A thermoelectric device may include at least two thermoelectric elements manufactured from a thermoelectrically active material. The thermoelectric device may also include at least one conductor path element electrically connecting the at least two thermoelectric elements. The thermoelectric device may further include at least one adapter layer made from a metal and disposed on each of the at least two thermoelectric elements and sandwiched between the respective thermoelectric element and the at least one conductor path element.

A thermoelectric sintered body according to an embodiment comprises thermoelectric powder, the thermoelectric powder, arranged in a horizontal direction, comprising: a plurality of first powders in the shape of plate-type flakes; and a plurality of second powders in a shape different from that of the first powders, wherein the second powders comprise 5 volume % or less of the total thermoelectric powder.

A thermoelectric conversion module is disclosed that corrects the difference in thermal resistance between a P-type thermoelectric conversion member and an N-type thermoelectric conversion member. In this thermoelectric conversion module, since insulators included in the P-type thermoelectric conversion member and the N-type thermoelectric conversion member have a different thermal resistance, it is possible to correct the difference in thermal resistance between the P-type thermoelectric conversion element and the N-type thermoelectric conversion element.

A thermoelectric generation module having: a base material; a plurality of electrodes disposed on the base material; and a thermoelectric conversion layer that coats each of the electrodes individually leaving a portion of the electrode to which a wiring is to be connected, wherein the thermoelectric conversion layer adheres to the base material around the electrode excluding the portion of the electrode to which the wiring is to be connected.

To provide a stress relaxation structure that can achieve both high thermal conductivity and high thermal stress relaxation ability and has excellent vibration durability, and a thermoelectric conversion module having such a stress relaxation structure. The stress relaxation structure includes a rolled-up body having a first thermal conductor and a second thermal conductor that are alternately rolled up. The first thermal conductor is metal foil, and the second thermal conductor is porous metal foil.

An exhaust manifold for a vehicle configured for improving fuel efficiency of the vehicle by improving fluidity of exhaust gas may include a manifold body having a plurality of inlet portions which are outwardly extended and an outlet portion which is outwardly extended, wherein the manifold body may have a flat surface formed on at least a portion of a top surface thereof.

The invention relates to the use of thermo-compression bonding (TCB) for bonding electrically conductive contacts to thermoelectric material pieces, respective processes and thermoelectric modules which are suitable for fitting in the exhaust system of an internal combustion engine.

Embodiments relate to methods of manufacturing and operating nano-scale energy converters and electric power generators. The nano-scale energy converters include two electrodes separated a predetermined distance. The first electrode is manufactured to have a first work function value. The second electrode is manufactured to have a second work function value different from the first work function value. A cavity is formed between the first and second electrodes, and a nanofluid is disposed in the cavity. The nanofluid includes a plurality of nanoparticles, with the nanoparticles having a third work function value that is greater than the first and second work function values. The relationship of the work function values of the nanoparticles to the work function values of the electrodes optimizes transfer of electrons to the nanoparticles through Brownian motion and electron hopping.

The present invention relates to a thermoelectric module, and a thermoelectric module according to an exemplary embodiment of the present invention includes: a plurality of thermoelectric elements that are disposed between a heat transmission member and a cooling member; and a first electrode layer and a second electrode layer that are respectively disposed between the heat transmission member and the plurality of thermoelectric elements and between the cooling member and the plurality of thermoelectric elements, wherein the plurality of thermoelectric elements may include P-type thermoelectric elements and N-type thermoelectric elements, and a P-type thermoelectric element and an N-type thermoelectric element that neighbor each other may have different heights, and one electrode layer selected from among the first electrode layer and the second electrode layer formed throughout the P-type thermoelectric element and the N-type thermoelectric element that neighbor each other may have at least two bent portions.

A compound containing Sn, Te and Mn, and further containing either one or both of Sb and Bi.