Abstract: A micromechanical sensor device and a corresponding production method, in which the micromechanical sensor device is equipped with a sensor substrate having a front side and a rear side, a sensor region provided on the front side that can be brought into contact with an environmental medium, and a capping device, attached on the front side, for capping the sensor region. In the capping device and/or in the sensor substrate, one or more capillaries are formed for conducting the environmental medium onto the sensor region, a liquid-repellent layer being provided at least in some regions on the inner walls of the capillaries.

Abstract: A micromechanical sensor device and a corresponding production method, in which the micromechanical sensor device is equipped with a sensor substrate having a front side and a rear side, a sensor region provided on the front side that can be brought into contact with an environmental medium, and a capping device, attached on the front side, for capping the sensor region. In the capping device and/or in the sensor substrate, one or more capillaries are formed for conducting the environmental medium onto the sensor region, a liquid-repellent layer being provided at least in some regions on the inner walls of the capillaries.

Abstract: A sensor comprises a sensor element configured to provide a sensor signal representing at least one measurand detected by the sensor element, an electrical circuit configured to process the sensor signal to form a data signal, a photovoltaic cell configured to provide electrical energy for the sensor element and the electrical circuit, and a housing, in which the sensor element, the electrical circuit and the photovoltaic cell are positioned, the housing including a recess in which the photovoltaic cell is positioned, and a rim surrounding the recess and protruding beyond the photovoltaic cell. A method is also provided.

Abstract: A method for producing a thermoelectric generator includes a preparation step, a connection step and an insertion step. In the preparation step, a first substrate, a thermoelectric generator material and a second substrate are prepared. In the connection step, the generator material is connected to the first substrate and the second substrate. In this way, a first side of the generator material is connected to the first substrate in a thermally and electrically conductive manner. A second side of the generator material, opposite the first side, is connected to the second substrate in a thermally and electrically conductive manner. In the insertion step, a support material is inserted between the first substrate and the second substrate, in order to support the first substrate and the second substrate against each other and/or to mechanically connect them together.

Abstract: A photovoltaic module has at least one solar cell having an irradiation surface for receiving light. The photovoltaic module is configured to provide a voltage. The photovoltaic module also includes a carrier unit which is arranged laterally offset from the solar cell at least on one side. A first surface of the carrier unit is oriented flush with the irradiation surface of the solar cell within a predefined tolerance range. The photovoltaic module also includes at least one electrical conductor, which contacts a carrier contact connection on a second surface of the carrier unit opposite the first surface via a cell contact connection of an electronic component on the solar cell or the solar cell in an electrically conductive manner. The cell contact connection is arranged on a contacting side of the solar cell opposite the irradiation surface.

Abstract: An electrical circuit includes a component, a thermoelectric generator, and a housing. The component is a sensor element configured to sense a quantity to be measured. The component is mechanically connected to an element side of a carrier element of the circuit. The thermoelectric generator is electrically connected to the component and mechanically connected to the carrier element. The thermoelectric generator is configured to supply the component with electrical energy by using a heat flow flowing through the thermoelectric generator. The housing is arranged on the element side of the carrier element and at least partially covers the component and the thermoelectric generator. The housing is configured to conduct the heat flow to the thermoelectric generator.

Abstract: A photovoltaic module has at least one solar cell having an irradiation surface for receiving light. The photovoltaic module is configured to provide a voltage. The photovoltaic module also includes a carrier unit which is arranged laterally offset from the solar cell at least on one side. A first surface of the carrier unit is oriented flush with the irradiation surface of the solar cell within a predefined tolerance range. The photovoltaic module also includes at least one electrical conductor, which contacts a carrier contact connection on a second surface of the carrier unit opposite the first surface via a cell contact connection of an electronic component on the solar cell or the solar cell in an electrically conductive manner. The cell contact connection is arranged on a contacting side of the solar cell opposite the irradiation surface.

Abstract: A sensor comprises a sensor element configured to provide a sensor signal representing at least one measurand detected by the sensor element, an electrical circuit configured to process the sensor signal to form a data signal, a photovoltaic cell configured to provide electrical energy for the sensor element and the electrical circuit, and a housing, in which the sensor element, the electrical circuit and the photovoltaic cell are positioned, the housing including a recess in which the photovoltaic cell is positioned, and a rim surrounding the recess and protruding beyond the photovoltaic cell.

Abstract: An electrical circuit includes a solar cell that has a photovoltaically active front side and a back side. An electronic or micromechanical component is arranged on the back side of the solar cell and is electrically connected to the photovoltaically active front side of the solar cell by a contact-making structure. The electrical circuit also includes a transparent first protective layer that is arranged on the photovoltaically active front side of the solar cell. The contact-making structure has a first contact-making section that is arranged on a front side of the first protective layer facing away from the solar cell.

Abstract: An electrical circuit includes a solar cell that has a photovoltaically active front side and a back side. An electronic or micromechanical component is arranged on the back side of the solar cell and is electrically connected to the photovoltaically active front side of the solar cell by a contact-making structure. The electrical circuit also includes a transparent first protective layer that is arranged on the photovoltaically active front side of the solar cell. The contact-making structure has a first contact-making section that is arranged on a front side of the first protective layer facing away from the solar cell.

Abstract: A method for producing an electrical and mechanical connection, wherein a solid body comprises a support, on which is disposed an electrical contact zone and an electrically insulating support zone. A flexible, flat cable comprises a support layer made of an electrically insulating material and a strip conductor, with an electrical contacting point and a laterally adjacent insulating cable zone. An adhesive layer is applied on the cable and the contacting point is disposed on the support layer so that the adhesive layer surrounds the contacting point and adheres to the cable. The support and the cable are positioned in a pre-assembly position so that the contacting point of the cable is facing the contact zone of the support and the adhesive layer is facing the electrically insulating support zone. The solid body and the cable are positioned so that the contacting point electrically contacts the contact zone and the adhesive layer adheres to the surface of the solid body.