DE20308393U1 - Solar power unit for pumps, illumination, lasers, radar etc has solar module loaded onto an element forming a bow or circular shape - Google Patents

Abstract

A solar power unit comprises a solar module (B) which is loaded onto a bow shaped or circular element (A). Preferably, the unit is movable to follow the sun and can be raised or lowered.

Description

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Description

The invention relates to a solar power plant.

In solar power plants, it is known to design them so that they can pivot around a central joint in order to always enable the best possible alignment with the sun, see e.g. patent specification DE 19928857 Cl or DE 101 44 601 A 1.

However, this is insufficient because the solar power plant is firmly connected to the ground by a foundation and because it rests on a mass. Setting up the solar power plant is very complicated because a foundation has to be poured. This construction is also inadequate because the power plant mentioned above is tied to a specific location.

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It is known from DE 4405650 C1 that concave mirrors can be used to concentrate solar rays. These can be used for photovoltaic and thermal purposes.

Concave mirrors have the disadvantage that they are very expensive to produce.

The invention aims to eliminate the disadvantages of the prior art and thus increase the efficiency of solar power plants.

The problem is solved by a solar power plant,

• where the modules rest on bent elements that form an arc or circle.

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This is based on the knowledge that the sun moves from the east through the south to the west over the course of the day. Since the solar modules produce their maximum power when the sun hits them as directly as possible, a tracking system increases the energy yield over the day. The sun is also lower in the sky in winter than in summer, which makes seasonal tracking worth considering. For these two reasons, there are single- and dual-axis tracking PV systems. The energy gain from dual-axis tracking can be up to 25% in our regions. The tracking, which is intended to optimize daily radiation, must be automated. Seasonal tracking can be done manually. If the tracking is too complex, however, the question arises as to whether the additional yield achieved thereby could not also be achieved with additional solar modules.

With conventional construction, the modules are firmly attached to the ground. They no longer move. The potential of the modules cannot be fully exploited. Valuable solar energy is lost. The efficiency of conventional power plants decreases the further the sun is from the optimal angle.

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A further development of the invention consists in

• that the modules are connected to at least one stretchable element. When the element stretches or contracts, it causes

• that the solar module is raised or lowered. This ensures that the optimal, vertical angle of the sun's rays on the solar modules is always maintained.

They move. The potential of the modules can be fully exploited.

« That the stretchable elements are directly or indirectly connected to the curved elements. This makes it possible to combine the adaptation to the rise and fall of the sun on the horizon with the adaptation to the cardinal direction.

This is based on the knowledge that the sun rises and sets on the horizon. This means that the optimal, vertical angle of the sun's rays on the solar modules is constantly changing.

With conventional construction, the modules are firmly attached to the ground. They no longer move. The potential of the modules cannot be fully exploited.

It is advisable

• that the curved elements are connected with "feet" for folding, on

on which the device is located. This means that the horizontal plane on which the ( curved elements are located can always be adjusted to the ground

• that the "feet" are stretchable. This ensures that even strong inclinations can be compensated by the "feet". Even an inclination of 90%, i.e. a vertical wall, can be connected to the horizontal curved elements by the "feet"

This is based on the knowledge that the subsoil of the power plant is often sloping, e.g. a roof, a mountain slope, or even a wall

The scope of the invention also includes

« that the solar modules are connected to elements that are directly adjacent to the modules on one side. These elements are positioned at such an angle to the modules that the sun's rays are reflected onto the solar modules. This can increase the amount of sunlight on the solar modules. The efficiency of the solar modules increases: the larger the reflecting elements, the greater the efficiency.

• that the solar modules can be combined with a circuit under their surface. This ensures that the great heat generated when the sun's rays are centered can be used. It can be used to produce warm liquid or steam. The efficiency of the solar power plant can thus be increased again.

This is based on the realisation that the modules have a small surface area (...' and that modules are relatively expensive, while the mirror surfaces are manufactured cheaply

The second point, the combination with a circuit, is based on the realization that the great heat that is generated when the sun's rays are centered can be used.

It may also be useful

• that the power plant can be lowered in just a few minutes using the stretchable element so that the solar modules reach the horizontal level. In short, the power plant can be folded up. Furthermore, the lightweight construction makes it possible to ensure that the power plant can be transported away quickly, because no foundation is needed to hold the structure securely, from which the power plant would have to be separated.

• that the "feet" can contract until the curved elements reach the ground. This ensures that the wind has no surface to attack the power plant, especially on sloping ground. In short, the power plant "lies" on the slope or on the roof.

This is based on the realisation that power plants offer a large surface area for attack by storms (in arid areas especially sandstorms).

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The scope of the invention also includes

• that the solar power plant can be connected to a power storage device, e.g. a solar battery. This makes it possible to store the electricity produced and release it when needed, e.g. at night or when the sky is overcast

• that the solar power plant can be connected to a device consisting of

- a fuel cell device. This makes it possible to generate electricity with high efficiency by burning hydrogen and oxygen to form water. This is also possible when the sun is not shining. As a result, the solar power plant is able to produce electricity around the clock. The amount of combustion can be adjusted to the current electricity demand

- an electrolysis device. This enables oxygen and hydrogen (the substances to be burned) to be produced from water.

&zgr; " solar energy can be used to decompose water - H2O into 02 and H2.

- a water tank. This makes it possible to provide water for electrolysis when needed. It can be connected to the circuit under the solar modules to produce hot water or to cool the modules.

- an oxygen storage device. This makes it possible to provide oxygen for the fuel cell. For example, the curved elements according to 1.1 in the tubular design can be filled inside in addition to their mechanical function and thus serve as storage.

- a hydrogen storage tank. This makes it possible to provide hydrogen for the fuel cell. For example, the curved elements according to 1.1 in the tubular element design can be filled inside in addition to their mechanical function and thus serve as storage

- works according to a similar principle as above, whereby other substances are used instead of the O substances mentioned there.

This is based on the knowledge that the sun does not shine at night and when the sky is overcast. The solar modules cannot produce electricity, although electricity is still needed at night when the sky is overcast.

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Furthermore, the invention includes

&bull; that the solar modules can be connected to a roller blind or a similar covering mechanism. This makes it possible to keep dirt, especially sand, away from the module surface and prevent a drop in efficiency.

&bull; that the solar modules can be connected to a windshield wiper or a similar cleaning mechanism as shown in the drawing! This makes it possible to keep dirt, especially sand, away from the module surface and prevent a drop in efficiency.

This is based on the knowledge that the modules become dirty or covered in sand during a sandstorm.

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Possible applications and further developments of the invention

1. Solar power plant according to drawing combined with an irrigation pump.

2. Solar power plant combined with a lighting system according to drawing

3. Analysis device for: Water, soil and air samples Radiation and waves Solar power plant according to drawing

4. Motion detector solar power plant according to drawing

V 5. Camera, terahertz camera Solar power plant according to drawing

6. Water extraction from air humidity. Solar power plant according to drawing

7. A trap, a feeding sifter with camera, an insect trap with sexual attractants Solar power plant according to drawing

8. A radar device solar power plant according to drawing

9. A laser device solar power plant according to drawing

10. A light barrier solar power plant according to drawing

11. A solar power plant for treetops Solar power plant according to drawing

12. Scout set solar power plant according to drawing

13. Children's construction kit solar power plant according to drawing

14. a light barrier rifle automatic shooting system for hunting solar power plant according to drawing

15. Directional microphone solar power plant according to drawing

16. a bus stop solar power plant according to drawing

List of reference symbols for drawing 1

A: Element for extending the module surface or mirror B: Device for moving the solar modules on the curved element C: Curved element, possible with partitions for the curved element

cavities that can be used to store chemical substances. D: Device that can provide electricity in the dark, preferably a solar battery or fuel cell and which controls the electricity, the fluid circuit, the

Gas circuit, which controls and drives the solar tracking and the other mechanical and energy-technical processes, as well as storing hot water. E: Connecting element that in a possible design with a circular arch connects the

stretchable element with the curved element and supplies device D. F: Mirror that reflects the sunlight onto the solar modules G: Solar modules that arbitrarily overlap the diameter of the curved elements H: Stretchable element that is connected at one end to the solar modules

and at the other end either directly or indirectly connected to the curved elements /- -, possibly hollow to supply G and D

^ T-L: Stretchable feet that adapt the solar power plant to a sloping surface

can, possibly hollow for the supply of C and D

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List of reference symbols for drawing 2

A: curved elements/circle (as drawing 1 C) B: solar modules (as drawing 1 G)

C: Stretchable element (as drawing 1 H )

D: Device (as drawing 1 D)

E: Connecting element with hinge (as drawing ) 1 G F: Wheels for moving the power plant forward as a vehicle G: Joint

H: Device for moving the aeolar modules on the curved element I: Electric motor

J: Laser

K: Radar or motion detector

L: Laser beam

Claims (15)

1. The invention relates to a solar power plant, characterized in that the solar modules rest on curved elements which form an arc or circle. 2. Solar power plant according to claim 1, characterized in that the solar modules are movable on the arc or circle in order to be able to follow the course of the sun. 3. Solar power plant according to claim 1, characterized in that the solar modules are connected to at least one stretchable element. 4. Solar power plant according to claim 1, characterized in that the solar module can be raised or lowered. 5. Solar power plant according to claim 1, characterized in that the stretchable elements are directly or indirectly bonded to the bent elements. 6. Solar power plant according to claim 1, characterized in that the curved elements are connected to feet for folding. 7. Solar power plant according to claim 1, characterized in that the feet are strockable. 8. Solar power plant according to claim 1, characterized in that the solar modules can be connected to elements. These elements are at such an angle to the solar modules that the sun's rays are reflected onto the solar modules. 9. Solar power plant according to claim 1, characterized in that the solar modules can be combined with a circuit beneath their surface. 10. Solar power plant according to claim 1, characterized in that the solar power plant can be lowered by the stretchable element so far that the solar modules can be placed parallel to the ground. 11. Solar power plant according to claim 1, characterized in that the feet can be pulled together until the curved elements reach the ground. 12. Solar power plant according to claim 1, characterized in that the solar power plant can be connected to a power storage device, e.g. a solar battery. 13. Solar power plant according to claim 1, characterized in that the solar power plant can be connected to a device which consists of a fuel cell device, an electrolysis device, a water storage device, an oxygen storage device and a hydrogen storage device. 14. Solar power plant according to claim 1, characterized in that the solar modules can be connected to a roller blind or a covering mechanism. 15. Solar power plant according to claim 1, characterized in that the solar modules can be connected to a windshield wiper or a cleaning mechanism.