DE102017212585A1 - Device and method for operating a solar module - Google Patents

Abstract

The invention relates to a device and a method for operating a solar module (20) having a number of at least one solar cell (11) comprising a solar cell (11) with at least one first transparent layer (12) arranged on a front side of the solar cell transparent layer (12) comprises a plurality of superimposed removable films (13). The invention further relates to a computer program for carrying out the method and to a machine-readable storage element on which the computer program is stored.

Description

State of the art

The invention relates to a device and a method for operating a solar module, in particular a solar module for a telematics unit in rail traffic.

In order to determine the exact position of a rail vehicle usually a telematics unit is used, which is mounted on the rail vehicle. In addition to the position tracking speeds and approach times or departure times of the rail vehicles can be accurately determined by the telematics unit, which leads to increased transparency in rail transport. In conventional telematics units for rail vehicles, especially freight and passenger trains, a solar cell is used as an energy source for the telematics unit.

However, this configuration suffers from the disadvantage that, due to the enormous distances traveled by rail vehicles, the solar cell is exposed to a high degree of contamination that can not be eliminated by simply wiping it off. The contamination leads to a reduced efficiency of the solar cell and consequently to an insufficient power supply of the telematics unit. Inadequate energy supply through the dirty solar cell leads to an interrupting operation, but can also lead to a complete failure of the telematics unit, which adversely affects the position tracking, etc. of the rail vehicles. Conventionally, regular cleaning is performed by manually wiping the solar cell as it fouled to maintain the efficiency of the solar cell. However, this manual cleaning can not eliminate all dirt and is also very laborious and time consuming.

It is therefore an object of the present invention to provide a device and method for operating a solar module, in particular a solar module for a telematics unit in rail traffic.

Disclosure of the invention

The inventive device for operating a solar module with a number of at least one solar cell comprising a solar cell with at least one arranged on a front side of the solar cell transparent layer, wherein the transparent layer comprises a plurality of superimposed removable films, has the advantage that the cleaning of the solar cell can be done easily, quickly and thoroughly by removing a soiled foil.

In a particularly advantageous embodiment, the removable films of the transparent layer starting from the top film are successively removable. The uppermost film is understood to be the film which is farthest from an optoelectronic surface of the solar cell and forms the contact with the environment of the solar cell. This has the advantage that after removal of the uppermost film, an original efficiency of a polluted solar cell can be effectively and efficiently produced. In addition, the time and effort required to remove the contamination can be significantly reduced.

Advantageously, the removable films of the transparent layer are formed to protect the solar cell from contamination. This has the advantage that the solar cell itself is protected against contamination by the transparent layer.

Alternatively, the front side of the solar cell is formed by a second transparent layer. In this exemplary embodiment, the second transparent layer advantageously acts as protection of the solar cell against mechanical and chemical stresses. Mechanical loads on the solar cell are caused, inter alia, by the removal of the uppermost film, but also in the case of an unfavorable positioning of the solar cell in the direction of travel by the airstream. Chemical stress can arise, for example, from the adhesive or adhesive that can be used to hold the transparent films together. The resulting advantage of the second transparent layer is that the adhesive or adhesive of the films need not be specially matched to the solar cell, since any adhesive or adhesive can be used by the protective effect of the second transparent layer.

In a further development, the solar cell provides energy for at least one self-sufficient computing unit. A self-sufficient computing unit is a system that can be operated independently and independently of a power grid. An autonomous arithmetic unit may for example be part of a self-sufficient counting unit for counting, for example, passing cars, vehicles, ships or passing aircraft, but also part of a measuring unit used in vehicles, ships or aircraft, for measuring, for example, a covered distance, a speed or a time , be. It is also conceivable that the self-sufficient arithmetic unit in a documentation unit, for example, to document a route, a Speed history or a period of operation of a used unit which also relates energy via the solar cell is used.

Advantageously, the autonomous arithmetic unit is part of a rail telematics unit. Under a rail telematics unit is understood a system which collects data about a rail vehicle to which the telematics unit is mounted and forwards to a control center and can be operated independently and independently of a power grid.

The inventive method for operating a solar module, wherein the solar module comprises an array of at least one solar cell, wherein the at least one solar cell has at least a first transparent layer, the first transparent layer having a plurality of superposed removable films, wherein an efficiency of the solar cell is detected and the uppermost film of the transparent layer, which falls below a minimum efficiency of the solar cell by the efficiency of the solar cell is removed, has the advantage that in this way an efficient and effective cleaning of the solar cell is made possible.

Particularly advantageous is the detection of the efficiency of the solar cell by at least one reference measurement of the efficiency of the solar cell. This is advantageous because the contamination of the solar cell can be measured automatically during operation without any additional effort. If the solar cell is used, for example, for a telematics unit in rail traffic, a time and GPS localization can be determined by the telematics. The known time and location of the solar cell can preferably be used to trigger the reference measurements at night, when the solar cell passes through an illuminated with artificial light station. In a known type of artificial lighting, the efficiency can be determined via the measured output voltage or output power of the solar cell. Alternatively, the reference measurement of the efficiency can also be carried out during the day at a specific time with a known sun position and the associated theoretical and measured energy yield of the solar cell.

Advantageously, the removal of the uppermost film is performed by peeling off the uppermost film, whereby the process has a very low susceptibility to error when performing the cleaning with little care.

Advantageous is a computer program which is set up to carry out each step of the method of the exemplary embodiments.

Advantageously, the computer program is stored on a machine-readable storage element.

Embodiments of the present invention are illustrated in the accompanying drawings and explained in more detail in the following description. Showing:

list of figures

• 1A and 1B a schematic representation of a solar cell with a transparent layer with removable films and alternatively with a second transparent layer;
• 2A and 2 B a schematic representation of a solar module with removable films;
• 3 a schematic representation of a sequence of the erfingungsgemäßen method;
• 4 a rail vehicle with telematics unit, which comprises an embodiment of the device according to the invention.

1A shows a schematic representation of a solar cell ( 11 ) on the front side of a transparent layer ( 12 ) is arranged. The transparent layer ( 12 ) comprises a plurality of layers of superposed removable translucent films ( 13 ). The removable films are arranged to each other so that when contamination of the top sheet ( 10 ) can be removed easily and quickly chemically or mechanically. After removing the top dirty film, the underlying clean film will be revealed. This ensures that the pollution is eliminated and an initial state in which again enough light reaches the solar cell, is produced. The initial state of the solar cell ( 11 ) is characterized in that the solar cell ( 11 ) again has its original efficiency. The removable slides ( 13 ) are preferably self-adhesive, so that they can be removed in case of contamination by time-saving removal. It is particularly advantageous if the films are successively removable, starting from the uppermost film ( 10 ). A self-adhesive film is understood as meaning a film which has an adhesive layer on one side. Preferably, when the self-adhesive film is removed along the adhesive layer, the adhesive is also removed so that the underlying film has no adhesive residue from the overlying self-adhesive film. Alternatively, it is also conceivable that the films of the transparent layer ( 12 ) are joined together along one edge and the connection between the two uppermost films when removing or peeling off the uppermost film ( 10 ) is broken.

1B shows an alternative embodiment in which a further transparent layer ( 14 ) is used. This layer is between the solar cell ( 11 ) and the transparent layer ( 12 ) and serves to protect the solar cell against mechanical and chemical stress, for example, by removing the films, but also by environmental influences, in particular weathering or shocks arise.

In 2A is shown schematically how the solar module ( 20 ) for a telematics unit ( 41 ) is constructed in particular for rail traffic. In this embodiment, the solar module ( 20 ) from several electrically interconnected solar cells ( 11 ). Alternatively, the solar module ( 20 ) also from only one solar cell ( 11 ), but this is not shown in the figures. The solar cells ( 11 ) are each separated by a separate transparent layer ( 12 ). Depending on the design, in particular the optoelectronic surface of the solar cell ( 11 ), the transparent layer ( 12 ) completely covering or partially covering on the solar cell ( 11 ) appropriate.

As in 2 B Alternatively, the entire solar module ( 20 ) with only one transparent layer ( 12 ) be covered. This has the advantage that when contaminated, the entire solar module ( 20 ) with once the top sheet ( 10 ) is cleaned. However, with selective soiling with separate transparent layers ( 12 ) of the individual solar cells, the pollution can be more purposefully removed without unnecessarily removing the film in other still clean areas.

3 shows a schematic representation of the method for operating a solar module ( 11 ) with removable foils ( 13 ).

In step 31 the degree of contamination of the solar cell ( 11 ). This can be done, for example, by measuring the efficiency of the solar cell ( 11 ) or the solar module ( 20 ) be performed. This is possible because the efficiency is proportional to the degree of contamination. Preferably, the efficiency is determined by means of a reference measurement. A reference measurement may preferably be performed at night, for example when the solar cell for a telematics unit is mounted on a rail vehicle passing through a station illuminated with artificial light. In a known type of artificial lighting, the efficiency can be determined via the measured output voltage or output power of the solar cell. Alternatively, a reference measurement of the efficiency can be carried out during the day at a fixed time. The reference measurement is preferably triggered when the power supply through the solar cell over a longer period of time, for example 2 days, constantly below a level at which, for example, the telematics unit can just be operated.

After measuring the degree of soiling of the solar cell ( 11 ), is in step 32 the measured efficiency compared with a minimum efficiency, which guarantees, for example, if the solar cell for a telematics unit is mounted on a rail vehicle that the telematics unit is supplied with sufficient energy. If the measured efficiency is less than a minimum efficiency, step 33 carried out. In step 33 becomes the topmost film ( 10 ) of the transparent layer ( 12 ) away. Removing the topmost film ( 10 ) can be achieved, for example, by an automated removal of the uppermost film ( 10 ), or manual tearing of the top sheet ( 10 ) be performed. This ensures that a cleaning of the solar module ( 20 ) is performed by an original efficiency of the solar cell ( 11 ), so that the telematics unit ( 41 ) is again supplied with sufficient energy to a trouble-free operation of the telematics unit ( 41 ) to ensure.

When in step 32 It is decided that the measured efficiency after step 31 is greater than the minimum efficiency step becomes 34 executed. In step 34 no foil is removed. Optionally, it is conceivable that after completing the step 33 and / or step 34 the procedure can either be ended or step 31 can be initiated again. In addition, the method may be implemented so that after completion of the step 33 or 34 , the step 31 is not restarted until a certain time, for example 24 hours, has passed. This has the advantage that by larger time intervals between the individual implementations of the reference measurements of the efficiency of the solar cell ( 11 ) Energy can be saved. This makes it possible to achieve a more energy-efficient implementation of the method.

4 shows a schematic representation of a rail vehicle ( 44 ), in particular a freight wagon, with a telematics unit ( 41 ). The telematics unit ( 41 ) is on the rail vehicle ( 44 ) and electrically connected to a solar module ( 20 ) connected. The energy gained through the solar module ( 20 ) is used to generate a computing unit ( 42 ) of the telematics unit ( 41 ) to operate. Alternatively, the arithmetic unit ( 42 ) a memory element ( 43 ) on which a computer program for carrying out the method according to the invention is stored.

Claims (11)

Device for operating a solar module (20) with a number of at least one solar cell (11) comprising - solar cell (11) with at least one first transparent layer (12) arranged on a front side of the solar cell (11), characterized in that the first one transparent layer (12) comprises a plurality of superimposed removable films (13). Device after Claim 1 , characterized in that the removable films (13) of the first transparent layer (12) starting from the top sheet (10) are successively removable. Device according to one of the preceding claims, characterized in that the removable films (13) of the first transparent layer (12) are formed to protect the solar cell (11) from contamination. Device according to one of the preceding claims, characterized in that the front side of the solar cell (11) by a second transparent layer (14) is formed. Device according to one of the preceding claims, characterized in that the solar cell (11) provides energy for at least one self-sufficient computing unit (42). Device after Claim 5 , characterized in that the self-sufficient computing unit (42) is part of a rail telematics unit (41). Method for operating a solar module (20), which comprises an arrangement of at least one solar cell (11), wherein the at least one solar cell (11) has at least one first transparent layer (12), wherein the first transparent layer (12) comprises a plurality of superposed layers Removable films (13), wherein - an efficiency of the solar cell (11) is detected, characterized in that - removing the uppermost film (10) of the first transparent layer (12) falls below a minimum efficiency of the solar cell (11) through the Efficiency of the solar cell (11) is performed. Method according to Claim 7 , characterized in that the detection of the efficiency of the solar cell (11) comprises at least one reference measurement of the efficiency of the solar cell (11). Method according to Claim 7 or 8th , characterized in that the removal of the uppermost film (10) by removing the uppermost film (10) is performed. Computer program, which is set up, the method according to one of Claims 7 to 9 perform. Machine-readable storage element (43) on which the computer program is based Claim 10 is stored.

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