterostructured solar cell with a one-sided working surface with a pn junction, the plane of which is parallel to the concentrator’s midsection and perpendicular to the concentrator’s optical axis, and the solar radiation flux side faces of the optical element. Parameters of a solar power plant: concentration 476, efficiency 22.7%, solar cell area 1 cm ² , paraboloid dimensions 25 × 25 cm, total electric power 500 kW (Photon International, November 2008, p. 150, 153; Sun and Wind Energy, 2008, No. 5, p. 130).

A disadvantage of the known solar power plant is the high cost and low efficiency of a three-element optical system: a parabolic mirror - a counter-reflector - an optical element - a solar element.

In a solar power plant containing concentrators, a biaxial tracking system and photodetectors in the focal region of each concentrator based on commutated solar cells with pn junctions, each photodetector is made in the form of sections of a solid-state matrix of sequentially commutated miniature solar cells with diode structures and a two-sided working surface, the pn junction planes of the diode structures are parallel to two of the four side faces and are perpendicular to the working surface of the photodetector, p the midsection of the midsection and the focal plane of the concentrator, and the optical axis of the concentrator and the flux of solar radiation are parallel to the p-n junction planes of the photodetector, the photodetector is installed in a shell transparent to solar radiation and equipped with a device for removing heat.

In the variant of the solar power plant, the concentrator is made in the form of a paraboloid mirror of the Cassegrain system with a hyperbolic counter-reflector in the focal region and a tetrahedral prism at the top of the paraboloid, at the base of which there is a photodetector, the p-n junctions of which are parallel to the two side faces of the prism.

In a variant of a solar power plant, the photodetector on the hub side has a protective coating of glass, the back side of the photodetector is attached through an electrically insulating heat-conducting adhesive to the surface of the heat exchanger, and the heat exchanger is equipped with a device for pumping a heat carrier or an air-cooled radiator (RF Patent No. 2431086, publ. March 20, 2011. Bull. No. 28).

A disadvantage of the known solar power plant is the reduction of electric power and the life of the photodetector due to insufficiently high thermal conductivity and aging of the electrically insulating heat-conducting adhesive between the photodetector and the heat exchanger. Another disadvantage is the decrease in electric power due to circuit losses in the case of uneven illumination of the photodetector in the focal region of the concentrator.

The objective of the present invention is to increase the electrical power and service life of a solar power plant.

The technical result is to reduce energy losses and increase the efficiency and service life of a solar power plant.

The technical result is achieved by the fact that in a solar power plant containing concentrators, a tracking system and photodetectors in the focal region of each concentrator based on commutated solar cells with pn junctions, each photodetector is made in the form of sections of a solid-state matrix of sequentially commutated miniature solar cells with diode structures and a two-sided working surface, the planes of pn junctions of the diode structures are parallel to two of the four side faces and are perpendicular to the surface of the photodetector, the midsection plane and the focal plane of the concentrator, and the optical axis of the concentrator and the solar radiation flux are parallel to the plane of pn junctions of the photodetector, the photodetector is installed in a shell transparent to solar radiation and equipped with a heat dissipation device, the transparent shell contains a homogenizer of concentrated solar radiation in in the form of a rod of rectangular cross section made of optically transparent material, the cross-sectional dimensions of the homogenizer are commensurate with the dimensions the working surface of the photodetector, and the rod length is 2-10 times larger than the dimensions of the working surface of the photodetector, the planes of the diode structures are parallel to two of the four faces of the homogenizer, and the heat removal device is made in the form of thin plates of heat-conducting material attached to the current leads of each section of the solid-state matrix by soldering or welding parallel to the plane of pn junctions of the diode structures, the size of the sections between the heat exchanger plates is 4-20 mm, and the total area of the heat exchanger plates Twain cooling equal to the area midsection hub.

In a variant of a solar power plant, the heat exchanger plates are made of metal, for example, copper, with a thickness of 0.05-0.5 mm.

In another embodiment of the solar power plant, the heat exchanger plates are made of heat-conducting ceramics, for example, aluminum nitride.

In another embodiment of the solar power plant, the heat exchanger plates are made of two dissimilar materials: at the current leads of the sections, the heat exchanger plates are made of metal, for example, copper, 0.05-0.5 mm thick, and at a distance of 1-5 mm from the heat exchanger plate section heat-conducting ceramics, and two dissimilar materials are interconnected by soldering or welding.

In an embodiment of the solar power plant, the heat exchanger plates are made of two metal parts, which are connected by an insulating gasket made of heat-conducting ceramics, for example aluminum nitride, by soldering or welding.

The invention is illustrated in FIG. 1, FIG. 2, FIG. 3 and FIG. 4, where in FIG. 1 is an optical diagram of a solar power station with a hub based on a Fresnel lens and the path of the rays; in FIG. 2 is an optical diagram of a solar power plant with a parabolic concentrator and ray paths; in FIG. 3 - a photodetector with a heat sink with heat exchangers of two dissimilar materials; in FIG. 4 - a photodetector with a heat sink with heat exchangers of two metal parts, which are connected by an insulating insert of heat-conducting ceramics.

гомогенизатора 14 в 2-10 раз больше размеров рабочей поверхности фотоприемника 2:In Fig. 1, the solar power station contains a concentrator 1 based on a Fresnel concentric lens, a photodetector 2 in the form of sections 3 of a solid-state matrix of sequentially commutated miniature solar cells 4 with diode structure n ⁺ -pp ⁺ or p ⁺ -nn ⁺ , pn junction planes 5 and isotype or transitions pp ⁺ nn ⁺ 6 parallel to the two faces 2 and the photodetector 7 are perpendicular to the working surface 8 of the photodetector 2 midship plane 9 and the focal plane 10 of the hub 1, the optical axis of the hub 11 1 and a stream of solar radiation 12 to the input a hub 1 pn junctions parallel to the plane of the photodetector 2. The photodetector 5 is set to 2 transparent for solar radiation 12 comprises a shell 13 and homogenizer 14 of concentrated solar radiation 15, the cross-sectional dimensions a and b homogenizer 14 commensurate with the size of the working surface 8 of the photodetector 2, and the length

homogenizer 14 is 2-10 times larger than the size of the working surface of the photodetector 2:

=(2÷10)a,

=(2÷10)b.

= (2 ÷ 10) a ,

= (2 ÷ 10) b.

The planes of the pn junctions 5 are parallel to the two faces 16 of the homogenizer 14. The input end 17 of the homogenizer 14 is mounted in the focal plane 10 on the optical axis 11 of the concentrator 1. The heat sink 18 is made in the form of thin plates 19 of heat-conducting material connected to the current leads 20 of each section 3 by soldering or welding parallel to the plane of the pn junctions 5, the size of the sections 3 d between the plates 18 is d = 4-20 mm, and the total area S _{t of the} plates 18 of the heat exchanger 17 during natural cooling is equal to the area S _{m of the} midsection 9 of the concentrator 1. The area of the midsection 9 S _m is equal to the product of the area S _{f of the} photodetector 2 by the concentration coefficient κ:

S _m = κS _f .

Therefore, the area S _{t of the} heat exchanger 17 is equal to:

S _t = S _m = κS _f . In FIG. 2, the concentrator 1 is made in the form of a parabolic-cylindrical concentrator 21, and the photodetector 2 with a homogenizer 14 is mounted above the parabolic concentrator 21.

In FIG. 3, the heat sink 18 contains heat exchanger plates made of two dissimilar materials: at current leads 20, plates 22 are made of metal, for example copper, and at a distance of 1-5 mm from the section of plate 23 of the heat exchanger are made of heat-conducting ceramics, plates 22 and 23 are interconnected by soldering or welding.

In FIG. 4 plates 22 and 24 of the heat exchanger are made of copper and interconnected by an electrically insulating gasket 25 of heat-conducting ceramics.

The solar power plant operates as follows.

Solar radiation 12 after the concentrator 1 enters the input end face 17 of the homogenizer 14 in the form of concentrated radiation 15. Due to the effect of multiple total internal reflection from the walls of the homogenizer 14, the unevenly distributed concentrated radiation 15 in the focal plane 10 at the input end 17 enters the photodetector 2 in the form of uniformly radiation flux distributed over the area of the photodetector 2. Photodetector 2 converts uniformly distributed concentrated radiation 15 into electrical energy with high efficiency η _f due to the absence of circuit losses in photodetector 2 due to uneven illumination of series-connected solar cells 4 in photodetector 2.

Part of the energy of concentrated solar radiation 15, proportional to 1-η _f , is converted into heat in sections 3 and enters the heat sink 18 and is dissipated through the plates of the heat exchanger 19 in the environment due to convection and radiation. With natural cooling and the fulfillment of the condition S _m = S _t = κS _{f, the} temperature of photodetector 2 at a concentration of κ = 5-500 will not exceed 80 ° C. The area S _{t of the} heat exchanger plates 19 can be reduced by using forced air cooling with a fan or by water cooling of the plates 19, 22. 23. 24 (not shown in FIG.), In order to isolate sections 3 from the environment, such as water, use ceramic plates 23 or ceramic insulating inserts 25.

An example of a solar power plant.

The hub 1 in figure 1 is made of a Fresnel lens with a size of 400 × 400 mm, the photodetector 2 has dimensions of 40 × 40 mm, the concentration coefficient κ = 100. The size of the section 3 between the two plates 19 is 5 mm, the number of plates 9, the dimensions of the plates 130 × 130 × 0.1 mm, the total area of the plates is 0.169 m ² , the dimensions of the homogenizer 14 are 40 × 40 × 320 mm. Electrical power 24 W, operating voltage 96 V, efficiency 15%, temperature of the photodetector 2 with natural cooling 80 ° C, with air cooling with a fan 40 ° C.

The use of a homogenizer 14 of concentrated solar radiation 15 and a heat sink 18 increases the electric power of the solar power station and the service life by reducing circuit losses in the photodetector 2 and lowering the temperature of the photodetector 2 when working with the solar radiation concentrator.

Claims (5)

1. A solar power plant containing concentrators, a tracking system and photodetectors in the focal region of each concentrator based on commutated solar cells with pn junctions, each photodetector is made in the form of sections of a solid-state matrix of sequentially commutated miniature solar cells with diode structures and a two-sided working surface, pn plane transitions of diode structures are parallel to two of the four side faces and perpendicular to the working surface of the photodetector, the plane the ideal and the focal plane of the concentrator, and the optical axis of the concentrator and the solar radiation flux are parallel to the pn junction planes of the photodetector, the photodetector is installed in a shell transparent to solar radiation and equipped with a heat removal device, characterized in that the transparent shell contains a concentrated solar radiation homogenizer in the form of a rectangular rod sections from an optically transparent material, the cross-sectional dimensions of the homogenizer are commensurate with the dimensions of the working surface of the receiver, and the rod length is 2-10 times greater than the dimensions of the working surface of the photodetector, the planes of the diode structures are parallel to two of the four faces of the homogenizer, and the heat removal device is made in the form of thin plates of heat-conducting material attached to the current leads of each section of the solid-state matrix by soldering or welding parallel to the plane of pn junctions of the diode structures, the size of the sections between the heat exchanger plates is 4–20 mm, and the total area of the heat exchanger plates during natural cooling is in the midship area of the hub. 2. The solar power plant according to claim 1, characterized in that the heat exchanger plates are made of metal, for example copper, with a thickness of 0.05-0.5 mm. 3. The solar power plant according to claim 1, characterized in that the heat exchanger plates are made of heat-conducting ceramics, for example, aluminum nitride. 4. The solar power plant according to claim 1, characterized in that the heat exchanger plates are made of two dissimilar materials: at the current leads, the sections of the heat exchanger plate are made of metal, for example, copper, 0.05-0.5 mm thick, and at a distance of 1-5 mm from the section of the heat exchanger plate are made of heat-conducting ceramic, and two dissimilar materials are interconnected by soldering or welding. 5. The solar power plant according to claim 1, characterized in that the heat exchanger plates are made of two metal parts that are connected by an insulating gasket made of heat-conducting ceramics, for example, aluminum nitride, by soldering or welding.

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