Abstract: This method is for manufacturing a thermoelectric conversion module in which a first conductive member, a thermoelectric conversion element, a second conductive member are joined by joining members, the method comprising: a step for, after applying on the first conductive member a first paste including metal particles, disposing the thermoelectric conversion element on the first paste, and compressing and spreading the first paste; a step for disposing the second conductive member, after applying a second paste including metal particles in a controlled amount, on the thermoelectric conversion element, and compressing and spreading the second paste; and a step for sintering the first and the second pastes to obtain joining members.

Abstract: This method is for manufacturing a thermoelectric conversion module in which a first conductive member, a thermoelectric conversion element, a second conductive member are joined by joining members, the method comprising: a step for, after applying on the first conductive member a first paste including metal particles, disposing the thermoelectric conversion element on the first paste, and compressing and spreading the first paste; a step for disposing the second conductive member, after applying a second paste including metal particles in a controlled amount, on the thermoelectric conversion element, and compressing and spreading the second paste; and a step for sintering the first and the second pastes to obtain joining members.

Abstract: The present invention provides: a composite metal material which is able to be controlled in terms of strength, thermal conductivity and thermal expansion amount; and a method for producing this composite metal material. A composite metal material according to the present invention has a Cu-rich phase and an Fe-rich phase; and this composite metal material has a composite metal phase wherein Fe-rich phases are independently dispersed in a Cu-rich phase. The Cu-rich phase has a Cu content of more than 85 wt %; and each Fe-rich phase has an Fe content of more than 50 wt %.

Abstract: In a configuration to join thermoelectric elements with an electrode in a thermoelectric module, reduction in junction reliability between the thermoelectric elements and the electrode is suppressed in a high-temperature environment and in an environment in which vibration and shock are imposed as load, to efficiently transmit the outer-circumferential temperature to the thermoelectric elements. In a thermoelectric module in which a plurality of p-type thermoelectric elements and a plurality of n-type thermoelectric element are alternately arranged by aligning the surfaces thereof on the high-temperature side and the surfaces thereof on the low-temperature side, to electrically connect the thermoelectric elements in series to each other; the p-type thermoelectric elements and the n-type thermoelectric element are joined via an intermediate layer with a deformable stress relaxation electrode, to thereby absorb stress taking place during the module assembling process and the module operation by the electrode.

Abstract: There is provided a thermoelectric conversion element and a thermoelectric conversion module capable of ensuring a temperature difference between the front and the rear of the thermoelectric conversion element even in a high-temperature environment and presenting a high power generation performance. The thermoelectric conversion element including a sintered body constitutes a crystal grain laminated in a transverse direction in which a length in a longitudinal direction of the crystal grain is longer than a length in the transverse direction using at least some of crystal grains constituting the sintered body.

Abstract: Provided is a thermoelectric conversion module which achieves, in the vicinity of an element/high-temperature-side electrode bonded part, stress relaxation or strain relaxation within the element and at the bonded part, on which stress is concentrated. A thermoelectric conversion module comprising: electrodes arranged on its high-temperature side and low-temperature side; and P-type and N-type thermoelectric conversion elements connected to the electrodes via a bonding layer; wherein an area where the high-temperature-side electrode is connected to an end face of the P-type or N-type thermoelectric conversion element is smaller than an area where the low-temperature-side electrode is connected to an end face of the P-type or N-type thermoelectric conversion element.

Abstract: In a configuration to join thermoelectric elements with an electrode in a thermoelectric module, reduction in junction reliability between the thermoelectric elements and the electrode is suppressed in a high-temperature environment and in an environment in which vibration and shock are imposed as load, to efficiently transmit the outer-circumferential temperature to the thermoelectric elements. In a thermoelectric module in which a plurality of p-type thermoelectric elements and a plurality of n-type thermoelectric element are alternately arranged by aligning the surfaces thereof on the high-temperature side and the surfaces thereof on the low-temperature side, to electrically connect the thermoelectric elements in series to each other; the p-type thermoelectric elements and the n-type thermoelectric element are joined via an intermediate layer with a deformable stress relaxation electrode, to thereby absorb stress taking place during the module assembling process and the module operation by the electrode.

Abstract: In a structure for joining thermoelectric devices and electrodes in a thermoelectric module, the thermoelectric module is configured such that multiple P-type thermoelectric devices and multiple N-type thermoelectric devices are alternately disposed so as to be electrically connected in series via electrode members. A connected portion of the electrode member to the P-type thermoelectric device and a connected portion of the electrode member to the N-type thermoelectric device are made of different materials. This can suppress a considerable reduction in connection reliability between the thermoelectric devices and the electrodes even at a high temperature and efficiently transmit a peripheral temperature to the thermoelectric devices.

Abstract: Provided is a high temperature thermoelectric converting module including a plurality of p type thermoelectric elements; a plurality of n type thermoelectric elements; a plurality of electrodes; and a lead line. The plurality of p type thermoelectric elements, the plurality of n type thermoelectric elements, and the plurality of electrodes are electrically serially connected to each other, a pair of connecting lines that connects the lead line to one of the plurality of electrodes to output to the outside is further included, at least one electrode which is disposed at the high temperature side and the plurality of p type and n type thermoelectric elements are bonded with an intermediate layer therebetween. The plurality of p type and n type thermoelectric elements contain silicon as a component and the intermediate layer is formed as a layer containing aluminum and silicon and components other than silicon of the thermoelectric elements.