Abstract: A thermoelectric element having high thermal resistance and requiring less semiconductor material than a conventional thermoelectric element with comparable performance comprises a substrate having a substrate front side and a substrate rear side opposite the substrate front side, a first contact, applied as a layer to the substrate front side, a second contact, applied as a layer to the substrate front side, a cut-off between the first and second contact which thermally and electrically separates the first and second contact from one another, and a thermoelectrically active layer having a top side and a bottom side, which are connected to one another by lateral delimiting surfaces, wherein the thermoelectrically active layer is arranged in the cut-off in such a way that the bottom side is on the substrate front side, and one of the lateral delimiting surfaces is against the first contact and one of the lateral delimiting surfaces is against the second contact.

Abstract: A thermoelectric element includes a first thermoelectric layer and a second thermoelectric layer, wherein a p-n junction is formed when the layers are formed. To specify a generic thermoelectric element that is suitable for a series connection in a thermoelectric generator without cabling, according to the invention—a substrate comprises a first and second contact surface on a cold side and a third contact surface on a hot side of the substrate. A temperature gradient can be applied between the contact surfaces on the cold and hot side. The first thermoelectric layer of the thermoelectric element is arranged on the substrate and connects a second contact surface to a third contact surface. The second thermoelectric layer of the thermoelectric element is arranged on the first thermoelectric layer, the p-n junction thereby being formed, and is connected to the first contact surface. The invention further relates to a method for producing such a thermoelectric element.

Abstract: A thermal solar system including a collector that is connected to a heat sink, in particular a heat storage medium, by way of a solar circuit containing a heat exchange medium. To reduce overheating of the system during idling and to improve the efficiency of the solar system, the solar circuit is connected temporarily to at least one heat exchanger by way of a valve control unit disposed at a hot side of a thermogenerator receiving an inflowing heat flow. A thermal insulation reduces the exchange of thermal energy between the collector of a thermal solar system and the heat exchanger.

Abstract: A thermogenerator including several thermocouples that are electrically connected together. The thermocouples are arranged between one hot side of the thermogenerator receiving a thermal flow and a cold side that is arranged at a distance from the hot side. The thermoelectric generator that at least temporarily uses the fed thermal energy efficiently. The thermoelectric generator can be designed as a module including a collector for a thermal solar system and the thermal carrier medium flowing through the collector is guided, at least temporarily, to a thermoelectric generator by a heat exchanger.

Abstract: A method for the low-cost production of sheet-like thermocouples comprises the following steps: —providing an electrically and thermally conductive substrate having at least one clearance, which subdivides the substrate into substrate regions, —fitting thermolegs onto the substrate, wherein each thermoleg is connected to a region of the substrate on a hot side and on a cold side, —applying an encapsulation, so that at least each thermoleg is enclosed and the encapsulation enters into a material bond with the regions of the substrate, —separating parts of the substrate in such a way as to prevent a flow of electric current between the regions of the substrate through the at least one clearance. The invention also relates to a substrate that is suitable for carrying out the method and to a thermocouple that can be produced by the method.

Abstract: The invention relates to an arrangement comprising a thermo-electric generator having a hot side which absorbs heat from a heat source, a cold side which discharges heat to a heat sink, and electrical terminals for outputting electrical energy with an output voltage and an electric circuit with a maximum permissible input voltage, the inputs of which are connected to the electrical terminals of the thermo-electric generator. Such arrangements may be used, for example, in exhaust systems of motor vehicles for more efficient use of the energy.

Abstract: A heat exchanger for at least one thermoelectric thin film element, having a hot and a cold side arranged on opposite longitudinal sides of the thin film element. The hot side is connected to a coupling element on a warm source and the cold side is connected to a heat sink. The heat exchanger connects in a simple and active manner to the thermoelectric thin film element and improves the efficiency of the attached thermoelectric thin film element. Especially flexible thin film elements spread out between the coupling element and the heat sink of the heat exchanger and support the load between the coupling element and the heat sink by a thermally insulating support structure.

Abstract: The invention relates to an arrangement comprising a thermo-electric generator having a hot side which absorbs heat from a heat source, a cold side which discharges heat to a heat sink, and electrical terminals for outputting electrical energy with an output voltage and an electric circuit with a maximum permissible input voltage, the inputs of which are connected to the electrical terminals of the thermo-electric generator. Such arrangements may be used, for example, in exhaust systems of motor vehicles for more efficient use of the energy.

Abstract: A module having a plurality of thermoelectric elements electrically connected in series, each being made of at least one n-layer and at least one p-layer made of thermoelectric material with a pn-transition implemented along a boundary layer. A temperature gradient parallel to the boundary layer between a hot and a cold side of each thermoelectric element can be applied or detected. Resistances of the electrical contacts of the individual thermoelectric elements are reduced and the thermal connection to a heat sink or heat source is improved for generating a temperature gradient along the boundary layer. The substrate and the thermoelectric elements are produced in separate processes, and the thermoelectric elements are adhered to previously structured, thermally and electrically conductive regions of the substrate using different adhesives for the cold and hot side of each thermoelectric element.

Abstract: A thermoelectric element includes at least one thermocouple comprising an n-doped and a p-doped thermal leg made of semiconductor material, wherein the thermal legs extend between a hot and a cold side of the thermoelectric element and different temperatures can applied and tapped between the hot and the cold side. In order to create a thermoelectric element haying a high thermal power density that nevertheless ensures sufficient mechanical stability using less semiconductor material, the thermoelectric effect and the support function of the block between two components is split.

Abstract: The invention relates to a method for producing thermoelectric layers by depositing thermoelectric material on a substrate by means of sputter deposition. In order to create a method for producing thermoelectric layers that are better suited for use in thermogenerators, and in particular have higher Seebeck coefficients, the production of a target made of thermoelectric material is proposed by mixing at least two powdered starting materials having a particle size from 0.01 ?m-5000 ?m, while coupling in energy and depositing the thermoelectric material from the target on the substrate by way of magnetron sputter deposition.

Abstract: A module having a plurality of thermoelectric elements electrically connected in series, each being made of at least one n-layer and at least one p-layer made of thermoelectric material with a pn-transition implemented along a boundary layer. A temperature gradient parallel to the boundary layer between a hot and a cold side of each thermoelectric element can be applied or detected. Resistances of the electrical contacts of the individual thermoelectric elements are reduced and the thermal connection to a heat sink or heat source is improved for generating a temperature gradient along the boundary layer. The substrate and the thermoelectric elements are produced in separate processes, and the thermoelectric elements are adhered to previously structured, thermally and electrically conductive regions of the substrate using different adhesives for the cold and hot side of each thermoelectric element.

Abstract: A heat exchanger for at least one thermoelectric thin film element, having a hot and a cold side arranged on opposite longitudinal sides of the thin film element. The hot side is connected to a coupling element on a warm source and the cold side is connected to a heat sink. The heat exchanger connects in a simple and active manner to the thermoelectric thin film element and improves the efficiency of the attached thermoelectric thin film element. Especially flexible thin film elements spread out between the coupling element and the heat sink of the heat exchanger and support the load between the coupling element and the heat sink by a thermally insulating support structure.

Abstract: A thermogenerator including several thermocouples that are electrically connected together. The thermocouples are arranged between one hot side of the thermogenerator receiving a thermal flow and a cold side that is arranged at a distance from the hot side. The thermoelectric generator that at least temporarily uses the fed thermal energy efficiently. The thermoelectric generator can be designed as a module including a collector for a thermal solar system and the thermal carrier medium flowing through the collector is guided, at least temporarily, to a thermoelectric generator by a heat exchanger.

Abstract: A thermal solar system including a collector that is connected to a heat sink, in particular a heat storage medium, by way of a solar circuit containing a heat exchange medium. To reduce overheating of the system during idling and to improve the efficiency of the solar system, the solar circuit is connected temporarily to at least one heat exchanger by way of a valve control unit disposed at a hot side of a thermogenerator receiving an inflowing heat flow. A thermal insulation reduces the exchange of thermal energy between the collector of a thermal solar system and the heat exchanger.