RU2436192C1 - Photovoltaic module with nanostructure photocell - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: photovoltaic module with a nanostructure photocell (1) has a primary optical concentrator (3) in form of a Fresnel lens whose optical axis (4) passes through the centre of the photoactive region (2) of the nanostructure photocell (1), made in form of a circle of diameter d and a secondary concentrator in line with the primary concentrator (6).The secondary concentrator (6) is placed at distance h₁ from the front surface of the Fresnel lens and consists of a front optical element (8) in form of part of a sphere of radius R, base diameter D and height h₂, an intermediate optical element (10) of thickness h₃ with parallel front and rear surfaces and a rear optical element (11) made in form of a cylinder of diameter d and height h₄, where values h₁, h₂, h₃, h₄, R and D satisfy certain relationships.

EFFECT: photovoltaic module is simple to design, has good photovoltaic characteristics, provides reliable and long-term operation.

7 cl, 5 dwg

Description

The invention relates to the field of solar energy, in particular to concentrator photovoltaic modules. The present invention is intended for use in solar concentrator power plants used as power supply systems in various climatic zones.

One of the most promising methods for generating electricity from renewable sources is the photoelectric conversion of concentrated solar radiation using highly efficient cascade nanostructured photocells and inexpensive optical concentrators. It is known that the use of radiation concentrators, provided that their parameters are matched with the parameters of the photocells, allows not only to increase the energy efficiency of the PV modules, but also to improve their energy and economic performance by reducing the consumption of expensive semiconductor materials. The use of the latter at a concentration of solar radiation of 500-2500 times allows you to proportionally reduce the total area of solar cells and significantly reduce the cost of electricity. But, at the same time, with a high degree of concentration of solar radiation, excessive heating of the solar cells occurs, which negatively affects the transforming properties of the solar cells, their service life and output characteristics of the photovoltaic modules. Therefore, the design of photovoltaic modules with solar concentrators should be such as to ensure reliable and long-term effective functioning of the solar cells in actual use at the lowest possible cost of generated electrical power.

A known photovoltaic module designed for solar concentration control (see patent US 6653551, class H01L 31/052, published November 25, 2003), containing many solar electric concentrators with a four-stage solar radiation concentration system. Each solar electric hub includes a first optical hub in the form of a Fresnel lens mounted on the front panel and concentrating solar radiation five to ten times, a second optical hub in the form of a Fresnel lens mounted on the intermediate panel, and a third optical hub in the form of a parabolic hub located under a second concentrator on the rear panel and concentrating solar radiation twenty to fifty times, and a fourth optical concentrator in the form of glass lens. Under the fourth optical hub is a multi-junction solar cell.

The known photovoltaic module has high efficiency, but its efficiency is low due to the cost of a large number of optical elements, and also because of the need to accurately install four optical concentrators coaxially when assembling the structure.

A known photovoltaic module (see patent US 6717045, IPC H01L 31/052, published 04/06/2004), including many optical concentrators focusing solar radiation on the photodetector area of solar cells. Each of the optical concentrators consists of a primary concentrator having a solar radiation concentration of 5-10 times, a secondary concentrator located below the first one and increasing the solar radiation concentration by 20-50 times, and a third concentrator mounted in the lower plane of the secondary concentrator and focusing the radiation to the surface of solar cells. As a primary concentrator, a Fresnel lens can be used. The secondary concentrator is a combined parabolic reflector made of glass or ceramic and having reflective and protective coatings. A glass lens serves as the third hub. A solar photocell is installed on a site having fins for heat dissipation.

The disadvantages of the known design of the solar photovoltaic module are the large loss of light due to reflection on the surfaces of the optical elements of a three-stage concentrator, the technical difficulties of manufacturing, mounting and aligning a large number of optical parts and, accordingly, also the high cost of the structure.

A known photovoltaic concentrator module (see PCT application WO 2007093422, IPC H01L 31/052, published August 23, 2007) comprising a lens panel and a panel with solar cells mounted on a support frame that provides sealing of the module’s internal volume and protects the optical elements from external influences Wednesday. Concentrator lenses are installed on the lens panel, which are Fresnel lenses. Solar cells made on the basis of multilayer heterostructures in the A ^III- B ^{V system} are soldered to heat sinks and mounted on the lower carrier panel so that the photodetector area of each solar cell is located in the focus of one of the Fresnel lenses.

The disadvantages of the known design of the concentrator photovoltaic module is the difficulty of installing with high accuracy a large number of solar cells on the carrier panel and low misorientation characteristics of the device, requiring the use of more accurate and complex tracking systems for the sun.

A known photovoltaic module (see application RU 2009122813, IPC H01L 31/00, published 06/15/2009), which contains side walls, a front panel with Fresnel lenses on its inner side, a translucent back panel and solar cells. The solar cells are equipped with heat sinks and are installed in the centers of the holes of the slats parallel to each other and made of dielectric material with a double-sided metal coating, to which the corresponding contacts of the solar cells are connected. Trims are installed behind the front panel. The center of the photodetector area of each solar cell lies on the same axis as the center of the corresponding Fresnel lens and coincides with the focus of this lens. The design of the photovoltaic module reduces the complexity of its manufacture and improves the accuracy of installation of solar cells.

A disadvantage of the known design of the photovoltaic module is the low disorientation characteristic of the device, requiring the use of more accurate and complex tracking systems for the sun.

Known solar photovoltaic module (see patent RU 2352023, IPC H01L 31/052, published April 10, 2009), containing side walls, a front panel and a rear panel made of silicate glass, primary and secondary optical concentrators and solar photocells with heat-removing elements. Primary optical hubs are made in the form of contacting lenses formed in the form of the back surface of the front panel by injection molding. Secondary optical concentrators are made in the form of focons installed on a smaller photosensitive surfaces of solar photocells with heat-removing elements placed on the front surface of the rear panel coaxially with the corresponding primary optical concentrators. Secondary optical concentrators can improve the disorientation characteristics of the solar photovoltaic module.

The disadvantages of the known solar photovoltaic module are the complexity of the manufacture and installation of secondary optical concentrators on the photosensitive surfaces of solar photocells, as well as additional optical losses when light is reflected by the side surfaces of the focons.

Known solar photovoltaic module (see patent US 6804062, IPC G02B 27/10, published 12.11.2004). The solar photovoltaic module contains the first lens panel made of Fresnel lenses made of silicone rubber, the second lens panel made of silicone rubber and contains a set of short-focus immersion lenses and an assembly of photoelectric converters based on thin-film solar cells. Moreover, the first lens panel of Fresnel lenses is located above the second lens panel of short-focus immersion lenses so that the incident solar radiation is focused by the lenses into a set of light points, each of which coincides with the photodetector area of one of the solar cells. A second silicone rubber lens panel containing a set of short-focus immersion lenses is glued to the photovoltaic assembly using liquid two-component silicone rubber. The considered solar photovoltaic module has a good disorientation characteristic.

The design disadvantages of the known solar photovoltaic module are the difficulty of mounting a panel of secondary optical concentrators made of silicone rubber in large industrial solar modules, in addition, short-focus immersion lenses made of silicone rubber, as well as the contact points of solar cells with the surfaces of immersion lenses, work at high the concentration of solar radiation generated by primary optical concentrators on Fresnel lenses. This leads to the degradation of the material (silicone rubber) of short-focus immersion lenses and places of contact of solar cells with the surfaces of immersion lenses, which degrades the quality of secondary optical concentrators, reduces the reliability of solar cells and reduces the life of the solar module.

A known photovoltaic module (see patent RU 2307294, IPC H01L 31/052, published September 27, 2007), coinciding with the claimed technical solution for the largest number of essential features and adopted for the prototype. The photovoltaic module contains side walls and a front panel of silicate glass with Fresnel lenses on its rear side, as well as nanostructured photocells with heat-removing bases. The heat sink bases are located on the rear panel of silicate glass or are made in the form of trays with a flat bottom, through the central longitudinal lines of the surfaces of which pass the optical axis of the corresponding Fresnel lenses. An additional intermediate panel of silicate glass has been introduced, on the front or back of which are installed flat-convex lenses, coaxial with the corresponding Fresnel lenses. The light-receiving surfaces of nanostructured photocells are located in the focal spot of two concentrator-Fresnel lenses and plano-convex lenses. Depending on the embodiment of the module, the distance between the intermediate panel and the heat-removing bases, the focal length of the plano-convex lenses, the thickness of the photocells, the intermediate panel and the plano-convex lenses are related by the ratios given in the claims.

The well-known photoelectric module provides an increase in the energy efficiency of the module and has a good disorientation characteristic. However, a disadvantage of the known prototype module is the high level of concentration of solar radiation on the solar cells. In the center of the focal spot of two concentrator-Fresnel lenses and a plano-convex lens, the concentration of solar radiation reaches 5000-7000 times, which reduces the efficiency of conversion of light into electricity and reduces the life of the photocells.

The problem solved by the claimed technical solution is the creation of a photovoltaic module with increased reliability and increased service life by reducing the local concentration of solar radiation and leveling the illumination of the photoactive region of the solar cell while maintaining high energy performance and good disorientation characteristic.

The problem is solved in that the photovoltaic module with a nanostructured photocell includes a primary optical hub in the form of a Fresnel lens, the optical axis of which passes through the center of the photoactive region of the nanostructured photocell, made in the form of a circle with a diameter d and a secondary concentrator coaxial with it, installed at a distance of h ₁ from the front surface of the Fresnel lens. The secondary hub consists of a frontal optical element in the form of a part of a sphere of radius R, base diameter D and height h ₂ , an intermediate optical element of thickness h ₃ with parallel frontal and rear surfaces and a rear optical element made in the form of a cylinder with a diameter equal to d and height h ₄ . The values of h ₁ , h ₂ , h ₃ , h ₄ , R and D satisfy the relations, mm:

h ₁ + h ₂ + h ₃ = F;

0.5d <h ₂ <0.07F;

0 <h ₃ <4 mm;

d <h ₄ <3d,

(h ₂ + h ₃ ) <R <2.5 · (h ₂ + h ₃ );

1.5 · S · (Fh ₁ -h ₂ ) <D <2.5 · S · (Fh ₁ -h ₂ );

where F is the total focal length of the primary and secondary optical concentrators, mm;

S - aperture of the Fresnel lens, rel. units

The intermediate optical element of the secondary hub can be made in the form of an inverted truncated cone, the diameter of the front base of which is equal to D, and the diameter of the rear base is equal to d.

The intermediate optical element of the secondary concentrator can be made in the form of a spherical layer with a radius equal to R, the diameter of the upper base equal to D, and the diameter of the lower base equal to 2R.

The intermediate optical element of the secondary concentrator can be made in the form of a plate, the linear dimensions of which repeat the linear dimensions of the Fresnel lens.

The intermediate optical element of the secondary concentrator can be made in the form of a cylinder with a diameter equal to the diameter D of the front optical element.

All three optical elements of the secondary concentrator can be made of the same material with a refractive index n satisfying the ratio:

1.4 <n <1.7.

The front and intermediate optical elements of the secondary concentrator can be made of material with a refractive index n satisfying the ratio:

1.4 <n <1.7,

and the rear optical element can be made of aluminum in the form of a hollow cylinder with an internal mirror surface.

The choice of the optimal range for the value of the height h ₂ cannot be carried out analytically due to the complexity of the rays in the elements of the secondary concentrator. In this regard, a program for numerically calculating a model of primary and secondary concentrators of specific sizes was compiled, and the calculation results were generalized to concentrating systems of any size based on the principle of similarity of the ray path when scaling the optical system. The experimental modeling of the efficiency of the primary and secondary optical concentrators was carried out for the focal length of the Fresnel lens equal to 70 mm and the size of the input aperture of the Fresnel lens 40 × 40 mm. Since the path of the rays in the optical system remains unchanged while maintaining the aspect ratio of the optical elements, and given that the size of the focused spot due to the angular divergence of solar radiation is 0.01 of the focal length of the lens, it was found that the maximum value of h ₂ should not exceed 0, 07 F. The minimum value of h ₂ was set equal to 0.5d, in this case, with a minimum value of radius R, the spherical surface of the front element of the secondary optical concentrator turns into a hemisphere with diameter equal to the diameter of the rear optical element of the secondary optical hub.

The intermediate optical element of the secondary concentrator serves to fix and align the front optical element and the rear optical element of the secondary optical concentrator. Height h ₃ is selected in the range from 0 to 4 mm for design reasons. Making an intermediate optical element above 4 mm is undesirable due to the increase in the weight of the device.

The height h _{1 is} set so that the sum of h ₁ + h ₂ + h _{3 is} equal to the total focal length F of the primary and secondary optical concentrators, which ensures focusing of solar radiation on the light receiving surface of the rear optical element of the secondary optical concentrator.

The choice of height h ₄ in the range d <h ₄ <3d is determined by the number of reflections of focused sunlight from the side surface of the rear optical element before it enters the photoactive region of the nanostructured photocell. Given the magnitude of the angle of total internal reflection for optical materials with a refractive index n in the range 1.4 <n <1.7, at h ₄ = d part of the sun's rays undergo at least one total internal reflection from the side surface of the rear optical element. At h ₄ = 3d, part of the sun's rays undergoes up to three reflections from the lateral surface of the rear optical element. Increasing the number of reflections of focused sunlight from the side surface of the rear optical element by more than three is impractical due to the increase in radiation loss.

At a minimum value of radius R equal to h ₂ + h ₃ , the spherical surface of the front optical element of the secondary concentrator turns into a hemisphere with the center lying on the light-receiving surface of the rear optical element of the secondary concentrator. The spherical surface of the front optical element of the secondary concentrator with a radius R greater than 2.5 · (h ₂ + h ₃ ) does not significantly affect the additional focusing of solar radiation and, accordingly, to improve the disorientation characteristics of the device.

The diameter of the light spot focused by the primary optical concentrator at the level of the front optical element of the secondary concentrator is equal to S · (Fh ₁ -h ₂ ), therefore, to ensure the disorientation characteristics of the device, the minimum diameter D of the front optical element of the secondary concentrator must be at least 1.5 · S · (Fh ₁ -h ₂ ). However, increasing the diameter D of the front optical element of the secondary concentrator by more than 2.5 · S · (Fh ₁ -h ₂ ) is impractical due to the increase in weight and cost of the device.

Variants of the claimed photovoltaic module with a nanostructured photocell are illustrated in the drawing, where

figure 1 schematically shows a photovoltaic module with a nanostructured photocell;

figure 2 shows a photovoltaic module with a nanostructured photocell, in which the intermediate optical element of the secondary concentrator is made in the form of an inverted truncated cone;

figure 3 shows a photovoltaic module with a nanostructured photocell, in which the intermediate optical element of the secondary concentrator is made in the form of a spherical layer with a radius equal to R, the diameter of the upper base equal to D, and the diameter of the lower base equal to 2R;

figure 4 shows a photovoltaic module with a nanostructured photocell, in which the intermediate optical element of the secondary concentrator is made in the form of a plate with linear dimensions equal to the linear dimensions of the Fresnel lens;

figure 5 shows a photovoltaic module with a nanostructured photocell, in which the intermediate optical element of the secondary concentrator is made in the form of a cylinder with a diameter equal to the diameter D of the front optical element, and the rear optical element is made in the form of a hollow aluminum cylinder with an internal mirror surface.

The inventive photoelectric module with a nanostructured photocell (see figure 1, figure 2, figure 3, figure 4, figure 5) contains a nanostructured photocell 1, the photoactive region 2 of which is made in the form of a circle with a diameter d, the primary optical concentrator 3 in the form Fresnel lens, the optical axis 4 which passes through the center of the photoactive region 5 2 1 nanostructured photocell and secondary coaxially with a hub 6 mounted at a distance h ₁ from the front surface 7 of the primary optical concentrator 3. Secondary optical concentrate 6 is composed of three optical elements: a front optical member 8 with a diameter D and a height h _2, constructed with a spherical front surface 9 of the radius R, an intermediate optical element 10 in height h ₃ and the rear optical member 11, made in the form of a cylinder with a diameter equal to d and with height h ₄ . The height h _{1 is} set so that the sum of h ₁ + h ₂ + h _{3 is} equal to the total focal length F of the primary optical hub 3 and the secondary optical hub 6, the height h _{2 of the} front optical element 8 of the secondary optical hub 6 is set in the range 0.5d <h ₂ 0.07F, height h _{3 of the} intermediate optical element 10 of the secondary optical concentrator 6 is set in the range 0 <h ₃ <4 mm, the radius R of the spherical frontal surface 9 of the frontal optical element 8 of the secondary optical concentrator 6 is set flax in the range (h ₂ + h ₃ ) <R <2.5 · (h ₂ + h ₃ ), and the diameter D of the front optical element 8 of the secondary optical hub 6 is set in the range 1.5 · S · (Fh ₁ -h ₂ ) <D <2.5 · S · (Fh ₁ -h ₂ ), where S is the aperture of the primary optical concentrator 3 (Fresnel lenses). The height h _{4 of the} rear optical element 11 of the secondary optical hub 6 is set in the range d <h ₄ <3d. The intermediate optical element 10 of the secondary hub 6 can be made (see figure 2) in the form of an inverted truncated cone, the diameter of the front base 12 of which is set equal to the diameter D of the front 8 of the optical element, and the diameter of the rear base 13 is set equal to d. The intermediate optical element 10 of the secondary concentrator 6 can be made (see FIG. 3) in the form of a spherical layer with a radius equal to R, the diameter of the upper base 14 equal to D, and the diameter of the lower base 15 equal to 2R. The intermediate optical element 10 of the secondary hub 6 can be made (see figure 4) in the form of a plate with linear dimensions equal to the dimensions of the Fresnel lens. The intermediate optical element 10 of the secondary concentrator 6 can be made (see FIG. 5) in the form of a cylinder with a diameter equal to the diameter D of the front optical element 8, and the rear optical element 11 of the secondary concentrator 6 can be made of aluminum in the form of a hollow cylinder with an inner mirror surface 16.

When the inventive photoelectric module with a nanostructured photocell 1 is oriented perpendicular to the sun's rays, the solar radiation incident on the input aperture of the primary optical concentrator 3 is focused by it and the front optical element 8 of the secondary optical concentrator 6 on the light receiving surface of the rear optical element 11 of the secondary optical concentrator 6, then in the form of a diverging light beam passes into the rear optical element 11 of the secondary optical concentrate ora 6. Through the output surface of the rear optical element 11 of the secondary optical concentrator 6, a diverging light beam enters the photoactive region 2 of the nanostructured photocell 1 either directly or after single or multiple reflections from the side surface 16 of the rear optical element 11 of the secondary optical concentrator 6. In this case, the disorientation the characteristic of the solar photovoltaic module, determined by the ratio of the sizes of the photoactive region 2 and the focal spot dimeter, remains Xia constant and higher than in the photovoltaic modules without secondary optical concentrator; the distribution of the concentration of solar radiation on the surface of the photoactive region 2 of the nanostructured photocell 1 is more uniform than in the focal spot of the primary and secondary optical concentrators 3, 6, and the maximum values of the local concentration of solar radiation are significantly lower than when using 6 convex lenses as secondary optical concentrators. A more uniform distribution of the concentration of solar radiation over the surface of the photoactive region 2 of the solar cell 1 leads to a decrease in the local overheating of the solar cell 1, increase the reliability of its operation and increase the efficiency of conversion of solar radiation into electrical energy.

The use of the proposed photovoltaic module gives a large economic effect, due to the fact that the photovoltaic module is simple in design, has high photovoltaic characteristics, provides reliable and long-term operation.

Claims (7)

1. A photovoltaic module with a nanostructured photocell, including a primary optical hub in the form of a Fresnel lens, the optical axis of which passes through the center of the photoactive region of the nanostructured photocell, made in the form of a circle with a diameter of d, and a secondary concentrator coaxial with it, installed at a distance of h ₁ from the front surface and a Fresnel lens consisting of a front optical member in the form of a sphere of radius R, the base diameter D and a height h _2, the intermediate optical element ₃ with a thickness h p is parallel to the front and rear surfaces of the rear and the optical element formed as a cylinder with a diameter equal to d, and the height h _4, wherein the magnitude of h _1, h _2, h _3, h _4, R and D satisfy mm:
h ₁ + h ₂ + h ₃ = F;
0.5d <h ₂ <0.07F;
0 <h ₃ <4 mm;
d <h ₄ <3d;
(h ₂ + h ₃ ) <R <2.5 · (h ₂ + h ₃ );
1.5 · S · (Fh ₁ -h ₂ ) <D <2.5 · S · (Fh ₁ -h ₂ ),
where F is the total focal length of the primary and secondary optical concentrators, mm;
S - aperture of the Fresnel lens, rel. units 2. The photovoltaic module according to claim 1, characterized in that the intermediate optical element of the secondary hub is made in the form of an inverted truncated cone, the diameter of the front base of which is equal to D, and the diameter of the rear base is equal to d. 3. The photovoltaic module according to claim 1, characterized in that the intermediate optical element of the secondary concentrator is made in the form of a spherical layer with a radius equal to R, the diameter of the upper base equal to D, and the diameter of the lower base equal to 2R. 4. The photovoltaic module according to claim 1, characterized in that the intermediate optical element of the secondary hub is made in the form of a plate, the linear dimensions of which repeat the linear dimensions of the Fresnel lens. 5. The photovoltaic module according to claim 1, characterized in that the intermediate optical element of the secondary concentrator is made in the form of a cylinder with a diameter equal to the diameter D of the front optical element. 6. The photovoltaic module according to claim 1, characterized in that all three optical elements of the secondary concentrator are made of the same material with a refractive index n satisfying a ratio of 1.4 <n <1.7. 7. The photovoltaic module according to claim 1, characterized in that the front and intermediate optical elements are made of material with a refractive index n satisfying the ratio
1.4 <n <1.7, and the rear optical element is made of aluminum in the form of a hollow cylinder with an internal mirror surface.

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