DE20309281U1 - Chassis part for vehicles has solar cell arranged between support and covering layer - Google Patents

Abstract

Chassis part has a solar cell (2) arranged between a support (1a, 1b) and a covering layer (5). A flat electrochromic element (3) is arranged between the support and the covering layer. The solar cell is electrically connected to the flat electrochromic element. An independent claim is also included for a vehicle having the above chassis part.

Description

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DaimlerChrysler AG Straub/deu

Body part of a vehicle and vehicle with such a

The typical structure of a vehicle body part shows a support structure which has at least one support, which usually consists of a steel plate pressed into a mold. This support is provided with several layers of paint, which in particular have a base coat, one or more color coats and a transparent top coat in the form of a clear coat. These coats of paint, which are applied by baptismal baths or spraying, create a very resistant protective layer for the support. The body part is also characterized by its special aesthetic effect.

It is also known to equip a house with solar cells and/or solar panels. These solar panels or solar cells have the following typical structure: a solar-active layer with corresponding electrical contacts is arranged between two layers of glass. Various systems are known as solar-active layers, for example dye solar cells, which the Fraunhofer Institute for Solar Energy Systems in Freiburg has extensively investigated. The way these solar cells work and their typical structure is known.

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Electrochromic systems are widely known based on their structure and their mode of operation, in particular from German patent applications DE 196 31 729 Al and DE 196 31 728 Al. Furthermore, various applications in space travel are known, for example from DE 44 09 470 C2 and as a glazing element from DE 196 31 420 Al. These electrochromic elements make it possible to change their optical transparency or their color by applying a predetermined voltage.
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The invention is based on the object of specifying a body part which has an appealing aesthetic effect and is suitable for providing energy.

A further object of the invention is to provide a vehicle that is particularly protected against overheating.

This object is achieved by a body part having the features of claim 1 and a vehicle having the features of claim 12.

Advantageous further training is the subject of the subclaims.

The body part according to the invention has at least one solar cell arranged between a carrier and the associated cover layer and at least one planar electrochromic element arranged between a carrier and the thick layer associated with the carrier. The at least one solar cell and the at least one planar electrochromic element are electrically connected to one another. This joint design and integration or arrangement of the solar cell or the electrochromic element in a ca-

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A very compact and functional arrangement is created for the body part, which gives the body part special functional properties. In particular, the body part shows the possibility of generating electrical energy with the help of the solar cell and, on the other hand, of changing the color or transparency and thus the optical appearance of the body part with the help of the flat electrochromic element. According to the invention, it is possible to overcome the mandatory requirement of an external energy supply to control the electrochromic element and thus the possibility of changing the aesthetic effect of the motor vehicle part, and thereby create a very safe and simple functionality of the body part, particularly with regard to the provision of electrical energy and the possibility of changing the aesthetic impression of the motor vehicle part. The carrier can be made of a wide variety of materials, for example steel, glass or plastic or other common carrier materials. In addition, it is possible to design the carriers of the at least one solar cell and the carriers of the at least one flat electrochromic element separately, contiguously, overlappingly or identically.

According to a particularly preferred embodiment of the invention, a control is provided which is suitable for varying the color and/or transparency of the at least one planar electrochromic element and thus its aesthetic effect using the energy obtained by the at least one solar cell. The control can be designed to be separate from the body part or arranged on it. In addition, it has proven particularly useful to design the control in the body part, in particular between the carrier and the transparent cover layer, with a design using the

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Chip-on-board technology has proven particularly effective for the control unit. The integrated design of the control, preferably using chip-on-board technology, has resulted in a very compact, robust and reliable design of the body part with its diverse functionalities.

The ability to vary the color and/or transparency of the body part or part of it creates the preferred option of influencing the amount of sunlight entering the vehicle interior in a targeted manner, thereby preventing the vehicle interior from heating up excessively. This is possible without the need for an external power supply to the body part.

The electrical energy generated by the solar cell alone is sufficient to control the color and/or transparency of the electrochromic element in such a way that, if necessary, for example in the case of strong sunlight, the electrochromic element is controlled in such a way that the heat input into the vehicle interior by the solar radiation is reduced.

The body part takes advantage of the fact that, especially in the case of strong sunlight, the solar cell provides enough electrical energy to control the electrochromic element accordingly. It has proven particularly useful to integrate the electrochromic element into a window for a motor vehicle, with a glass sunroof, a side window or a rear or front window all having proven to be suitable.

In addition, it has proven to be very advantageous to provide an energy storage device for the electrical energy generated by the solar cell, which energy storage device is connected to the at least one solar cell and the at least one flat electrical

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chrome element is electrically connected in such a way that the stored electrical energy gained by a solar cell is used to control the at least one electrochromic element to change its color and/or its transparency. So-called gold cups or nickel-metal hydride or nickel-cadmium accumulators, which are connected to the body part or attached to it, have proven to be particularly suitable energy stores. The so-called gold cups, which can be integrated into the body part, have proven to be particularly advantageous. This design enables very autonomous operation of the body part, which now enables reliable control of the at least one electrochromic element even under poor external radiation conditions, largely independent of the current radiation conditions or weather conditions.

In addition, it has proven particularly useful to provide electrical lines using indium tin oxide (ITO) to form the electrical line of the at least one solar cell and the at least one flat electrochromic element. These electrical lines make it possible, on the one hand, to conduct the electrical energy for controlling the at least one electrochromic element safely and reliably from a solar cell to the electrochromic element(s) and, on the other hand, to not negatively influence the optical, aesthetic properties of the body part due to the transparent property of the indium tin conductor. In addition, the conductors made of indium tin oxide (ITO) can be created in conjunction with the application of the solar cell(s) or the application of the electrochromic element(s), depending on the type of electro-optical element used, without fundamentally different or more complicated additional manufacturing or process steps.

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It has proven particularly useful to design the body part in such a way that at least one solar cell and at least one flat electrochromic element are spatially separated from one another, in particular between different supports and the transparent cover layers assigned to the supports. This spatial separation and maintenance of the electrical connection makes it possible to select positions for the individual electro-optical components that are optimally suited to the respective functionality. For example, it has proven useful to design the solar cell as part of the tailgate, or the trunk lid, or as part of the vehicle roof and to arrange the associated electrochemical element in the rear window. These arrangements make it possible to design the solar cell over a very large area so that the at least one solar cell can generate sufficient electrical energy and store it in an optionally provided energy storage device. This electrical energy is then used to supply the electrochemical element(s) that are electrically connected to the solar cell(s) with electrical energy so that they change their transparency or color so that the light or heat entering the vehicle interior is pleasantly low for the vehicle occupants. Overheating of the vehicle interior is thus largely ruled out. The provision of additional other energy sources is not necessary.

Alternatively, it has proven to be useful to connect at least one solar cell and at least one flat electrochromic element 0 to one another in a flat manner and to arrange these in particular in a window of a vehicle. This design makes it possible on the one hand to form a compact body part, in particular in the form of a window of the vehicle, and also to ensure safe, reliable and compact

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In this way, the energy supply of the surface-connected electrochromic element is ensured by the surface-connected solar cell. During the manufacture of this body part, the solar cell is preferably first applied to a common carrier and then the electrochromic element is applied to this surface, or vice versa, in order to then provide this with a transparent thick layer, which is preferably carried out as part of the usual painting process for the entire body, for example by means of an immersion bath or by spray painting.

It has proven particularly advantageous to make the surface-connected solar cell transparent. This transparent design can be achieved by making the surface elements of the solar cell very thin and having a small-area structure, which is particularly possible with thin-film solar cells. The use of such a transparent surface-connected solar cell enables the electrochromic element to be integrated with the surface-connected, transparent solar cell in a single window of a vehicle in a particularly advantageous manner. This ensures that when sunlight enters the body part, for example in the form of a window, the transparent solar cell is irradiated by the sunlight first, with the transparent solar cell converting the portions of the sunlight to which it is particularly sensitive with regard to optical-electrical conversion into electrical energy. The electrical energy obtained is used to control the electrochromic element arranged beneath the transparent solar cell. After passing through the transparent solar cell, the sunlight or the rest of the sunlight hits the electrochromic element, which is controlled by the applied voltage in such a way that it

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desired transparency or the desired color. This makes it possible to further filter the sunlight (or the remainder of it) that has passed through the transparent solar cell through the electrochromic element in the desired manner by adjusting the transparency or the color, and to control the desired optical properties and, in addition, the vehicle interior with regard to the desired heating or prevention of heating. It has proven particularly advantageous to select the electrochromic element(s) in such a way or to select the solar cells in such a way that their absorption properties are largely complementary, i.e. that the electro-optical components complement each other in their transmission properties in such a way that the sun's rays are attenuated on the one hand by the solar cell and on the other hand by the electrochromic element, insofar as attenuation by the latter is desired. The transmission properties are therefore preferably selected in such a way that their particularly strong absorption areas do not overlap, but rather fall apart.

This results in a very effective, shading body part, which is preferably designed in the form of a pane with flatly connected solar cells or electrochromic elements ^.

It has proven to be particularly advantageous to form individual components of the surface-connected solar cell or the surface-connected electrochromic element as a common component and thus to form these surface-connected electro-optical components as an integrated unit.

For example, the solar cell may be designed as a dye solar cell and the electrochromic element may have the same electrolyte as the dye solar cell, so that the electrolyte is used as a common component of both the solar cell and the electrochromic element and

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This creates a compact, simply structured body part. Other examples of common components include the use of common electrodes, which are of particular interest, as these are very costly and complex to manufacture and typically not very transparent components of the electrochromic elements or solar cells, and therefore have a strong influence on the aesthetic, optical properties of the body part, particularly with regard to body parts in the form of panes.

It has proven particularly useful to provide solar cells in the form of thin-film solar cells, particularly when used in a pane, in the form of a thick-film solar cell, particularly when forming solar cells separated from electrochromic elements, and organic or dye-sensitized solar cells, particularly in integrated units together with electrochromic elements connected over a large area. Depending on their design, these solar cells have proven to work specifically in combination with the electrochromic elements depending on the choice of body part, for example in the form of a pane or a trunk lid or sunroof or engine hood with their respective special properties.

An electrochromic element with an electrochromic agent in the form of tungsten trioxide, which interacts with an ion storage and ion conductor dissolved in an electrolyte, has proven to be a suitable electrochromic element. In a particularly preferred embodiment of the invention 0, the same electrolyte is used for the electrochromic element as for the dye solar cell, which means that the dye solar cell and the electrochromic element form an integrated system with a common electrolyte, common electrodes and layered structure of the solar cells.

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active dye layers or electrochromic layers. This integrated structure enables a cost-effective and durable body part that is suitable for providing energy, changing its color or transparency and thus not only conveying a uniform, attractive, aesthetic impression, but also changing it when necessary. The energy required to change the color, or the application of the voltage or the removal of the applied voltage, is preferably provided by the dye solar cell implemented in the body part. External circuitry can be implemented very easily so that the driver can cause the color change, for example by operating a switch. Alternatively or additionally, it is also possible, regardless of the choice of solar cell, for the electrochromic element to be controlled using measurement parameters determined by the sensors provided. For example, the solar cell itself can be used as a sensor for the amount or intensity of sunlight in order to change the color or transparency of the body part depending on this. The layers required for the formation of the electrochromic element, such as tungsten trioxide, the electrodes, the electrolyte with ion conductor and ion storage, are produced on the carrier of the body part using the same or corresponding technologies as the components/layers of the dye solar cell. This means that the integration of this arrangement of dye solar cell and electrochromic flat element into the production of a body part for a vehicle is possible without any fundamental difficulties.

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Another embodiment of the invention relates to a vehicle with a body part according to the invention, to which at least one electrically operated cooling element is assigned, which is operated using the energy generated by the solar cell. Fans, air conditioning systems or Peltier elements have proven particularly suitable as electrically operated cooling elements. This design of the vehicle makes it possible to achieve very effective prevention of overheating, which makes use of active cooling on the one hand and prevention or reduction of the undesirable excessive introduction of heat into the interior of a vehicle on the other. The design of the body part according to the invention makes it possible to provide all or a considerable proportion of the required energy independently.

In the following, the invention is explained in more detail with reference to an exemplary embodiment of a body part.

The figure shows a schematic representation of an exemplary body part 7 according to the invention. It shows a carrier structure 1, which consists of two carriers la, 1b. The carrier la is made of steel, while the carrier Ib is transparent, in particular made of glass-like material. A thick-film solar cell 2 is applied to the carrier la, which is connected to an electrochromic element 3 via electrical lines 4. The electrochromic element 3 is applied to the transparent carrier Ib. The carriers la, Ib, the thick-film solar cell 2, the electrical lines 4 and the electrochromic element 3 are coated with a transparent clear varnish 5, which covers the electro-optical components 2, 3 including the electrical lines

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and protects the carriers la, Ib from disturbing chemical or mechanical influences.

The thick-film solar cell 2 generates, with sufficient
Solar radiation generates electrical energy, which is transmitted via the electrical lines 4 and a not shown in the figure
Control is used to control the electrochromic element 3 in such a way that its transparency is significantly reduced. This makes it possible to limit the entry of sunlight into the vehicle interior through the transparent clear coat 5, the electrochromic element 3 and the transparent carrier
Ib can be reduced significantly and in a targeted manner. Heating of the interior, which adjoins the body part 7, can be reduced in a targeted manner by the body part 7. The solar cell 2 can be used both as an energy source for controlling the electrochromic element 3 and
also as a sensor to detect the situation in which a reduction in transparency is required. This is particularly necessary and advantageous in the case of strong solar radiation,
The electrochromic element 3 is combined
controlled by the control system not shown. According to the invention, it is possible to use an additional
Energy source for controlling the electrochromic element 3
to largely dispense with.

Claims (12)

1. Body part which is formed in one or more parts, with at least one carrier and at least one transparent cover layer, characterized in that
that at least one solar cell ( 2 ) is arranged between the carrier ( 1 a, 1 b) and the associated cover layer ( 5 ),
that at least one planar electrochromic element ( 3 ) is arranged between the carrier ( 1 a, 1 b) and the associated cover layer ( 5 )
and that at least one solar cell ( 2 ) is electrically connected to at least one planar electrochromic element ( 3 ). 2. Body part according to claim 1, characterized in that a control is provided which is suitable for varying the color and/or transparency of the planar electrochromic element ( 3 ) using the electrical energy obtained by the at least one solar cell ( 2 ). 3. Body part according to claim 1 or 2, characterized in that an energy storage device is provided which stores the electrical energy obtained by the at least one solar cell ( 2 ) and this energy can be used in particular for controlling the flat electrochromic element ( 3 ). 4. Body part according to one of claims 1 to 3, characterized in that at least one solar cell ( 2 ) and at least one planar electrochromic element ( 3 ) are connected by electrical lines ( 4 ) formed using indium tin oxide (ITO). 5. Body part according to one of claims 1 to 4, characterized in that at least one solar cell ( 2 ) and at least one flat electrochromic element ( 3 ) are arranged spatially separated from one another. 6. Body part according to one of claims 1 to 5, characterized in that at least one flat electrochromic element ( 3 ) is integrated in a pane ( 1b ) for a motor vehicle and in particular that at least one solar cell ( 2 ) electrically connected to this electrochromic element ( 3 ) is spatially offset. 7. Body part according to one of claims 1 to 4, characterized in that at least one solar cell ( 2 ) and at least one planar electrochromic element ( 3 ) are connected to one another in a planar manner. 8. Body part according to claim 7, characterized in that the at least one surface-connected solar cell ( 2 ) is transparent. 9. Body part according to one of claims 7 to 8, characterized in that the at least one surface-connected solar cell ( 2 ) and the at least one surface-connected electrochromic element ( 3 ) have common components and form an integrated unit. 10. Body part according to one of claims 1 to 9, characterized in that at least one solar cell ( 2 ) is a thin-film, a thick-film, an organic or a dye solar cell. 11. Body part according to one of claims 1 to 10, characterized in that the at least one electrochromic element ( 3 ) has tungsten trioxide (WO ₃ ) as the electrochromic active ingredient. 12. Vehicle with a body part ( 7 ) according to one of the preceding claims, with an electrically operated cooling element, in particular a fan, an air conditioning system or a Peltier element, which is operated using the electrical energy obtained by the solar cell ( 2 ).