WO2004100274A1

WO2004100274A1 - Unit for focusing solar radiation onto a micro solar cell

Info

Publication number: WO2004100274A1
Application number: PCT/EP2004/004445
Authority: WO
Inventors: Gerhard Willeke
Original assignee: Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V.
Priority date: 2003-05-02
Filing date: 2004-04-28
Publication date: 2004-11-18
Also published as: DE10320663A1

Abstract

Disclosed is a unit for focusing solar radiation onto a micro solar cell (4). An optical device (3) and a micro solar cell (4) are disposed inside said unit. Incident sunlight can be focused onto the micro solar cell by means of the optical device (3). The optical device (3) is movable independent of the micro solar cell (4) and/or the unit is movable independent of a housing (2) which surrounds the unit in order to track the position of the sun. The housing (2) that surrounds the units can be integrated into a building shell.

Description

Patent application: unit for concentrating solar radiation on a microsolar cell

Applicant: Fraunhofer Society for the Promotion of Applied Research e.V.

The invention relates to a unit for concentrating solar radiation on a microsolar cell. Microsolar cells are solar cells that usually do not exceed a size of a few hundred square millimeters and are able to absorb concentrated solar radiation.

In the field of using solar energy, it is known to concentrate solar radiation before converting it into electrical energy or heat. While in solar thermal applications the concentration is aimed at higher efficiencies through higher temperatures, the concentration in photovoltaic applications primarily serves to save high-quality area of semiconductor material.

One approach that is chosen primarily in the field of photovoltaics is the concentration of solar radiation on microsolar cells, which convert the incident sunlight directly into electricity. Units are used which are made up of an optical device and a microsolar cell. The optical devices are usually lenses with a diameter of up to 20 cm. A microsolar cell is arranged in the focal point of the lens. In the prior art, a large number of units are combined and installed in a weatherproof housing (module) in such a way that the optical device and the microsolar cell cannot be moved relative to one another. The modules can be made in dimensions limited by a few meters by truck transport. Because of the movement of the sun, it is necessary to adjust the entire module to the position of the sun so that the incident solar radiation is focused on the microsolar cells located in the focus. As a rule, several modules are mechanically moved or tracked at the same time. Both the east / west movement of the sun and the different heights of the sun must be taken into account.

Because of the high technological complexity associated with the tracking, solar power plants that require tracking are hardly widespread The object of the present invention is therefore to create a device with which a less complex tracking to the constantly changing position of the sun is possible. This task is solved by the independent claim. Advantageous refinements can be found in the dependent claims.

According to the invention, it was recognized that, in order to achieve certain possible uses, it is necessary to move the entire housing with its heavy weight to track the position of the sun. This is realized in that units for concentrating the solar radiation are created with an optical device and a microsolar cell, in which the incident sunlight can be focused on the microsolar cell with the optical device, the optical device being independent of that for tracking the position of the sun. Micro solar cell and the surrounding housing can be moved. Although it usually makes sense to move the optical device, the microsolar cell could also be moved. Advantageously, both the microsolar cell and the optical device are selected so that they have a very low weight in the range of a few grams. Very simple tracking devices can thus be selected. It is also possible to move an entire unit independently of the surrounding housing. Whole units in the above configuration also have a low weight, so that simple tracking devices are also possible for entire units.

With the module size of a few ten square meters known in the prior art, with a simultaneous tracking of, for example, 5 modules, a collector field of approximately 200 m ^{2 is obtained} . Due to the required static and dynamic stability (wind forces) and at the same time high precision of the tracking, such a system has to be made quite massive, which leads to masses in the range of 10 tons and a correspondingly safe elevation. Known systems of this type are not used because of the high outlay in spite of the strong growth in photovoltaic power generation. It was only with the tracking device according to the invention that an inexpensive implementation option for the use of tracking systems for photovoltaic power generation was created. It is advantageous that the tracking devices are arranged within the weatherproof housing, so that the tracking devices are hardly subject to weather influences. Only temperature fluctuations caused by solar radiation have to be taken into account. Such housings can be used in a simple manner as part of a facade cladding or as a building material. The solar module according to the invention can thus be integrated in a building envelope. This means that large, previously unused areas are available for energy generation.

Furthermore, the tracking devices should be long-lasting, since tracking must take place at least during the usable hours on every sunny day during the life of the units. A number of inexpensive technologies are available for the tracking, especially since micro-solar cells will become mass-produced items.

It makes sense to arrange several units in one housing and thus combine them to form a micro-concentrator module, since this enables less complex production. A transparent design of the housing enables the micro-concentrator module to be integrated into a building envelope, with the housing taking on the functions of weather protection, heat and sound insulation. In addition, partial shading of light (especially) is achieved in summer, since the concentrating units absorb the (intensive) direct light and allow the (weak) diffuse light to pass through largely unhindered.

The tracking movement can be controlled using astronomical data. The necessary tracking movement can be calculated and carried out from the time and date together with the geographical location and the orientation of the microconcentrator module. Alternatively, the current position of the sun can be measured and, depending on this, the necessary tracking movement can be determined and regulated accordingly. It is possible to determine the current position of the sun in the micro concentrator module. In this way, the orientation of the module is taken into account when measuring the position of the sun. Such regulation of the tracking allows the modules to be used regardless of location. In addition, the angle of attack and the alignment of the modules can be varied. Fresnel lenses are particularly suitable for focusing the solar radiation due to their low-mass and inexpensive production, for example from embossed, millimeter-thin plastic layers.

The requirements for the accuracy of the tracking can be reduced by attaching an additional converging lens to the microsolar cell. The light concentrated in the optical device is concentrated again in a converging lens.

Since the same tracking movement is required for all optical devices within a housing, the movement of the optical device of one unit can be coupled with the movement of the optical device of at least one neighboring unit.

If the entire unit is to be moved for tracking purposes, the same movement is also required for neighboring units within a housing. Therefore the movements of several units can be coupled. The number of drive devices can be reduced by coupling the movement of several optical devices or units. Since drive devices are more complex to produce than devices for coupling the movement of adjacent optical devices or units, the equipment effort can be reduced by coupling the movements. The effort stems, among other things, from the fact that each drive device must be supplied with energy and controlled with signals.

The coupling of the movement of several optical devices and / or units can be realized with a linkage. This can be done by connecting each optical device and / or unit with a rod, which ensures the tracking of the east / west movement of the sun, and compensates for the different heights of the sun. The rod must be connected to the optical devices and / or the units with suitable joints. It is possible to fasten each optical device and / or optical unit movably on a rod and movably at a fixed point. The tracking can be achieved by moving the rod. Alternatively, it is also conceivable to provide different rods for tracking the east / west movement and the different height of the sun. Of course, this requires the use of suitable joints for connecting the rods to the optical devices and / or units. An arrangement of the optical devices which saves material and production effort can be achieved by the drive linkage also serving as a suspension. If, for example, each optical device is movably attached both to a rod for tracking the east-west movement of the sun and to a rod to compensate for different heights of the sun, a further attachment of the optical devices is no longer necessary.

A tracking that allows an optimal concentration of the incident solar radiation on the microsolar cells is best achieved by the fact that the optical axis of the optical device comes to lie approximately on the connecting line between the microsolar cell and the sun. The necessary accuracy of the tracking increases with increasing concentration of sunlight. In order to reduce the tracking accuracy in highly concentrating systems (a hundred to a thousand times the concentration), a suitable second optical unit that is fixedly connected to the microsolar cell can be used, which at the same time hermetically shields the microsolar cell against possible environmental influences. A stepper motor can be provided to drive the tracking. Stepper motors allow precise control of the movement. It is possible to use stepper motors to move the linkage described above.

Worm gears can be used to transmit the forces and convert the movements during tracking.

The invention is described in more detail with reference to the following figures:

1 shows a unit for concentrating solar radiation arranged in a stationary housing.

Fig. 2 shows a unit arranged in a stationary housing for concentrating solar radiation with two lenses.

The radiation coming from the sun 1 strikes the optical device 3. This concentrates the solar radiation on the microsolar cell 4, in which the solar radiation is converted photovoltaically into electrical energy. Since the efficiency of the microsolar cell 4 decreases with increasing temperature, the microsolar cell 4 is surrounded by a heat sink 5, which dissipates the waste heat. A micro-tracking device 6 is arranged below, which comprises the unit of microsolar cell 4 and optical device 3 moves. The movement of the sun 1 can thus be compensated for without the housing 2 having to be moved.

2 shows a variant according to the invention in which the optical device 3, here a Fresnel lens 8, is moved independently of the microsolar cell 4 which is fixed in the housing 2 and which is provided with a converging lens 7 to increase the light concentration and to reduce the tracking accuracy , The tracking device for the Fresnel lens 8 is not shown here. The connecting lines between the Fresnel iris 8 and the microsolar cell 4 represent the marginal rays of the collected light.

LIST OF REFERENCE NUMBERS

T Sun 2: housing (stationary)

3 optical device 4 microsolar cell 5: heat sink 6 micro tracking device 7 converging lens 8 Fresnel lens

Claims

claims

1. Unit for concentrating solar radiation on a microsolar cell (4), an optical device (3) and a microsolar cell (4) being arranged in the unit, incident sunlight being able to be focused on the microsolar cell with the optical device (3), wherein for tracking the position of the sun, the optical device (3) can be moved independently of the microsolar cell (4) and / or the unit can be moved independently of a housing (2) surrounding the unit, characterized in that the housing (2) surrounding the units can be integrated into a building envelope.

2. Unit according to claim 1, characterized in that several units are arranged in a housing (2)

3. Unit according to claim 1 or 2, characterized in that. The optical device (3) is a Fresnel lens (8).

4. Unit according to one of the preceding claims, characterized in that a converging lens (7) is arranged on the microsolar cell (4).

5. Unit according to one of the preceding claims, characterized in that the movement of the optical device (3) of a unit is coupled with the movement of the optical device (3) of at least one adjacent unit.

6. Unit according to one of the preceding claims, characterized in that the movement of a unit is coupled with the movement of at least one adjacent unit.

7. Unit according to one of claims 5 or 6, characterized in that the movement of a plurality of optical devices (3) and / or units is coupled by means of a linkage.

8. Unit according to claim 7, characterized in that the linkage also serves as a suspension for the optical devices (3) and / or units

9. Unit according to one of the preceding claims, characterized in that the optical device (3) and the microsolar cell (4) are arranged such that by means of Tracking the optical axis of the optical device (3) comes to lie approximately on the connecting line between the microsolar cell and the sun (1).

10. Unit according to one of the preceding claims, characterized in that a stepping motor is provided for driving the tracking

1 1. Unit according to one of the preceding claims, characterized in that a worm gear is available for tracking.