DE29911116U1 - Solar energy station - Google Patents

Description

LEMO-SOLAR Lehnert Modellbau Solartechnik GmbH Am Taubenloch 35
74906 Bad Rappenau

Solar energy station

The invention relates to a solar energy station for supplying batteries and/or small devices with electrical power, consisting of a solar module and a device connection connected by means of wiring.

Known solar energy stations of this type consist of the solar module, wiring and device connection designed as individual elements. These individual elements are coupled together as required to form an energy station for supplying power consumers, whereby they are only loosely connected to one another over a large area. The disadvantage here is that such a combination is not mobile, i.e. cannot be moved to another location in a simple manner, e.g. without dismantling and reassembling each time. The transport itself is also difficult, since the individual elements are essentially loose and therefore have to be placed together in a separate transport container. On the other hand, there are a large number of electrical devices that have batteries as energy sources. The latter have to be charged from time to time, but this can only be done at the location of the energy station, which in turn is not available at the location needed. The batteries can also only be charged after they have been removed from the associated device and connected

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to the energy station at their location. This limits the use of these devices, as they are always likely to fail because the battery(s) no longer supply enough power and charged batteries are not available.

The object of the invention is therefore to create an energy station that can be used at any time and regardless of the location.

This object is achieved by the invention in that the solar module, the wiring and the device connection are combined into a single unit and designed as a handheld device.

The advantages achieved with the invention are in particular that the combination of the individual elements results in a compact energy station which is not only easy to handle in the form of a handheld device, but also easy to transport, meaning it can be taken anywhere. Since the handheld device is always in a functional state and can be transported in this state, its function is also ensured during transport, so that power is always available to charge batteries and/or to operate, for example, a Walkman, pocket radio or recorder. These devices can therefore be operated continuously, and replacement batteries can be charged at the same time. Another significant advantage of the invention is that batteries no longer need to be used, which are unusable after they have been drained and may be disposed of in an uncontrolled manner. Batteries also have a long service life, which currently amounts to up to 10,000 operating hours. Furthermore, the energy station according to the invention can be used either in direct operation, i.e. exclusively to supply a current collector, or as a

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Solar buffer, i.e. both for operating a device and for charging batteries, or also for charging batteries alone, i.e. as a solar charging station. The solar energy station according to the invention is therefore versatile in its application and, due to its structure and external design as a handheld device, can be easily handled, transported and used anywhere, both stationary and mobile.

Further useful embodiments of the invention are the subject of subclaims.

Embodiments of the invention are illustrated in the drawing and are explained in more detail below.

Show it:

Fig. 1 is a view of the solar energy station; Fig. 2 is a longitudinal section through the solar energy station; Fig. 3 is another embodiment of the solar energy station.

A solar energy station is used to supply power consumers such as batteries and/or small devices such as radios, recorders, cell phones, etc. with electrical power. It has, as individual elements, a solar module 1 composed of solar cells, which is connected via wiring 2 to a device connection 3 in the form of at least one connection socket. According to the invention, these individual elements 1 to 3 are combined to form a unit in the form of a hand-held device 4, as can be seen in Figs. 1 and 2. To store the individual elements 1 to 3 and to make them easy to handle, a housing 5 is provided, on one broad side of which the solar module 1 facing outwards is attached. The wiring 2 is housed in the housing 5, while the device connection 3 consisting of one or more connection sockets is arranged on one or more narrow sides of the housing 5. The housing 5 has any shape that is convenient for the hand and operation.

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A charging station 6 is provided in the housing 5, into which one or more batteries 7 can be inserted, whereby they are automatically inserted into the circuit of the wiring 2, as can be seen in Fig. 2. A discharge protection diode 8 is connected upstream of the batteries 7 to prevent the batteries 7 from discharging. Charging electronics 9 can also be provided to prevent the batteries 7 from being overcharged without overcharge protection. A flap 10 is arranged in the housing base 5' for installing and removing the batteries 7. In order to obtain a certain storage possibility, a gold capacitor can also be connected in the wiring 2.

The majority of small devices are designed for 3-volt voltage, such as Walkmans, disc players, radios, recorders, cell phones, pocket calculators, etc. The handheld device 4 is therefore designed in its main form for this voltage and, in addition to the corresponding size of the solar module 1, also has a charging station 6 for holding two AA batteries 7. In addition to the design of the housing 5 to be easy to hold and operate, fastening elements are provided for optionally attaching it to people, objects or for setting it up. For example, a plug-in holder 11 can be provided on the broad side of the housing 5 opposite the solar module 1 in order to be able to put the handheld device 4 in a pocket or belt, with the solar module 1 facing the light side. The energy supply for charging the batteries 7 and/or for operating a power consumer, such as a radio, is thus also ensured during transport. For intensive light irradiation on the solar module 1 when stationary, a foldable and adjustable setting device 12 can be provided, possibly in addition to the plug-in holder 11, in order to be able to set up the hand-held device according to the incidence of light (Fig. 3). Likewise, a clamping device or the like can be provided as a fastening element in order to fix the hand-held device 4 in the

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Vehicle, bicycle, disc box or similar. In this way, these devices form a closed unit that can also be transported as such. The current collector, e.g. a light that can be used as a front or rear light on the bicycle, can also be attached to this fastening element or in addition to it. A loop for attaching the hand-held device 4 to the arm or to a post is also possible.

It is clear that by combining the previous individual elements 1 to 3 into a compact handheld device 4, a widespread and practical use has been created, which is available in numerous ways both in the mobile sector and in stationary use, e.g. in connection with construction or experiment kits. All 3-volt devices can be operated with the handheld device 4 according to the invention, which makes it particularly suitable for leisure use. In a further application, the handheld device 4 can also be designed as a kit, which can be purchased as such and used for teaching purposes in schools or by hobbyists, especially young people.

Claims (13)

1. Solar energy station for supplying batteries and/or small devices with electrical power, consisting of a solar module and a device connection connected by means of wiring, characterized in that the solar module ( 1 ), the wiring ( 2 ) and the device connection ( 3 ) are combined to form a unit and are designed as a handheld device ( 4 ). 2. Solar energy station according to claim 1, characterized in that a charging station ( 6 ) for batteries ( 7 ) is arranged in the hand-held device ( 4 ). 3. Solar energy station according to claims 1 and 2, characterized in that the hand-held device ( 4 ) has a housing ( 5 ), on one broad side of which the solar module ( 1 ) is arranged on the outside and on at least one narrow side at least one connection socket is arranged as a device connection ( 3 ). 4. Solar energy station according to claims 1 to 3, characterized in that the solar module ( 1 ) and the charging station ( 6 ) are designed to supply 3-volt power consumers. 5. Solar energy station according to claims 1 to 3, characterized in that a plug-in holder ( 11 ) and/or an adjusting device ( 12 ) is arranged on the housing ( 5 ) opposite to the solar module ( 1 ). 6. Solar energy station according to claims 1 to 3, characterized in that a fastening device for attachment to persons and/or objects is attached or can be attached to the housing ( 5 ). 7. Solar energy station according to claim 6, characterized in that the fastening device is designed as a clamping device. 8. Solar energy station according to claim 6, characterized in that the fastening device is designed as a loop. 9. Solar energy station according to claims 1 to 3, characterized in that a holding device for attaching a power consumer to the housing ( 5 ) is provided. 10. Solar energy station according to claims 1 to 3, characterized in that charging electronics ( 9 ) are provided in the wiring ( 2 ). 11. Solar energy station according to claims 1 and 2, characterized in that the charging station ( 6 ) is designed for two AA batteries ( 7 ). 12. Solar energy station according to claims 1 and 2, characterized in that a gold capacitor is provided in the wiring ( 2 ). 13. Solar energy station according to at least one of claims 1 to 12, characterized in that the hand-held device ( 4 ) is designed as an assembleable kit.