RU2431086C2 - Solar power plant (versions) - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: in solar power plant containing concentrators, two-axis tracking system and photoreceiver in focal zone of each concentrator on the basis of commutated solar elements with p-n junctions the planes of which are perpendicular to optical axis and parallel to middle plane of concentrator the photoreceiver is made in the form of flat module consisting of in-series miniature solar elements each of which has the shape of circular sector with apex angle of 3-30°, which are installed axisymmetrically in focal zone with apex at optical axis of concentrator. Photoreceiver is installed in transparent cover for solar radiation and equipped with heat removal device. In the other version, in solar power plant containing concentrators, two-axis tracking system and photoreceivers in focal zone of each concentrator on the basis of commutated solar elements with p-n junctions, each photoreceiver is made in the form of sections of solid-state matrix consisting of in-series commutated miniature solar elements with diode structures and two-sided working surface; planes of p-n junctions of diode structures are parallel to two of four side edges and perpendicular to working surface of photoreceiver, middle plane and focal plane of concentrator, and optical axis of concentrator and solar radiation flow are parallel to plane of p-n junctions. Photoreceiver is installed in transparent cover for solar radiation and equipped with heat removal device.

EFFECT: invention shall allow reduction of power losses, and cost of installed capacity and generated power.

20 cl, 9 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 the 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 paraboloidal mirror of square shape, a Cassegrain counter-protector and a pyramidal optical element made of glass, on the lower base of which a cascade heterostructured solar cell with a one-sided working surface with a pn junction, the plane of which is parallel to the concentrator’s midsection plane and perpendicular to the concentrator’s optical axis, is fixed to the solar flow radiation and the 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 25x25 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.

The objective of the present invention is to reduce energy losses and the cost of installed power and generated energy.

The technical result is achieved in that in a solar power plant containing concentrators, a biaxial tracking system and a photodetector in the focal region of each concentrator based on commutated solar cells with pn junctions whose planes are perpendicular to the optical axis and parallel to the plane of the hub midship, the photodetector is made in the form of a flat a module of sequentially switched miniature solar cells, each of which has the shape of a circular sector with an angle at the apex of 3-30 °, setting ennyh axially in the focal region with vertex in the optical axis of the concentrator, a photodetector is mounted in the transparent for solar radiation and the shell is provided with a device for removing heat.

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 plane of the pn 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, 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 device for removing heat.

In a variant of a solar power plant, the photodetector is made in the form of a cascade converter of two sections of solid-state arrays mounted one above the other in the direction of the concentrated radiation flux: the first section is made of silicon, and the second section is made of germanium.

In another embodiment of the solar power plant, the photodetector is made of three sections of solid-state arrays mounted one below the other in the direction of the concentrated radiation flux: the first section is made of silicon carbide, the second section is silicon, and the third section is germanium.

In another embodiment of the solar power plant, sections of the solid-state matrix of the composite photodetector are mounted axisymmetrically in the focal region and have a variable area of miniature solar cells in the matrix, which increases with distance from the optical axis of the concentrator.

In a variant of a solar power plant, a composite photodetector consists of five sections of solid-state arrays connected in parallel and mounted axisymmetrically in the focal plane of the concentrator, the central section is square, four other sections are made in the form of regular trapeziums, the smaller base of each trapezoid is equal to the side of the square section and adjoins it .

In a variant of a solar power plant, sections of the solid-state matrix of the photodetector are made in the form of a regular tetrahedral pyramid and form a composite cavity axisymmetric photodetector, which is placed in a cone-shaped transparent shell filled with organosilicon liquid and facing the cavity to the hub.

In a variant of the solar power station, the cavity photodetector is turned at the apex to the hub.

In a variant of a solar power station, 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 plane of the pn junctions of which are parallel to the two side faces of the prism.

In a variant of a solar power plant, sections of a solid-state matrix of a photodetector coated with glass on a working surface are mounted in the form of a cylinder axisymmetrically in the focal region inside a transparent cylindrical shell parallel to the optical axis of the concentrator and immersed in coolant.

In a variant of a solar power plant, the heat removal device has a pump for pumping coolant.

In a variant of a solar power plant, the coolant is made of organosilicon components.

In another embodiment of a solar power plant, the coolant contains purified water based components.

In a variant of a solar power plant, the heat exchanger is connected to two cooling circuits, one circuit for pumping coolant and a second circuit for pumping water.

In another embodiment of the solar power plant, the heat exchanger is equipped with an air-cooled radiator.

In a variant of a solar power station, the photodetector on the concentrator 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.

In a variant of the solar power plant, the heat exchanger is equipped with a device for pumping the coolant.

In another embodiment of the solar power plant, the heat exchanger is equipped with an air-cooled radiator.

The invention is illustrated by figures, in which Fig. 1 shows a solar power plant with a paraboloid reflector and a sector photodetector based on commutated axisymmetric solar cells, Fig. 2 shows the location of a sector photodetector in the focal plane, Fig. 3 shows a solar power station with a paraboloid concentrator and a photodetector in the form of a cascade converter of two sections of solid-state matrices of silicon and germanium, Fig. 4 - a solar power station with a concentric concentrator Inza Fresnel integral photodetector variable area miniature solar cells in the matrix in Figure 5 - the location of the receiver in the composite focal plane 6. - the location of the cavity receiver in two projections in the focal region, in Fig.7 - a solar power station with a concentrator based on a concentric Fresnel lens and a composite cavity photodetector in a conical cooling chamber, Fig. 8 - solar power station with a paraboloid mirror of the Cassegrain system and a photodetector in a tetrahedral a prism, in Fig.9 - a solar power plant with a paraboloidal mirror and a cylindrical photodetector.

In Fig. 1, the solar power station contains a paraboloidal concentrator 1 with a biaxial tracking system (not shown in Fig.) And a photodetector 2 mounted axisymmetrically in the focal plane 3 with a center in focus F and an optical axis 4 of the concentrator 1. Photodetector 2 is mounted in a cone-shaped chamber 5 made of glass, which is connected by a metal support 6 to a paraboloid 1. Inside the support 6, tubes 7 and 8 are installed for supplying and discharging an organosilicon liquid. For pumping the organosilicon liquid into the heat exchanger 9, a pump 10 is installed. The pipes 11 and 12 of the water cooling circuit are connected to the heat exchanger. The photodetector 2 is made in the form of sequentially switched planar sector solar cells 3 (Fig. 2) with a sector angle of 3-30 °, mounted axisymmetrically around the optical axis 4 in the form of a circle.

In Fig. 3, the solar power station contains a paraboloid concentrator 1 and a cascade photodetector 12 of two sections of solid-state arrays of silicon 13 and germanium 14. The contact planes 15 and pn junctions 16 in sections 13 and 14 are parallel to each other and to the optical axis 4 of hub 1 and perpendicular to the plane of the midsection 17 and the hub 1, which receives solar radiation i.

In Fig. 4, the solar power station contains a concentrator based on a Fresnel concentric lens 18 and a composite photodetector 19, which consists of a central section 20 of a square-shaped solid-state matrix and four sections 21, 22, 23 and 24 of solid-state arrays (Fig. 5), which are made in in the form of regular trapezoids, the smaller base 25 of each trapezoidal section is equal to side 26 of the central square section 20 and adjoins it. All sections of the photodetector 19 are connected in parallel and mounted on a heat exchanger-radiator 27, the area of which is commensurate with the area of the concentrator 18. The composite photodetector 19 has a protective coating 28 of glass on the illuminated side and is attached to the heat exchanger 27 using heat-conducting electrically insulated adhesive 29.

The planes of p ⁺ -n (n ⁺ -p) junctions 30 and isotypic n ⁺ -n (p ⁺ -p) junctions of diode structures are shown in the figures by thin lines, and of metal contacts by thick lines.

The planes of pn junctions 30 and the contacts of all sections of the composite photodetector 19 are parallel to the optical axis 31 of the hub 18 and perpendicular to the plane of the Fresnel lens 18. Sections 21, 22, 23 and 24 of solid-state arrays have a variable area of miniature solar cells 32, which increases with increasing distance from optical axis 31 of the hub.

Figure 6 shows in two projections (side view and top view) a composite cavity receiver 34, which has the shape of a tetrahedral pyramid and consists of four sections 35, 36, 37 and 38 solid-state matrices, each of which is made in the form of a regular triangle. The planes of the pn junctions 39 in the sections are parallel to the base of the receiver.

7, a composite cavity photodetector 34 is mounted in the focal region 33 of the Fresnel concentric lens inside a sealed conical transparent chamber 40, which is filled with coolant 41. The total surface area of the walls of the conical chamber 40 is comparable with the area of the Fresnel lens 18.

In Fig. 8, the hexagonal paraboloid concentrator 41 has a counterblock 42 in the form of a hyperbolic mirror in the focal region F and a prism optical element 43 mounted at the apex 44 of the hub 41. The photodetector 45 is mounted on the basis of a tetrahedral prism 43 of optical glass. Photodetector 45 consists of series-connected miniature solar cells 46 with diode n ⁺ -pp ⁺ structure. The planes of the pn junctions 47 in the diode structure are parallel to two of the four faces of the prism 43, the incident radiation i and the optical axis of the concentrator 4. The photodetector 45 is attached to the prism 43 using optical transparent glue (not shown in Fig.) And installed in a sealed chamber 48 filled with organosilicon liquid 49. The back side 50 of the photodetector 45 has a protective coating of glass 51 and is immersed in an organosilicon cooling liquid 49. The cooling device of the photodetector 52 consists of pipelines 53 connected to a germ the chamber 48 of the pump 54 and the heat exchanger 55 to which the water circuit 56 is connected.

In Fig. 9, the solar power station comprises a square-shaped paraboloid concentrator 57 and a cylindrical photodetector 58 mounted symmetrically in the focal region 59 of the concentrator 57 in a cylindrical glass shell 60. The cross-section of the photodetector in its middle part coincides with the focal plane 61 of the concentrator 57. R-n planes transitions 62 of the photodetector 58 are perpendicular to the focal plane 61 and the midsection plane 63 of the hub 57 and parallel to the optical axis 64 and the stream of incident i arriving at the hub 57, and is reflected sunlight s i _o, received on the photodetector 58. The photodetector 58 has a protective coating 63 made of glass and immersed in a silicone coolant 64 which fills the cylindrical shell 60. The cylindrical shell 60 has nozzles 65 for connection to the heat exchanger. In another embodiment, the cylindrical shell 60 is attached to an air radiator.

An example of a solar power plant (SES)

SES consists of modules with a paraboloid axisymmetric concentrator with a biaxial tracking system (Fig.9). Each module has a square paraboloid mirror 57 of 0.283 × 0.283 m in size with a protective cylindrical shell with a diameter of 60 × 30 mm made of glass. Photodetector 58 consists of 6 sections of matrix solar cells measuring 60 mm × 10 mm × 0.6 mm installed along the inner generatrix of the protective cylindrical shell 60 in the focal region 59 of the hub 57. The planes of the pn junctions 62 and the contacts of the sections of the photodetector 58 are parallel to the optical axis 64 of the concentrator, the incident flux i and the reflected flux i _{o of} radiation and are perpendicular to the midsection plane 63 and the focal plane 61 of the concentrator 57. The sections of the matrix solar cells have a protective coating 63 of glass and are immersed in an organosilicon 64 cooling liquid. The cylindrical protective shell 60 in the upper part has a coil radiator for cooling the coolant. The area of the photodetector 58 is 36 cm ² , the midsection area of the 63 concentrator is 800 cm ² , the geometric concentration coefficient is 222, the optical efficiency is 0.8, the peak electric power with a photodetector efficiency of 20% and a module efficiency of 16% is 12.8 W.

The location of the plane of pn junctions parallel to the concentrated flux of solar radiation allows us to obtain two important advantages of SES compared to the known one. This makes it possible to fabricate a photodetector from a cheap semiconductor material with indirect junctions, for example, silicon, and reduce the cost of a photodetector from $ 13 / cm ² for cascaded heterostructured solar cells to $ 0.065 / cm ² , i.e. 200 times.

The concentrated radiation flux in the photodetector is orthogonal to the flux of radiation generated by the charge carriers through pn junctions, which reduces the joule losses in the doped layer and in the base region of the photodetector and improves the heat removal conditions by using metal collectors located over the entire pn junction area, as heat-conducting layers for removing heat from the volume of the photodetector to both working surfaces. The infrared component of the concentrated radiation flux beyond the edge of the absorption band (1.2 μm for a silicon photodetector) passes parallel to the plane of pn junctions through the photodetector volume without significant absorption, which also reduces the cost of cooling the photodetector by about 20%. The presence of an antireflection coating on both working surfaces of the photodetector reduces reflection losses and increases the transmission of the non-photoactive part of the spectrum of incident direct and concentrated solar radiation.

Claims (20)

1. A solar power plant containing concentrators, a biaxial tracking system and a photodetector in the focal region of each concentrator based on commutated solar cells with pn junctions whose planes are perpendicular to the optical axis and parallel to the concentrator’s midship plane, characterized in that the photodetector is made in the form of a flat module of successively switched miniature solar cells, each of which has the shape of a circular sector with an angle at the apex of 3-30 °, mounted axisymmetrically in the focal region with vertex in the optical axis of the concentrator, a photodetector is mounted in the transparent for solar radiation and the shell is provided with a device for removing heat. 2. The solar power station according to claim 1, characterized in that the heat removal device has a pump for pumping coolant and a heat exchanger. 3. The solar power station according to claim 1, characterized in that 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. 4. 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, characterized in that 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 the pn junctions of the diode structures are parallel to two of the four side faces and are perpendicular to the working surface 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 the pn junctions of the photodetector, the photodetector is installed in a shell transparent to solar radiation and equipped with a device for removing heat. 5. The solar power station according to claim 4, characterized in that the photodetector is made in the form of a cascade converter of two sections of solid-state arrays mounted one below the other in the direction of the concentrated radiation flux: the first section is made of silicon and the second section is made of germanium. 6. The solar power station according to claim 4, characterized in that the photodetector is made of three sections of solid-state arrays mounted one below the other in the direction of the concentrated radiation flux: the first section is made of silicon carbide, the second section is made of silicon, and the third section is made of germanium . 7. The solar power station according to claim 4, characterized in that the sections of the solid-state matrix of the composite photodetector are mounted axisymmetrically in the focal region and have a variable area of miniature solar cells in the matrix, which increases with distance from the optical axis of the concentrator. 8. The solar power station according to claim 4 or 7, characterized in that the composite photodetector consists of five sections of solid-state arrays connected in parallel and mounted axisymmetrically in the focal plane of the concentrator, the central section has the shape of a square, four other sections are made in the form of regular trapezoid, smaller the base of each trapezoid is equal to the side of the square section and adjoins it. 9. The solar power station according to claim 4 or 7, characterized in that the sections of the solid-state matrix of the photodetector are made in the form of a regular tetrahedral pyramid and form a composite cavity axisymmetric photodetector, which is placed in a cone-shaped transparent shell filled with organosilicon liquid and facing the cavity to the concentrator. 10. The solar power station according to claim 4, characterized in that the cavity photodetector is facing the apex towards the concentrator. 11. The solar power station according to claim 4, characterized in that the hub 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 planes of the pn junctions of which are parallel to two side faces prisms. 12. The solar power station according to claim 4, characterized in that the sections of the solid-state matrix of the photodetector coated with glass on the working surface are mounted in the form of a cylinder axisymmetrically in the focal region inside the transparent cylindrical shell parallel to the optical axis of the concentrator and immersed in coolant. 13. A solar power plant according to any one of claims 4, 5, 6, 7, 10, 11, 12, characterized in that the heat removal device has a pump for pumping coolant and a heat exchanger. 14. The solar power station according to item 13, wherein the cooling liquid is made of organosilicon components. 15. The solar power station according to item 13, wherein the cooling liquid contains components based on purified water. 16. The solar power station according to item 13, wherein the heat exchanger is connected to two cooling circuits, one circuit for pumping coolant and a second circuit for pumping water. 17. The solar power station according to item 13, wherein the heat exchanger is equipped with an air-cooled radiator. 18. The solar power station according to claim 4, characterized in that the photodetector on the hub side has a protective coating of glass, the reverse side of the photodetector is attached through an electrically insulating heat-conducting adhesive to the surface of the heat exchanger. 19. The solar power plant according to claim 18, characterized in that the heat exchanger is equipped with a device for pumping the coolant. 20. The solar power station according to claim 19, characterized in that the heat exchanger is equipped with an air-cooled radiator.

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