RU2740738C1 - Powerful concentrator photoelectric module - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: concentrator photoelectric module comprises monolithic front panel (3), side walls (1) and rear panel (2), at least one primary optical concentrator (4), at least one secondary optical concentrator in the form of focon (9) with a smaller base facing photoelectric element (10) with heat-removing element (11) placed on the front surface of rear panel (2). Larger base of focon (9) is closed by plate (12) made of silicate glass attached by optical silicone-sealant to the faces of the larger base of focon (9). Opposite edges of larger base of focon (9) are equipped with L-shaped lobes (7), horizontal flanges (8) of which are fixed on heat-removing element (11) to form a gap between smaller base of focon (9) and light-sensitive surface of photoelectric element (10). Areas of contacts (16) to photoelectric element (10), to heat-removing element (11) and space between faces of smaller base of focon (9) and non-light-sensitive surfaces of photoelectric element (10) are filled with layer of optical silicone sealant (18).

EFFECT: concentrator photoelectric module has high reliability and long service life while maintaining high efficiency of converting solar radiation into electric power.

7 cl, 5 dwg

Description

The invention relates to the field of solar energy, in particular to concentrator solar photovoltaic modules used in ground-based solar power plants intended for autonomous power supply systems. One of the most promising methods for generating electricity from renewable sources is the photovoltaic conversion of concentrated solar radiation using expensive, highly efficient multistage photovoltaic converters and relatively inexpensive optical concentrators. The use of highly efficient optical concentrators, providing a degree of concentration of solar radiation over 500 times, makes it possible to obtain a high efficiency of conversion of solar radiation into electricity with a significant reduction in the area of solar photovoltaic cells.

A photovoltaic module with a nanostructured photovoltaic cell is known from the existing prior art (see patent RU2436192, IPC H01L 31/052, В82В 1/00, published on 10.12.2011), containing a primary optical concentrator in the form of a Fresnel lens (LF), the optical axis of which passes through the center of the photoactive region of the nanostructured photovoltaic cell and a secondary concentrator coaxial with it. The secondary concentrator consists of a front optical element in the form of a part of a sphere, an intermediate optical element with parallel front and rear surfaces, and a rear optical element made in the form of a cylinder.

The photovoltaic module has high photovoltaic performance. The disadvantage of the known module is the complexity and high cost of manufacturing a secondary concentrator with the required accuracy.

Known solar photovoltaic module with a concentrator (see patent RU2444809, IPC H01L 31/052, published 03/10/2012), containing a LF with a concentric working profile and installed in the focal plane photovoltaic cell with a cooling device. The concentrator is composed of a sequential set of sectors of the original concentric LF, with a uniform distribution of concentrated radiation on an annular focal region. The original concentric LF consists of two zones with working profiles. The working profiles alternate at different inclination in the focal plane of the ring-shaped focal area.The original lens is cut along the radius into a certain number of sectors and is a flat rectangular LF, in which adjacent sectors are installed opposite each other with a uniform distribution of concentrated radiation on a linear photoelectric detector in the focal plane. The photoelectric receiver is made in the form of a line of switched high-voltage photovoltaic cells and is symmetrically mounted on a secondary omega-shaped parabolic-cylindrical concentrator.

The invention provides an increase in conversion efficiency and a decrease in the cost of the generated energy, however, this effect is achieved by a complicated design of the concentrators.

Known solar photovoltaic concentrator module (see patent RU2641627, IPC H01L 31/054, published on January 18, 2018), containing a primary optical concentrator in the form of an LF, with a linear dimension D, the optical axis of which passes through the center of the photoactive region of the photovoltaic cell, made in the form a circle with a diameter d, and a secondary concentrator coaxial with it, made in the form of a quarter-wave radial gradan with a diameter d and a height h ₁ , installed at a distance h ₂ from the frontal surface of the LF, while the values h1, h ₂ , and D satisfy certain relationships.

The solar photovoltaic concentrator module provides the formation of a photovoltaic module with increased reliability, extended service life and high energy efficiency by leveling the illumination of the photoactive area and reducing the local concentration of solar radiation. The disadvantage of the known solar photovoltaic concentrator module is the difficulty of maintaining all the relationships between structural elements in the manufacture of the module.

Known concentrator photovoltaic module (see application US2016204736, IPC H02S 0/32; H02S 40/22, published on July 14, 2016), consisting of a primary concentrator, a photovoltaic cell and a secondary concentrator. The secondary concentrator includes a secondary lens and a transparent coating with a refractive index higher than that of air and lower than that of the secondary lens, and it covers at least the surface of the secondary lens in the form of a thin film on which solar radiation is incident.

The disadvantages of the known solar photovoltaic module are the technical difficulties of manufacturing, mounting and aligning a large number of optical parts and, as a consequence, the high cost of the structure.

Known concentrator photovoltaic module (see application US20140261627, IPC H01L 31/052, published 09/18/2014), including a substrate, a plurality of concentrator photovoltaic cells on the surface of the substrate and concentrator optics located above the surface of the substrate and focusing light on the concentrator photovoltaic cells. On the surface of the substrate, between the concentrator photovoltaic cells, there is also a plurality of non-concentrator photovoltaic cells that are illuminated by light passing outside the axis of the concentrator optics.

The known concentrator photovoltaic module is rather difficult to manufacture.

Known concentrator photovoltaic module (see application WO2006128417, IPC H01L 31/052, published on 07.12.2006), containing side walls and a front translucent panel with the first focusing solar radiation optical elements on its rear side, a translucent intermediate panel with the second focusing solar radiation optical elements and a rear panel with solar photovoltaic cells.

The presence of an intermediate translucent panel increases the optical reflection loss from this panel and increases the cost of the known hub module.

Known concentrator photovoltaic module (see patent RU2352023, IPC H01L 31/052, published 10.04.2009), which coincides with the present technical solution for the greatest number of essential features and is taken as a prototype. The concentrator photovoltaic module includes a monolithic front panel, side panels and rear panel, primary optical concentrators and secondary optical concentrators. the primary optical concentrators are made in the form of lenses in contact with each other, formed in the form of the rear surface of the front panel. Secondary optical concentrators are made in the form of foxes mounted on a smaller base on the photosensitive surfaces of photovoltaic cells with heat sink elements, located on the front surface of the rear panel coaxially with the corresponding primary optical concentrators.

The well-known prototype photovoltaic concentrator module has a high efficiency of converting solar radiation into electricity. The disadvantages of the known concentrator photovoltaic module are the complexity of manufacturing and installation of secondary optical concentrators on the photosensitive surfaces of the photovoltaic cells. The resulting mechanical stresses and the lack of sealing of the end area of the photovoltaic cell and places of installation of the photovoltaic cell during long-term operation lead to its degradation and to a decrease in the efficiency of conversion of solar radiation.

The objective of this technical solution is to develop a concentrator photovoltaic module that would have high reliability and long service life while maintaining a high efficiency of converting solar radiation into electricity.

The problem is solved in that the concentrating photovoltaic module includes a monolithic front panel, side walls and a rear panel, at least one primary optical concentrator and at least one secondary optical concentrator in the form of a focal point. The primary optical concentrator is made in the form of a lens formed in the form of the rear surface of the front panel. The focal point with its smaller base faces the photosensitive surface of the photovoltaic cell with a heat-removing element located on the front surface of the rear panel, coaxially with the corresponding primary optical concentrator. New in the concentrator photovoltaic module is that the opposite faces of the larger base of the focal point are equipped with L-shaped petals to form a gap between the smaller base of the focal point and the photosensitive surface of the photovoltaic cell; panels, the larger base of the focal point is closed with a plate of silicate glass attached with an optical silicone sealant to the edges of the larger base of the focal point, and the contact areas to the photovoltaic cell, to the heat-conducting alumina panel and the spaces between the edges of the smaller base of the focal point and non-light-sensitive surfaces of the photovoltaic cell are covered with a layer of optical silicone sealant.

The lens of the primary optical concentrator can be made of silicone on the front panel of silicate glass.

The lens of the primary optical concentrator can be made in the form of a Fresnel lens (LF).

The heat-conducting alumina panel can be made with a thickness of (0.2-1.0) mm and covered with a copper layer on both sides.

The photovoltaic cell can be made of a three-stage GaInP / GaAs / Ge heterostructure.

The fokon can be made in the form of a hollow truncated pyramid or a hollow truncated cone.

The focal point can be made of anodized aluminum sheet with a thickness of (0.3-1.0) mm with a mirror-polished inner surface.

The essence of this technical solution is illustrated by drawings, where:

in fig. 1 is a perspective view of a cross-section of a multi-element embodiment of the present concentrator photovoltaic module;

in fig. 2 is a schematic perspective view of a focal point and a photovoltaic cell mounted on the front surface of a heat sink alumina panel;

in fig. 3 shows a cross-sectional view of a focal point and a photovoltaic cell mounted on the front surface of a heat sink alumina panel fixed to the rear panel;

in fig. 4 shows a photograph of a single-element concentrator photovoltaic module, in which an LF is used as a primary concentrator, and an electric generating panel contains a photovoltaic cell based on a three-stage GaInP / GaAs / Ge heterostructure with a focal point made of anodized aluminum sheet 0.5 mm thick, mounted on a heat-removing alumina panel.

FIG. 5 shows a 32-element concentrator photovoltaic module, in which a lens panel consisting of 32 LFs is used as primary concentrators, and an electric generating panel contains 32 photovoltaic cells with foxes mounted on 32 heat-dissipating alumina panels.

The present concentrator photovoltaic module (see Fig. 1-Fig. 3) in a multi-element version contains side walls 1, a back panel 2, for example, made of aluminum and a monolithic front panel 3, for example, made of silicate glass, on the back surface of which by casting under pressure, for example, from silicone formed primary optical concentrators in contact with each other 4. Primary optical concentrators 4 can be made in the form of square plano-convex lenses or square LF, as well as in the form of regular hexagonal plano-convex lenses (see Fig. 1). Secondary optical concentrators are made in the form of fixed L-shaped petals 7 with horizontal shelves 8 foxes 9, installed with a smaller base with a gap above the photosensitive surfaces of photovoltaic cells 10, for example, made of a three-stage GaInP / GaAs / Ge heterostructure with heat-removing elements 11, made in the form heat-conducting alumina panels, for example, with a thickness of (0.2-1.0) mm. Focon 9 can be made, for example, in the form of a hollow truncated pyramid or a hollow truncated cone. Focal points 9 fixed by horizontal shelves 8 L-shaped petals 7 are located with a gap above the photosensitive surfaces of photovoltaic cells 10 with heat-removing elements 11 (see Fig. 3), located on the front surface of the rear panel 2, coaxially corresponding to the primary optical concentrators 4. Height of the focal points 9 can be within (5-25) mm. The diameter of the larger base of the foxes 9 can be (3-20) mm. The diameter of the smaller base of the foxes 9 can be (1-5) mm. Primary optical concentrators 4 can have a focal length in the range of (8-25) cm.Secondary optical concentrators in the form of foxes 9 can be made, for example, of anodized aluminum sheet with a thickness of (0.3-1.0) mm with a mirror-polished inner surface ... In this case, the large bases of the foxes 9 (see Fig. 3) are covered by plates 12 made of silicate glass, for example, with antireflection coatings 13, 14 on both sides of the plate 12. In the side opposite walls 1 of the photovoltaic module, holes 15 are made for communication with the surrounding environment of the internal space of the module. The non-light-sensitive surfaces of the photovoltaic cell 10, the areas of contacts 16 to the photovoltaic cell 10 and contacts 17 to the heat-removing element 11, the gaps between the edges of the smaller base of the focal point 9 and the non-light-sensitive surfaces of the photovoltaic cell 10 are covered with a layer 18 of silicone sealant. Thus, the photovoltaic cells 10 attached to the heat sink 11 are sealed from the external environment. The plates 12 are attached with a layer 19 of an optical silicone sealant to the edges of the larger base of the focal point 9. The horizontal shelves 8 of the L-shaped petals 7 are attached to the surface of the heat sink 11 with a layer 20 of silicone. The heat-conducting elements 11 are coated on one or both sides with a copper layer 21. The heat sink elements 11 are attached to the front surface of the rear panel 2 with a silicone layer 22.

During operation of a real concentrator photovoltaic module, oriented perpendicular to the sun's rays, the primary optical concentrators 4, as well as secondary optical concentrators in the form of foxes 9, concentrate sunlight and focus it on the photosensitive surfaces of the photovoltaic cells 10. When the optical axis of the photovoltaic concentrator module is misoriented from the direction to the Sun most of the rays are reflected from the inner lateral mirror faces of the focal point 9 and are focused on the surface of the photoactive region of the photovoltaic cell 10, thus improving the misorientation characteristics of the concentrator photovoltaic module. Photovoltaic cells 10 convert the energy of light quanta into electrical energy, creating a potential difference at their contacts. The power generated by the module is supplied to an external consumer or energy storage.

Communication with the environment of the inner space of the concentrator photovoltaic module through the holes 15 in the walls 1 of the photovoltaic module, in which the photovoltaic cells 10 are located, excludes the occurrence of pressure drops between the inner volume of the photovoltaic module and the atmosphere, thus preventing the occurrence of strong mechanical stresses in the structure. Filling the gaps between the edges of the smaller base of the focal point 9 and the non-photosensitive surfaces of the photovoltaic cell 10 with a layer 18 of elastic silicone sealant makes it possible to reduce mechanical stresses in the photovoltaic cells 10 with temperature changes, as compared to installing the focal points 9 with smaller bases on the light-sensitive surfaces of the photovoltaic cells 10 without a gap. Sealing the inner volume of the focal point 9, soldering points of contacts 16, contacts 17 and non-light-sensitive surfaces of the photovoltaic cell 10 with a layer of silicone 18 makes it possible to protect the photovoltaic cell 10 from environmental influences, to increase its service life, as well as to increase the reliability of the assembly and reduce the degradation of the concentrator photovoltaic the whole. Installing a glass plate 12 on the inlet of the focal point 9 and filling the gaps between the ends of the plate and the edges of the focal point with optical silicone-hermetic 19 allows protecting the inner volume of the focal point 9 and the photosensitive surface of the photovoltaic cell 10 from dirt and moisture, increasing their service life. Double-sided antireflection coating 13, 14 on the glass plate 12 minimizes optical losses due to the reflection of incident solar radiation from the front and rear surfaces of the glass plate 12. All this leads to an increase in reliability, an increase in the service life of the concentrator photovoltaic module and an increase in the conversion efficiency of solar radiation during long-term operation photovoltaic module.

Example 1. At the Physics and Technology Institute. A.F. Ioffe, the photovoltaic concentrator module shown in FIG. 4, in which a Fresnel lens with an entrance aperture of (80 × 80) mm ² and a focal length of 150 mm was used as the primary concentrator. A three-stage photocell (3 × 3) mm ² based on a GaInP / GaAs / Ge nanoheterostructure, mounted on an alumina board, was used as a photovoltaic cell. The focal point in the form of a truncated pyramid was made of anodized aluminum with highly reflective and antireflection coatings with a total reflectance of no less than 96% and a diffuse reflection fraction of no more than 3%. The photovoltaic cell is installed at a distance of 155 mm from the Fresnel lens. The height and angle of inclination of the edges of the truncated pyramid were 18 mm and 22 °, respectively. The larger base of the focal point was covered with a 1 mm thick glass plate attached with an optical silicone sealant. The gaps between the edges of the smaller base of the focal point and the non-light-sensitive surfaces of the photovoltaic cell are closed with a layer of elastic silicone sealant. The distance between the smaller base of the focal point and the photovoltaic cell was set to 150 μm. The exit aperture of the focal point had the shape of a square with a side of 2.6 mm. Due to the use of the focal point, the permissible positioning error of the photoelectric element when mounted on the photo-receiving panel of the module increases from ± 0.2 mm (without the focal point) to ± 1.2 mm (with the focal point). The sector of misorientation angles from the direction to the Sun, in which the output power of the module was no less than 0.9 of the maximum value, was ± 0.85 °. The efficiency of the module with the installed focal point was 34%, which is 3% higher than without the focal point.

Example 2 A concentrator photovoltaic module shown in FIG. 5, in which a lens panel consisting of 32 Fresnel lenses with an entrance aperture of (120 × 120) mm ² and a focal length of 220 mm was used as the primary concentrator. Three-stage photovoltaic cells based on GaInP / GaAs / Ge nanoheterostructure, mounted on aluminum oxide boards, were used as photovoltaic cells. Tubes in the form of truncated pyramids were made of anodized aluminum with highly reflective and antireflection coatings with a total reflectance of at least 96% and a diffuse fraction of no more than 3%. The photovoltaic cells were mounted 225 mm from the Fresnel lens. The height and angle of inclination of the faces of the foxes were 15 mm and 19 °, respectively. The large bases of the focal lengths are covered with glass plates 0.5 mm thick. The distances between the output aperture of the foxes and the photovoltaic cells are set equal to 200 μm. The output aperture of the foxes had the shape of a square with a side of 4 mm. In accordance with the above ratios, the following values of the parameters of the concentrator photovoltaic module were achieved: the permissible positioning error of the photoelectric cells during the installation of the photodetector panel of the module increases from ± 0.2 mm (without foci) to ± 1 mm (with foci), the sector of misorientation angles, in where the output power of the module was not less than 0.9 of the maximum value was ± 0.8 °; The efficiency of the module with installed foxes was 32%, which is 3% higher than without foci.

The result of the technical solution was the development of concentrator photovoltaic modules with increased reliability, increased service life and high conversion efficiency of solar radiation.

Claims (7)

1. A concentrator photovoltaic module including a monolithic front panel, side walls and a rear panel, at least one primary optical concentrator in the form of a lens formed in the form of a rear surface of the front panel, at least one secondary optical concentrator in the form of a focal point, with the smaller base facing to the photosensitive surface of a photovoltaic cell with a heat sink located on the front surface of the rear panel, coaxial to the corresponding primary optical concentrator, characterized in that the opposite edges of the larger base of the focal point are equipped with L-shaped petals, the horizontal shelves of which are fixed on the front surface of the heat-conducting alumina panel to form a gap Between the smaller base of the focal point and the photosensitive surface of the photovoltaic cell, the larger base of the focal point is closed with a plate of silicate glass, attached with an optical silicone sealant to the faces of the larger base of the focal point, and the contact areas to the photovoltaic cell, to the heat-conducting alumina panel and the spaces between the edges of the smaller base of the focal point and non-photosensitive surfaces of the photovoltaic cell are filled with a layer of optical silicone sealant. 2. The module according to claim 1, characterized in that the lens of the primary optical concentrator is made of silicone on the back surface of the front panel made of silicate glass. 3. The module according to claim 1, characterized in that the lens of the primary optical concentrator is made in the form of a Fresnel lens. 4. The module according to claim 1, characterized in that the fokon is made of anodized aluminum sheet with a thickness of (0.3-1.0) mm with a mirror-polished inner surface. 5. The module according to claim 1, characterized in that the fokon is made in the form of a hollow truncated pyramid. 6. The module of claim. 1, characterized in that the focal point is made in the form of a hollow truncated cone. 7. The module according to claim 1, characterized in that the heat-conducting alumina panel is made with a thickness of (0.2-1.0) mm and is coated on both sides with a copper layer.

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