DE2749992A1 - Photoelectric solar cell - with photoconverter cooled by arrangement inside hollow coolant filled radiation concentrator (CS 30.11.78) - Google Patents

Abstract

A photoelectric solar cell consists of a photoconverter, a solar radiation concentrator and a reflector. The photoconverter is kept cool by being arranged inside a concentrator which is designed as a hermetically sealed cavity, filled with a transparent heat transfer medium. This enables the photoconverter to be operated continuously at a high solar ray concentration rate. Such a cell contains no revolving parts and requires no maintenance. Typically the photoconverter has a working surface which receives the solar radiation. It is housed inside a hermetically sealed vessel which is filled with a transparent heat transfer medium; this vessel combines the functions of a concentrator (as a collecting lens) and of a coolant for the photoconverter; a mirror reflector is arranged at half the local length L from the photoconverter.

Description

Photoelectric solar cell

The invention relates to a device for converting the energy the solar radiation into electrical energy and in particular a photoelectric Solar cell.

From US-PS 3,383,246 is known a photoelectric solar cell, that from a photo converter, a concentrator for solar radiation energy, the is arranged in the way of the light that hits the sensitive work surface of the photo transducer falls, and consists of a means for cooling the photoconductor. In the well-known Facility is used as a means to cool down Turntable provided, which is coupled to an electric motor by means of a shaft. The photo converter is placed on the turntable and becomes periodic as it rotates along with it out of the radiation zone, whereby a cooling of the photo converter causes will.

But that means that the photo converter in the known device works in pulse mode with pauses for cooling. An electric motor in the cooling system also causes an additional expenditure of electrical energy and reduces the reliability of the cooling system, what with the presence of rotating Associated assemblies that require an interrupted lubrication and maintenance with replacement of worn parts.

The invention is based on the object of a photoelectric solar cell by providing them with such a means for cooling the phototransducer to perfect, which enables the photoconverter to operate continuously use, requires no energy expenditure and no maintenance and is through a high operational reliability.

The task at hand is a photoelectric solar cell, consisting of a photo converter, a concentrator for solar radiation energy, which is arranged in the path of the radiation that hits at least one work surface of the photo converter is incident, and from a means for cooling the photo converter, solved according to the invention in that a concentrator is provided as the means for cooling is, which is designed in the form of a hermetically sealed hollow vessel that is filled with a transparent heat transfer medium, within which the photo converter is arranged.

Advantageous refinements and developments of the invention are characterized in subclaims in detail.

The photoelectric solar cell according to the present invention ensures effective cooling and reliable protection of the photo converter from the effects of the environment as well as a high concentration of radiant energy.

The photoelectric solar cell designed according to the invention is characterized is also characterized by a high degree of efficiency, because the photo converter in it is continuous is operated, the cooling takes place through the heat transfer medium that the hermetically sealed vessel fills, so that no additional energy expenditure is required for cooling. Such a cell has a high level of operational reliability, as it does not contain any rotating assemblies, requires no maintenance and is constructive is easy.

The invention is further illustrated by means of exemplary embodiments the drawing explained in more detail; show it; 1 shows a photoelectric solar cell with a concentrator in the form of a converging lens in a longitudinal section; Fig. 2 a Photoelectric solar cell with a photo transducer in the lower part of the lens is arranged in a longitudinal section; 3 shows a photoelectric solar cell with an additional lens in a longitudinal section; Fig. 4 is a photoelectric Solar cell with a mirror reflector made of two parts, namely a central plane Part and a peripheral curvilinear part, in a longitudinal section; Fig. 5 is a photoelectric Solar cell with a mirror reflector made of two parts, namely a central curvilinear one Part and a peripheral planar part, in a longitudinal section; Fig. 6 is a photoelectric Solar cell with a mirror reflector, which is connected to a wall of the hollow vessel and is assembled with an additional reflector, in a longitudinal section; Fig. 7 a photoelectric solar cell with a mirror reflector, which has a wall of the hollow vessel is assembled and has a focal length that does not exceed the vessel extends out, in a longitudinal section; 8 shows a photoelectric solar cell with two photo converters in a longitudinal section.

In the example of a photoelectric solar cell shown in FIG. 1 is a photo converter 1 with a work surface 2, which receives radiation 3, in one hermetically sealed vessel 4 housed with a transparent heat transfer medium 5 is completed. The vessel 4 also serves as a concentrator for solar radiation and as a means of cooling the photoconductor 1. In this example, the vessel represents 4 is a transparent converging lens, hereinafter referred to as lens 4 for short, which with one Mirror reflector 6 is provided. As a reflector 6 plan, Convex and concave mirrors are used, for example made of glass with a Mirror layer made of aluminum or silver metal are carried out.

In this example, the mirror reflector 6 is designed and flat arranged at a distance L from the working surface 2 of the photo converter 1, which is approximately half of the focal length Of the lens 4.

The photo converter 1 is provided with power supply lines 7, the outside the lens 4 are attached without violating their tightness, and for the Connection of the photo converter 1 to a load resistor 8 are suitable. In the drawing the course of rays is shown with arrows, which on the working surface 2 of the Photo converter 1 fall.

In the example of a photoelectric solar cell shown in FIG. 2 In contrast to the previous example, the photo transducer 1 is shown in FIG the sun is arranged lower part of the lens 4, and a mirror reflector 6 is inclined set up to the optical axis of the lens 4.

Another embodiment for a photoelectric solar cell is shown in FIG. In this variant, a photo converter 1 'has two work surfaces 2 and 9 on. Opposite the second working surface 9 of the photo converter 1 'is a additional converging lens 10 set up, the area of which is approximately half the area of the first lens 4.

The additional lens 10 is at a distance of 1 from the Working surface 9 of the photo converter 1 'is arranged away, which is approximately the focal length the lens 10 is the same.

In the embodiment shown in Fig. 4 for a photoelectric Solar cell is a double-sided irradiation of the photo converter 1 'in difference to the embodiment of Fig. 3 by two reflectors 11 and 12, accordingly Main and additional reflector, secured. The reflector 12 is designed to be curvilinear and arranged opposite the work surface 9 at a distance therefrom, which is the deflection the radiation 3 on the work surface 9 secures. The one opposite the work surface 2 arranged reflector 11 consists of two parts, a central flat part 13, the one for reflecting the radiation 3 onto the working surface 2 of the photo converter 1 'is suitable, and a peripheral curvilinear part 14 which is suitable for retroreflection the radiation 3 on the additional reflector 12 is suitable.

In Fig. 5 is an analogous to the previous embodiment Photoelectric solar cell shown, which is only due to the constructive Execution of the main reflector 11 'differs whose central part 13' is curvilinear and the peripheral part 14 'of which is flat.

In the example shown in FIG. 6, there is a wall of the hollow vessel 15 designed in the form of a mirror reflector 16 which focuses the radiation 3, and the opposite wall 17 is transparent.

The photo converter 1 is transparent with its work surface 2 Conversion 17 facing, compared to the additional reflector 12 'is arranged for deflecting the radiation focused by the reflector 16 3 on the work surface 2 of the photo converter 1 is suitable. The additional reflector 12 'is attached at a distance 1 from the working surface 2 of the photo converter 1, which makes up approximately half of the focal length Of of the mirror reflector 16.

In Fig. 7 is yet another embodiment of a photoelectric Solar cell shown, in which 151 a wall of the hollow vessel 151 in the form of a Mirror reflector 16 'is carried out, which has a focal length Of that does not extends beyond the vessel 15 ', and the opposite wall 17 is transparent carried out for the radiation 3 which falls on the reflector 16 '. The photo converter 1 'is set up in this case at the focal point of the reflector 16', and the radiation 3 falls on both work surfaces 2 and 9.

If the reflector has a large radius of curvature, it is useful to To use photo transducers with a work surface facing the reflector should (not shown in the drawing).

In Fig. 8, a photoelectric solar cell is shown, which in Difference to the previous embodiments, two hermetically sealed Has hollow vessels which represent identical transparent converging lenses 4 and 4 ', which are filled with the heat transfer medium 5. Lenses 4 and 4 'are at a distance L 'from one another which is approximately the focal length of the lenses 4 and 4 'is the same. The photo converter 1 is in the center of the lens 4 and in the center the lens 4 'is an additional photo converter 1 "is arranged, the photo converter 1 and 1 with their work surfaces 2 and 2 'facing each other. The lens 4 serves as a concentrator for the photo converter 1 ″, which is inserted into the lens 4 ' is built in, and the lens 4 'in turn serves as a concentrator for the photo converter 1 built into the lens 4. Opposite each of the lenses 4 and 4 'is below an angle (in this example the angle is equal to 450) to the axis of the lenses 4 and 4 'a mirror reflector 18 for a simultaneous deflection of the radiation 3 placed on the work surfaces 2 and 2 'of the two photo converters 1 and 1'.

The photoelectric solar cells shown operate in the following way Way: solar radiation 3 (Fig. 1) passes through the lens 4 and then becomes by means of the mirror reflector 6 and focused on the working surface 2 of the photo converter 1 transferred.

Electrical energy is generated by the photo converter 1 and via the Power supply lines 7 are fed to the load resistor 8.

Thermal energy is by means of the heat transfer medium 5 at a cost the convective thermal conductivity from the photo converter 1 to the walls of the lenses 4 derived.

When attaching the photo converter 1 (Fig. 2) in the lower part of the Lens 4 is a deterioration in heat dissipation from the photo transducer 1 to the Walls of the lens 4 flow due to the emergence of rising heat.

An improvement in the heat retention of the photoelectric solar cell is when using a photo converter 1 (Fig. 3) with two work surfaces 2 and 9 observed.

In this case, the radiation 3 is divided into approximately two equal parts divided, and the photoconductor 1 'is irradiated on both sides. This is going through causes the attachment of the additional converging lens 10 by way of the radiation 3. Part of the solar radiation 3 is focused by the lens 10 and hits the Work surface 9 of the photo converter 1 'a. The work surface 2 is from the other Part of the solar radiation 3 is irradiated that is not shielded by the lens 10 Part of the lens 4 passes and is focused by the mirror reflector 6.

An analogous effect is achieved in the exemplary embodiments, which are shown in Fig. 4 and 5, the two mirror reflectors 11 and 12 and 11 'and 12'. In these examples, the solar radiation 3 goes through the Lens 4 through, hits the reflector 11 (11 ') and arrives at the rear-view mirror at its central part 13 (13 ') on the working surface 2 of the photo converter 1'.

Part of the radiation 3, approximately half of it, is from the peripheral part 14 (14 ') of the reflector 11 (11') reflected back, arrives at the additional reflector 12 and is of the same on the work surface 9 of the Photo transducer 1 'transferred.

The embodiment of FIG. 5, in contrast to the embodiment 4 can be made more compact as a result of the reduction in the distance L.

The photoelectric solar cell with the mirror reflector 16 (Fig. 6), which is assembled with a wall of the hollow vessel 15, works in the following Way: Solar radiation 3 passes through the transparent wall 17, is focused by the mirror reflector 16 and arrives on the additional Reflector 12 ', after its reflection on the same, the radiation 3 is on the Working surface 2 of the photo converter 1 steered.

This embodiment is for equipping a photoelectric Solar cell with elements of a tracking device suitable for the sun because the vessel 15 has an opaque wall.

If the focal length Of (Fig. 7) of the reflector 16 'does not exceed the Reaches out hollow vessel 15, the solar radiation 3 is focused by the reflector 16 ' and reaches the work surfaces 2 and 9 of the photo converter 1 '.

The embodiment of Fig. 7 provides besides one convenient one Execution also has a large utilization factor for solar radiation 3 because the Radiation 3 falls completely on the reflector 16 '(one part of the Additional reflector shielding radiation).

The photoelectric solar cell with two photo converters 1 and 1 "(Fig. 8) works in the following way: The solar radiation 3 is from the mirror reflectors 18 reflected back and focused through lenses 4 and 4 '.

The solar radiation 3 focused by the lens 4 reaches the Working surfaces 2 'of the photo converter 1 ", which is built into the lens 4', and the solar radiation 3 focused by the lens 4 'reaches the work surface 2 of the photo transducer 1 built inside the lens 4.

The embodiment of Fig. 8 is particularly good for protection suitable for the sun tracking control, for this one only needs the reflectors 18 accordingly to rotate the movement of the sun.

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Claims (9)

Patent claims solar cell, consisting of a #Photoelectric Photo converter, a concentrator for solar radiation energy, which by way of radiation is arranged, which is incident on at least one working surface of the photo converter, and means for cooling the photoconductor, characterized in that a concentrator is provided as a means for cooling, which is in the form of a hermetically closed hollow vessel (4) is carried out with a transparent heat transfer medium (5) is filled, within which the photo converter (1) is arranged. 2. Photoelectric solar cell according to claim 1, characterized in that that the hollow vessel is a transparent converging lens (4) with a mirror reflector (6) is provided, which is set up opposite the work surface (2) of the photo converter (1) is. 3. Photoelectric solar cell according to claim 2, characterized in that that the mirror reflector (6) is extended and at a distance (L) from the work surface (2) of the photo converter (1) is arranged, which is approximately half the focal length (Of) the lens (4). 4. Photoelectric solar cell according to claim 2, characterized in that that the photo transducer (1) is arranged in the lower part of the lens (4) with respect to the sun and the mirror reflector (6 ') for the purpose of reflecting the solar radiation back onto the Work surface (2) of the photo converter (1) at an angle (#) to the optical axis of the lens (4) is set up. 5. Photoelectric solar cell according to claim 3 with a photo transducer with two work surfaces, characterized in that opposite the second work surface (9) of the photo converter (1 ') an additional converging lens (10) at a distance (1) of this work surface (9) is set up, which is approximately the focal length of the additional Lens (10) is the same, the area of which is approximately half the area of the first lens (4) matters. 6. Photoelectric solar cell according to claim 2 with a photo transducer with two work surfaces, characterized in that they are provided with an additional Mirror reflector (12) is provided opposite the second work surface (9) of the photo transducer (1 ') is set up at a distance from this, the rear reflection the radiation through the additional reflector (12) onto the second work surface (9) of the photo converter (1 ') secures, and the first mirror reflector (11) with a central part (13 and 13 ') for a reflection of the radiation back onto the first Working surface (2) of the photo converter (1 ') and a peripheral part (14 and 14') designed to reflect the radiation back onto the additional reflector (12) is. 7. Photoelectric solar cell according to claim 1, characterized in that that a wall of the hollow vessel (15) in the form of a focusing mirror reflector (16) and the opposite wall (17) is made transparent and the photo converter (1) with its work surface (2) the transparent wall (17) is facing, which is arranged opposite an additional reflector (12 '), the the radiation (3) is focused on the work surface (2) of the photo converter (1). 8. Photoelectric solar cell according to claim 1, characterized in that that one wall of the hollow vessel (15 ') is designed in the form of a mirror reflector (16') which has a focal length (Of) which does not extend beyond the vessel (15 '), the opposite wall (17) is made transparent, and the photo converter (1 ') is arranged in the focal point of the reflector (16'). 9. Photoelectric solar cell according to claim 1, characterized in that that it has an additional photo converter (1 "), which is the first photo converter (1) set up opposite and with its work surface (2 ') the work surface (2) of the first photo converter (1) is facing and analogous to this in a hermetic manner closed hollow vessel is housed, with both vessels identical transparent Collecting lenses (4 and 4 ') represent the lens (4) of the first photo converter (1) as Concentrator for the additional photo converter (1 ") is used and the lens (4 ') of the additional photo converter (1 ") as a concentrator for the first photo converter (1) serves, opposite each lens (4 and 4 ') at an angle to the optical axis the lens (4 and 4 ') a mirror reflector (18) for the simultaneous deflection of the Solar radiation on the work surfaces (2 and 2 ') of both photo converters (1 and 1') is set up.