RU2445553C2 - Solar concentrator module and method of its manufacturing (versions) - Google Patents

Abstract

FIELD: power engineering.

SUBSTANCE: in a solar concentrator module comprising an optically transparent element with inlet and outlet faces of different sizes, reflecting surfaces on side faces and a radiation receiver installed on the outlet face of smaller size, the optical element is made of hardened polysiloxane gel arranged in the cavity between the inlet face comprising a protective transparent barrier, the outlet face comprising the radiation receiver, and the reflecting surfaces, and the reflecting surfaces are made in the form of a sheet thin-walled mirror reflector. In the other version of the module optically transparent elements are made of hardened polysiloxane gel arranged in the cavity between two inlet faces formed by two protective transparent barriers, side reflecting surfaces made of a sheet mirror reflector and each side of the receiver. A solar concentrator module is manufactured by generation of an optical element with inlet and outlet surfaces of different sizes and application of reflecting surfaces onto side faces of the optical element, a closed cavity is formed with side surfaces from the sheet mirror reflector, the radiation receiver on the outlet surface and the transparent protective barrier on the inlet surface, a previously vacuumised mixture of polysiloxane gel components is filled into the cavity, and polysiloxane gel is structured in the range of temperatures and duration of the process from the temperature of 20°C during 24 hours until the temperature of 150°C during 3 minutes under vibration exposure. In the other version of the method two closed cavities are formed with inlet and outlet surfaces of different sizes, the specified cavities are connected along the outlet surface of smaller section with side surfaces from the sheet mirror reflector, two closed cavities are installed with the surface of one of inlets with larger cross section to the transparent protective barrier in the horizontal plane, the surface of contact is sealed between the cavity and the protective transparent barrier, the mixture of polysiloxane gel components is filled into one of two closed cavities arranged on the protective transparent coating, the receiver is installed at the joint of outlet surfaces of smaller section of two cavities, the mixture is filled into the second closed cavity, the second protective transparent barrier is installed on the outlet surface of the second cavity, structuring is carried out in both closed cavities in the range of temperatures and duration of the process from the temperature of 20°C for 24 hours to the temperature of 150°C for 3 minutes under vibration exposure.

EFFECT: higher specific capacity of the optical element, simplified technology of photoelectric module manufacturing and its reduced cost.

28 cl, 12 dwg

Description

The invention relates to solar technology, in particular to solar concentrator modules for generating electrical and thermal energy.

A known photovoltaic module containing a solar energy concentrator made in the form of an optically transparent prism of total internal reflection having the shape of a truncated quadrangular pyramid (AS USSR No. 1620784, MKI F24J 2/08, BI No. 2, 1991).

Different-sized rectangular bases serve as the faces of the input and output of radiation. The photoconverter is installed in contact with the face of the radiation output, i.e. in contact with a smaller base. The ratio of the face areas of the prism containing the working surface and solar cells determines the theoretical concentration coefficient of the solar photovoltaic module.

The disadvantage of this design solution is the need to cut round silicon wafers, which leads to an increase in the cost of the module.

A known photovoltaic module containing an optical element with a trapezoidal cross-section, the side faces of which are made reflective of radiation, and different-sized bases serve as faces of the input and output of radiation, having the shape of a truncated cone (AS USSR No. 1048260, MKI F24J 3/02, BI No. 38, 1983). The disadvantage of this design is the low utilization of the working surface when forming solar receiving surfaces from a large number of individual photovoltaic modules with a receiving surface in the form of a circle. The surface fill factor in this case is small, therefore, a significant part of the solar radiation does not fall on the surface of the photoconverter, which leads to a decrease in the output power of the photovoltaic module.

Known solar photovoltaic module with a concentrator of radiant energy, containing an optically transparent element with input and output faces and a photoconverter, the input face is made in the form of a hexagon. In the design variant of the module, a photoconverter with two-sided sensitivity is used, which is mounted on the round output faces of two identical optical elements of solar photovoltaic modules directed in opposite directions. (Solar photovoltaic module with a concentrator of radiant energy (options). Pat. RF No. 2158045 10/20/2000).

A disadvantage of the known module is the large volume of the optical element made of glass and the high complexity of its manufacture. Another disadvantage of the known solar concentrator modules is the use of photoconverters without a cooling system as receivers, which leads to overheating and lower efficiency when the concentration is high.

A known method of manufacturing concentrator modules based on prismacons from organic or optical glass with the deposition of a reflective layer of aluminum, silver or other metals by chemical deposition or vacuum spraying (Strebkov D.S., Tveryanovich E.V. Concentrators of solar radiation. M: GNU VIESH , 2007, p. 91, 95, 104). The disadvantage of this method is the high complexity of surface treatment of glass and a low reflectance of the layers obtained by the deposition or vacuum deposition.

The objective of the invention is to increase the efficiency of the concentrator module by removing heat from the photodetector in the module and reduce its cost by using new material of the optical element and simplifying the manufacturing technology of the concentrator module.

As a result of using the present invention, the specific power of the optical element increases, the manufacturing technology of the photovoltaic module is simplified, and its cost is reduced.

The above technical result is achieved in that in a solar concentrator module containing an optically transparent element with different input and output faces, reflecting surfaces on the side faces and a radiation receiver mounted on a smaller output face, the optical element is made of a cured polysiloxane gel located in the cavity between the input face containing a transparent protective fence, the output face containing the radiation receiver, and reflective surfaces, and I reflect s surface formed as a thin-walled flat mirror reflector.

In a variant of the solar concentrator module, the radiation receiver is made in the form of a photoconverter connected by a heat-conducting material to a sheet mirror reflector.

In another embodiment of the solar concentrator module, the receiver is made in the form of a photoconverter and is equipped with a heat removal circuit with an air cooling system.

In another embodiment of the solar concentrator module, the receiver is made in the form of a photoconverter and is equipped with a heat removal circuit with a liquid coolant.

In another embodiment of the solar concentrator module, the radiation receiver is made in the form of a heat absorber with a selective coating on the working surface on which the radiation is incident, and is equipped with an air-cooled heat removal circuit.

In a variant of the solar concentrator module, the radiation receiver is made in the form of a heat absorber with a selective coating, thermally insulated from an optically transparent element and a mirror reflector and connected to a heat removal circuit with a liquid coolant.

In a solar concentrator module containing two identical optically transparent elements having a side reflective surface, an input face and an output face smaller and a receiver with a two-sided working surface mounted on the output faces of the optical elements directed in opposite directions, the optically transparent elements are made of cured polysiloxane gel located in the cavity between two entrance faces, formed by two protective transparent fences, lateral reflecting E surfaces made of sheet specular reflector, and each receiver side.

In a variant of the solar concentrator module, the radiation receiver is made in the form of a two-sided photoconverter connected by a heat-conducting material with two sheet mirror reflectors on the outside of the side reflective surfaces.

In another embodiment of the solar concentrator module, the receiver is made in the form of a two-sided photoconverter and is equipped with a heat removal circuit with an air cooling system.

In the embodiment of the solar concentrator module, the receiver is made in the form of a two-sided photoconverter and is equipped with a heat removal circuit with a liquid coolant.

In a variant of the solar concentrator module, the radiation receiver is made in the form of a two-sided thermal absorber with a selective surface on two working surfaces on which radiation is incident, and is equipped with an air-cooled heat removal circuit.

In a variant of the solar concentrator module, the thermal absorber with a two-sided working surface is equipped with a water-cooled heat removal circuit.

In the method of manufacturing a solar concentrator module by forming an optical element with different entrance and exit surfaces and applying reflective surfaces on the side faces of the optical element, a closed cavity is formed with side surfaces from a sheet mirror reflector, a radiation receiver on the exit surface and a transparent protective fence on the entrance surface, a pre-evacuated mixture of polysiloxane gel components into the cavity and the snares are structured ANOVA of the gel in the cavity in a range of temperatures and duration of the process from 20 ° C temperature for 24 hours to a temperature of 150 ° C for 3 minutes when subjected to vibration.

In an embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a photoconverter and connected with a heat-conducting material with a sheet mirror reflector.

In another embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a photoconverter and a heat removal circuit with an air cooling system is connected to the photoconverter.

In another embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a photoconverter and a heat removal circuit with a liquid coolant is connected to the photoconverter.

In the method of manufacturing a solar concentrator module by forming two optically transparent elements with different input and output surfaces, applying reflective surfaces to the side faces of each optical element, placing a two-sided photoconverter on the exit surface of a smaller section of one of the optically transparent elements and connecting two optical elements along the exit plane faces of a smaller cross section, form two closed cavities with different entrance and exit surfaces, soy these cavities are molded along the exit surface of the smaller section by the side surfaces from the sheet mirror reflector, two closed cavities are mounted by the surface of one of the inputs of the larger section on a transparent protective fence in the horizontal plane, the contact surface of the cavity and the protective transparent fence is sealed, a mixture of siloxane gel components is poured into one two closed cavities, located on a protective transparent coating, install the receiver at the junction of the exit surfaces less cross section of two cavities, pour the mixture of components into the second closed cavity, install a second protective transparent fence on the exit surface of the second cavity, carry out structuring in both closed cavities in the temperature range and the duration of the process from a temperature of 20 ° C for 24 hours to a temperature of 150 ° C within 3 minutes when exposed to vibration.

In an embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a two-sided photoconverter and the receiver is connected with a heat-conducting material with a sheet mirror reflector.

In an embodiment of the method for manufacturing a solar concentrator module, the receiver is made in the form of a two-sided photoconverter and a heat removal circuit with an air cooling system is connected to the two-sided converter.

In another embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a two-sided photoconverter and a heat removal circuit with a liquid coolant is connected to the two-sided photoconverter.

In another embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a thermal absorber with a two-sided working surface with internal air channels and a thermal absorber is connected to the air-cooled heat removal circuit.

In another embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a heat absorber with a two-sided working surface with internal channels for pumping a liquid coolant and a heat absorber is connected to an air-cooled heat removal circuit.

In the method of manufacturing a solar concentrator module by forming two optically transparent elements with different input and output surfaces, applying reflective surfaces to the side faces of each optical element, placing a two-sided photoconverter on the exit surface of a smaller section of one of the optically transparent elements and connecting two optical elements along the exit plane faces of a smaller cross section form the lateral surfaces of two symmetrical isolated cavities with equal with double-sided surfaces of the entrance and exit of the sheet mirror reflector, double-sided radiation detectors are fixed on a transparent substrate at a distance from each other equal to Dd, where D and d are the dimensions of the faces of the entrance and exit, lateral sheet mirror reflectors are fixed on the transparent substrate with a smaller exit surface the boundary of the radiation receivers, optical transparent elements are formed by pouring a mixture of polysiloxane gel components into each of the formed cavities, a transparent protective shield is installed forming on the entrance surface of optically transparent elements, polysiloxane gel is structured in the temperature range and the duration of the process from a temperature of 20 ° C for 24 hours to a temperature of 150 ° C for 3 minutes when exposed to vibration, then optically transparent elements are formed on the other side of the transparent substrate by fixing sheet mirror reflectors with a smaller exit cross-section surface along the boundary of the radiation receivers, pouring a mixture of siloxane gel components into each of the formed cavities, installation of a transparent protective fence on the entrance surface, structuring and curing of the polysiloxane gel at room temperature for 90-3 minutes when exposed to vibration.

In an embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a two-sided photoconverter and the receiver is connected with a heat-conducting material with a sheet mirror reflector.

In another embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a two-sided photoconverter and a heat removal circuit with an air cooling system is connected to the two-sided converter.

In another embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a two-sided photoconverter and a heat removal circuit with a liquid coolant is connected to the two-sided photoconverter.

In an embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a two-sided photoconverter and the receiver is connected with a heat-conducting material with a sheet mirror reflector.

In another embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a two-sided photoconverter and a heat removal circuit with an air cooling system is connected to the two-sided converter.

In another embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a two-sided photoconverter and a heat removal circuit with a liquid coolant is connected to the two-sided photoconverter.

In another embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a thermal absorber with a two-sided working surface with internal air channels and a thermal absorber is connected to the air-cooled heat removal circuit.

In another embodiment of the method of manufacturing a solar concentrator module, the receiver is made in the form of a heat absorber with a two-sided working surface with internal channels for pumping a liquid coolant and a heat absorber is connected to an air-cooled heat removal circuit.

The essence of the invention is illustrated in figure 1, figure 2, figure 3, figure 4, figure 5, figure 6, figure 7, figure 8, figure 9, figure 10, figure 11, figure 12.

Figure 1 shows a cross section of a solar concentrator module with an optical element in the form of a truncated prism cavity filled with polysiloxane gel, with side sheet mirror reflectors.

Figure 2 shows a plan view of a solar concentrator module with a square receiver and an optical element in the form of a truncated square prism cavity filled with an optically transparent polysiloxane gel, with four lateral flat sheet mirror reflectors and conical mirror reflectors in the corners of the prism cavity.

Figure 3 shows a plan view of a solar concentrator module with a round receiver and an optical element in the form of a truncated hexagonal prism cavity filled with cured polysiloxane gel, with six side flat mirror reflectors.

Figure 4 presents a plan view of a solar concentrator module with a round receiver and an optical element in the form of a truncated conical cavity filled with a cured polysiloxane gel, with conical side mirror reflectors with cut vertical edges in the shape of a hexagon on the entrance surface.

Figure 5 shows a plan view of a solar concentrator module of switched square receivers and an optical element in the form of a truncated rectangular prism cavity filled with cured polysiloxane gel, with two side flat sheet mirror reflectors.

Figure 6 shows a cross section of a solar concentrator module, in which the receiver-photoconverter is thermally insulated and equipped with tubular cooling elements with a liquid coolant.

7 shows a cross section of a solar concentrator module of three optical elements and receivers, in which the side sheet mirror reflectors form closed cavities for air cooling.

On Fig shows a plan view of a solar concentrator module, consisting of six square optical elements and square receivers, in which the side sheet mirror reflectors form cavities for air cooling.

Figure 9 shows a plan view of a solar concentrator module of three rectangular optical elements and nine switched square receivers, side sheet mirror reflectors of the optical elements form cavities for air cooling.

Figure 10 shows a cross section of a solar concentrator module with a common two-sided receiver and two optical elements directed in opposite directions, made in the form of two truncated pyramidal cavities, with side faces of sheet mirror reflectors forming a common housing, filled with cured polysiloxane gel and equipped with water cooling radiator.

11 shows a cross section of a solar concentrator module of three double-sided receivers, each of which is equipped with two optical elements of cured polysiloxane gel, directed in opposite directions and having a common casing of sheet mirror reflector with cavities for air cooling.

12 shows a cross section of a solar concentrator module with a double-sided working surface, in which the double-sided converters are mounted on a glass substrate separating the optical element housings and the air cooling cavities.

Figure 1, the solar concentrator module contains in cross section an optical transparent element 1 made of a cured polysiloxane gel 2 located in the cavity 3 between the input face 4 containing a protective transparent fence 5, the output face 6 containing the radiation receiver 7, and side faces 8, made of sheet thin-walled mirror reflector 9 with a linear size l. Side faces 8 are inclined to the surface of the input face 4 at an angle α.

Figure 2, 3, 4, 5 shows various designs of the solar concentrator module, a plan view, with the cross section shown in figure 1.

In Fig. 2, the solar concentrator module comprises a square receiver 10 and an optical element 1 in the form of a truncated square pyramidal prism cavity 11 filled with a cured polysiloxane gel 2 with four lateral flat sheet mirror reflectors 9 that form an angle α with four input face surfaces 4 and four conical mirror reflectors 12 in the corners of the prism cavity 11, which are inclined to the surface of the input face 4 at an angle β, β> α.

In Fig. 3, the solar concentrator module comprises a round receiver 13 and an optical element 1 in the form of a truncated hexagonal pyramidal prism cavity 14 filled with a cured polysiloxane gel, with six side flat mirror reflectors 9 that are inclined to the surface of the input face 4 at an angle α.

In figure 4, a circular receiver 13 is mounted on the output face 6 of the optical element 1, made in the form of a truncated conical cavity 15 filled with a cured polysiloxane gel. The cavity 15 is formed by conical side mirror reflectors, which are inclined to the surface of the input face 4 at an angle α, and have cut vertical faces 16 in the form of a hexagon on the surface of the input face 4.

5, the optical element 1 is made in the form of a truncated rectangular pyramidal prism cavity 17 filled with a cured polysiloxane gel. The lateral faces of the cavity 17 are made of two flat sheet mirror reflectors 9, the planes of which form an angle α with the input face. The receiver 7 is made of four switched photoconverters 18.

In Fig. 6, in a cross section, the radiation detector - photoconverter 18 is thermally insulated from the optical element 1 by means of a vacuum double-glazed window 19 and is connected to the cooling element 21 with a heat-transfer agent using an insulating heat-conducting coating 20, which is provided with thermal insulation 22 on the outer surface 23 to reduce heat loss into the environment. The cooling element 21 is connected to the circuit of the cooling system (not shown in Fig.6).

In Fig. 7, in the cross section of the solar concentrator module, the lateral sheet mirror reflectors 9 of the three optical elements 1 shown in Fig. 1 form cavities 24 for connecting to an air cooling system comprising a fan and heat exchangers (not shown in Fig. 7).

The solar concentrator modules in Figs. 8 and 9, a plan view, have a cross section shown in Fig. 7.

In Fig. 8, the solar concentrator module contains six optical elements in the form of a square truncated pyramidal cavity 11 filled with cured polysiloxane gel, and six square receivers 10 shown in Fig. 2, in which side sheet mirror reflectors 9 form cavities 24 (see Fig. .7) for connection to an air cooling system (not shown in Fig. 8).

In Fig. 9, the solar concentrator module contains nine switched receivers 7 and three optical elements 1 (see Fig. 5, Fig. 7) in the form of a truncated rectangular pyramidal prism cavity 17 (Fig. 5) of a cured polysiloxane gel, in which the side sheets mirror reflectors 9 form cavities 24 connected to an air cooling system (not shown in Fig. 9).

10, the solar concentrator module comprises a double-sided photoconverter 25 and two optical elements 1, which are in optical contact with the photoconverter 25 with output faces of a smaller section 26 and directed in opposite directions. The lateral faces 27 of both optical elements 1 form a common housing 28 made of flat sheet mirror reflectors 9. The common housing 28 is filled with cured polysiloxane gel 2. On the outer surface of the side mirror reflectors 9 are installed tubular heat exchangers 29 of the cooling system, which are connected to the pumps and heat exchangers of the circuit with a liquid coolant (not shown in FIG. 10).

11, the solar concentrator module contains three double-sided photoconverters 25, each of which is equipped with two optical elements 1 of the cured polysiloxane gel directed in opposite directions. The optical elements 1 have a common housing 28 of sheet flat mirror reflectors 9. The outer surfaces of the mirror reflectors 9 form cavities 24 for connection with an air cooling system. The outer side surfaces of the module have a frame 30.

12, the solar concentrator module contains three double-sided photoconverters 25 mounted on a flat glass substrate 31. On the two sides of each photoconverter 25, two optical elements 1 are attached to the glass substrate 31 with side walls of sheet mirror reflectors 9 filled with cured polysiloxane gel. Both faces of the inlet 4 of the module have a transparent protective fence 5. The outer surfaces of the sheet mirror reflectors 9 form cavities 24 that are connected to the air cooling system (not shown in FIG. 12).

Examples of the implementation of the solar concentrator module.

Example 1. The solar concentrator module contains several rows of sequentially connected photoconverters 18 made of silicon (figure 5). Dimensions of photoconverters: width 62.5 mm, length 125 mm. Each row contains 9 photoconverters 18 and has dimensions: width 62.5 mm, length 1135 mm. Photoconverters 18 are attached to a 3 mm thick tempered glass substrate and form an exit face. At the edges of each row, flat mirror sheet reflectors 9 made of polished aluminum 0.5 mm thick, filled with cured polysiloxane gel, are attached at an angle α = 30 ° along the edges of each row. Entrance faces 4 have a common protective fence 5 of tempered glass 3 mm thick. The dimensions of the optical elements 1: the width of the input face 125 mm, the width of the output face 62.5 mm, length 1135 mm The number of rows with optical elements is 4, the number of connected photoconverters is 36, the geometric concentration coefficient is 2, the peak electric power of the module is 75 W, the operating voltage is 16 V. The dimensions of the module: length 1135 mm, width 55 mm, thickness 25 mm.

Example 2. The solar concentrator module (figure 2) contains 18 square receivers 10, connected in series and mounted on a 3 mm thick tempered glass substrate. The sizes of the photoconverters 10 are made of silicon 125 × 125 mm. Each photoconverter 10 has an optical element 1 in the form of a tetrahedral truncated pyramidal cavity 11 filled with a cured polysiloxane gel. The lateral faces 9 of the optical element 1 are made of polished aluminum with a thickness of 0.5 mm and are inclined to the plane of the input face 4 at an angle α = 48 °. The reflecting surface 12 in the corners of the optical element 1 is made conical, with an angle of inclination to the surface of the input face 4 β = 52 °. The dimensions of the input face are 250x250 mm, the dimensions of the output face are 125 × 125 mm. The module contains a general protective transparent guard 5 of tempered glass 3 mm thick and has dimensions of 75 mm × 150 mm × 40 mm. Peak electrical power of the module is 150 W, operating voltage is 16 V.

An example of a method of manufacturing a solar concentrator module.

Twelve double-sided photoconverters 25 are connected in series 125 with a size of 125 × 125 mm per section (Fig. 12). Three sections commute with each other and fix on a transparent substrate 31 with a distance between sections equal to Dd = 250-125 = 125 mm, where D = 250 mm and d = 125 mm are the linear dimensions of the input 4 and output 6 faces of the optical element 1. Fix along the perimeter of each section on a transparent substrate 31, lateral sheet mirror reflectors 9 at an angle α = 30 ° to the plane of the photo converters 25 so that the distance between the free ends of the reflectors 9 is 250 mm with a reflector size of 33 l = 72 mm. Optical elements 1 are formed by pouring a pre-evacuated mixture of polysiloxane gel components, a common transparent protective fence 5 is made of tempered glass on the verge of entry 4 of all optical elements 1, polysiloxane gel 2 is structured at a temperature of 50 ° C for 1.5 hours when exposed to vibration , then the optical elements 1 are formed in a similar way symmetrically from the opposite side of the transparent substrate 31. A frame 30 is fixed around the perimeter of the module. A box with current outputs from the connected sections is fixed on the frame. The resulting module has a concentration coefficient of 2 when illuminated on each side, voltage 16 V, power 75 watts.

Solar concentrator module operates as follows.

Solar radiation enters through the transparent transparent guard 5 to the input face 4 of the optical element 1, penetrates inward, reaching the side faces 8, is reflected from the sheet mirror reflectors 9 to the receiver 7 (Fig. 1) or to the input face 4 (Fig. 6) at an angle total internal reflection φ, after which it is reflected to the output face 6 of the output of optical radiation to the radiation receiver 7. The angle of total internal reflection

,

,

where n is the refractive index for the input face of glass n = 1.51, φ = 42 °.

For the input face of the polysiloxane gel n = 1.406, φ = 45.3 °.

For radiation incident on the input face 4 at an angle β to the surface, the condition for total internal reflection will be satisfied with the following relationship between the angles α, β, and φ:

,

,

where all angles are measured from the normal to the reflection surface. The minus sign corresponds to 0≤β≤90 °, and the plus sign corresponds to 90 ° ≤β <0.

In a dual solar concentrator module, a two-sided photoconverter 25 with two-sided sensitivity is mounted on the output faces 6 of two optical elements 1 directed in opposite directions (Fig. 10). Solar radiation enters the double-sided photoconverter 25 from two sides due to direct solar radiation and due to the reflection of solar radiation from the environment, for example from the surface of the snow. The concentration coefficient of the solar concentrator module is equal to:

,

,

where S _in - the area of the input face 4, S _o - the area of the output face 6.

For the square receiver 7 in figure 2:

S _in = D ² ,

S _o = d ₂

where D and d are the linear dimensions of the input face 4 and the radiation receiver 7; optical element thickness 1:

;

;

linear size of the input face 4:

D = d + 2h ctg α;

size l of the side sheet mirror 9:

;

;

concentration ratio:

, получим d=2h·ctgα, что соответствует условию максимальной концентрации.Equating the Derivative to Zero

, we obtain d = 2h · ctgα, which corresponds to the condition of maximum concentration.

The design of the solar concentrator module and the method of its manufacture allow solving the following problems:

1. Improving the conversion efficiency of solar energy and specific power of the module through the use of air or liquid cooling systems.

2. Creation of cogeneration solar power plants by generating electrical and thermal energy in the module.

3. Reducing the cost of optical elements by replacing optical glass in prism concentrators with polysiloxane gel.

4. Reducing the cost of manufacturing a solar concentrator module by eliminating the time-consuming operation of processing glass prisms and using the technology of pouring a mixture of polysiloxane gel components into the cavity from mirror reflectors and forming optical elements by curing the polysiloxane gel.

5. The proposed method allows to produce optical elements of complex configuration during the assembly of the solar concentrator module.

Claims (28)

1. A solar concentrator module containing an optically transparent element with different input and output faces, reflecting surfaces on the side faces and a radiation detector mounted on a smaller output face, characterized in that the optical element is made of a cured polysiloxane gel located in the cavity between the input a face containing a protective coating, an output face containing a radiation receiver, and reflective surfaces, and the reflective surfaces are made in the form of thin sheet ennogo mirror reflector. 2. The solar concentrator module according to claim 1, characterized in that the radiation receiver is made in the form of a photoconverter connected by a heat-conducting material to a sheet mirror reflector. 3. The solar concentrator module according to claim 1, characterized in that the receiver is made in the form of a photoconverter and is equipped with a heat removal circuit with an air cooling system. 4. The solar concentrator module according to claim 1, characterized in that the receiver is made in the form of a photoconverter and is equipped with a heat removal circuit with a liquid coolant. 5. The solar concentrator module according to claim 1, characterized in that the radiation receiver is made in the form of a heat absorber with a selective coating on the working surface on which the radiation is incident, and is equipped with an air-cooled heat removal circuit. 6. The solar concentrator module according to claim 1, characterized in that the radiation receiver is made in the form of a heat absorber with a selective coating, thermally insulated from an optically transparent element and a mirror reflector and connected to a heat dissipation circuit with a liquid coolant. 7. A solar concentrator module containing two identical optically transparent elements having a lateral reflective surface, an input face and an output face smaller and a receiver with a two-sided working surface mounted on the output faces of the optical elements directed in opposite directions, characterized in that they are optically transparent the elements are made of a cured polysiloxane gel located in the cavity between two entrance faces formed by two transparent transparent fencing holes, side reflective surfaces made of sheet mirror reflector, and each side of the receiver. 8. The solar concentrator module according to claim 7, characterized in that the radiation receiver is made in the form of a two-sided photoconverter connected by a heat-conducting material with two sheet mirror reflectors on the outside of the side reflective surfaces. 9. The solar concentrator module according to claim 7, characterized in that the receiver is made in the form of a two-sided photoconverter and is equipped with a heat removal circuit with an air cooling system. 10. The solar concentrator module according to claim 7, characterized in that the receiver is made in the form of a two-sided photoconverter and is equipped with a heat removal circuit with a liquid coolant. 11. The solar concentrator module according to claim 7, characterized in that the radiation receiver is made in the form of a two-sided thermal absorber with a selective surface on two working surfaces on which radiation is incident, and is equipped with an air-cooled heat removal circuit. 12. The solar concentrator module according to claim 7, characterized in that the thermal absorber with a two-sided working surface is equipped with a water-cooled heat removal circuit. 13. A method of manufacturing a solar concentrator module by forming an optical element with different input and output surfaces and applying reflective surfaces to the side faces of the optical element, characterized in that a closed cavity is formed with side surfaces from a sheet mirror reflector, a radiation receiver on the exit surface and a transparent protective with a fence at the entrance surface, a vacuum mixture of polysiloxane gel components is poured into the cavity and structuring is carried out polysiloxane gel in the cavity in the temperature range and duration of the process from a temperature of 20 ° C for 24 hours to a temperature of 150 ° C for 3 minutes when exposed to vibration. 14. A method of manufacturing a solar concentrator module according to item 13, wherein the receiver is made in the form of a photoconverter and connected with a heat-conducting material with a sheet mirror reflector on the outside of the side faces of the optical transparent element. 15. A method of manufacturing a solar concentrator module according to item 13, wherein the receiver is made in the form of a photoconverter and a heat removal circuit with an air cooling system is connected to the photoconverter. 16. A method of manufacturing a solar concentrator module according to item 13, wherein the receiver is made in the form of a photoconverter and a heat removal circuit with a heat transfer fluid is connected to the photoconverter. 17. A method of manufacturing a solar concentrator module by forming two optical transparent elements with different input and output surfaces, applying reflective surfaces to the side faces of each optical element, placing a two-sided photoconverter on the exit surface of a smaller section of one of the transparent optical elements and connecting two optical elements on a plane output face of a smaller cross-section, characterized in that two closed cavities are formed with different-sized surfaces entry and exit holes, connect these cavities on the exit surface of a smaller section with side surfaces from a sheet mirror reflector, install two closed cavities with the surface of one of the inputs of a larger section on a transparent protective fence in a horizontal plane, seal the contact surface of the cavity and the protective transparent fence, fill in the mixture of components polysiloxane gel in one of two closed cavities located on a protective transparent coating, set the receiver on the joint exit surfaces of a smaller cross section of two cavities, pour the liquid mixture into a second closed cavity, install a second protective transparent fence on the exit surface of the second cavity, polysiloxane gel is structured in both closed cavities in the temperature range and the duration of the process from a temperature of 20 ° C for 24 hours to temperature 150 ° C for 3 minutes when exposed to vibration. 18. A method of manufacturing a solar concentrator module according to 17, characterized in that the receiver is made in the form of a two-sided photoconverter and the receiver is connected with a heat-conducting material with a sheet mirror reflector. 19. A method of manufacturing a solar concentrator module according to claim 17, wherein the receiver is made in the form of a two-sided photoconverter and a heat removal circuit with an air cooling system is connected to the two-sided converter. 20. A method of manufacturing a solar concentrator module according to claim 17, characterized in that the receiver is made in the form of a two-sided photoconverter and a heat removal circuit with a liquid coolant is connected to the two-sided photoconverter. 21. A method of manufacturing a solar concentrator module according to 17, characterized in that the receiver is made in the form of a heat absorber with a two-sided working surface with internal air channels and connect the heat absorber to the air-cooled heat removal circuit. 22. A method of manufacturing a solar concentrator module according to claim 17, characterized in that the receiver is made in the form of a heat absorber with a double-sided working surface with internal channels for pumping a liquid coolant and a heat absorber is connected to an air-cooled heat removal circuit. 23. A method of manufacturing a solar concentrator module by forming two transparent optical elements with different input and output surfaces, applying reflective surfaces to the side faces of each optical element, placing a two-sided photoconverter on the exit surface of a smaller section of one of the transparent optical elements and connecting two optical elements in a plane output face of a smaller cross section, characterized in that the side surfaces of two symmetrical isolators are formed of cavities with equal input and output surfaces from the sheet mirror reflector, fix on the transparent substrate two-sided radiation detectors at a distance from each other equal to Dd, where D and d are the dimensions of the input and output faces, lateral sheet mirror reflectors are fixed on the transparent substrate by the exit surface of a smaller cross section along the boundary of the radiation receivers, optical transparent elements are formed by pouring a mixture of polysiloxane gel components into each of the formed cavities; an obscure protective fence at the entrance surface of optically transparent elements, polysiloxane gel is structured in the temperature range and process duration from a temperature of 20 ° C for 24 hours to a temperature of 150 ° C for 3 minutes when exposed to vibration, then optically transparent elements are formed on the other hand transparent substrate by fixing sheet mirror reflectors with an exit surface of a smaller cross section along the boundary of the radiation receivers, pouring a mixture of siloxane gel components into each and h formed cavities, installing a transparent protective fence on the entrance surface, structuring the polysiloxane gel in the temperature range and the duration of the process from a temperature of 20 ° C for 24 hours to a temperature of 150 ° C for 3 minutes when exposed to vibration. 24. A method of manufacturing a solar concentrator module according to claim 23, characterized in that the receiver is made in the form of a two-sided photoconverter and the receiver is connected with a heat-conducting material with a sheet mirror reflector. 25. A method of manufacturing a solar concentrator module according to claim 23, wherein the receiver is made in the form of a two-sided photoconverter and a heat removal circuit with an air cooling system is connected to the two-sided converter. 26. A method of manufacturing a solar concentrator module according to claim 23, wherein the receiver is made in the form of a two-sided photoconverter and a heat removal circuit with a heat transfer fluid is connected to the two-sided photoconverter. 27. A method of manufacturing a solar concentrator module according to item 23, wherein the receiver is made in the form of a thermal absorber with a two-sided working surface with internal air channels and connect the thermal absorber to the air-cooled heat removal circuit. 28. A method of manufacturing a solar concentrator module according to item 23, wherein the receiver is made in the form of a heat absorber with a two-sided working surface with internal channels for pumping a liquid coolant and connect the heat absorber to the air-cooled heat removal circuit.

Images