The present disclosure provides wearable electronic devices with thermoelectric devices. The wearable electronic device may comprise a user interface for displaying information to a user. The thermoelectric device may comprise a heat collecting unit, a thermoelectric element, and a heat expelling unit. During use, the thermoelectric element may generate power upon the flow of thermal energy from the heat collecting unit, across the thermoelectric element, and to the heat expelling unit.

A thermoelectric converter includes a first substrate that is deformable, a second substrate that is deformable, a plurality of thermoelectric conversion elements, and a group of electrodes. The plurality of thermoelectric conversion elements are disposed between the first substrate and the second substrate. The group of electrodes electrically interconnect the plurality of thermoelectric conversion elements. The plurality of thermoelectric conversion elements are arranged in a plurality of rows. The group of electrodes include a bridge electrode disposed across a first row and a second row among the plurality of rows. The first row is adjacent to the second row. The bridge electrode has a first part whose thickness is smaller than a thickness of each of remaining electrodes other than the bridge electrode among the group of electrodes and whose surface area is larger than a surface area of each of the remaining electrodes.

Method for generation of electrical power within a three-dimensional integrated structure comprising several elements electrically interconnected by a link device, the method comprising the production of a temperature gradient in at least one region of the link device resulting from the operation of at least one of the said elements, and the production of electrical power using at least one thermo-electric generator comprising at least one assembly of thermocouples electrically connected in series and thermally connected in parallel and contained within the said region subjected to the said temperature gradient.

There is provided a calorimeter. Heat flows in and out of the sample via a thermoelectric module. The thermoelectric module is so constituted that a pair of a P-type thermoelectric element and an N-type thermoelectric element is disposed between substrates, and the pair of the thermoelectric elements are connected in n pairs so that the P-type thermoelectric elements and the N-type thermoelectric element are arranged alternately in π-shape; a calorimetric sensitivity of the thermoelectric module of a thermal conductance surrounding thermoelectric module and a thermal conductance between substrates of the thermoelectric modules and a noise based on an electric resistance of the thermoelectric module depend on an L/A ratio of the thermoelectric element constituting the thermoelectric module and the number n of the pairs of the thermoelectric elements, where the L/A ratio is 6 mm.sup.−1 or more, and the number n of the pairs is 4 or more.

A thermoelectric generator includes a first channel for passing a warm fluid along a direction of flow, a second channel for passing a cold fluid, a plurality of thermocouple elements disposed along the direction of flow between the first and second channels, a first member includes portions disposed between the elements and the first channel and associated with the individual elements for providing a heat coupling between the associated element and the first channel, and a second member including portions disposed between the elements and the second channel and associated with the individual elements for providing a heat coupling between the associated element and the second channel. The sum of the thermal resistances of those portions that are associated with a first element positioned upstream of a second element is bigger than the sum of the thermal resistances of those portions that are associated with the second element.

Disclosed is a flexible thermoelectric system. More particularly, the flexible thermoelectric system includes thermoelectric units that are wearable on the human body; a heating unit that is provided on one side of the thermoelectric units so as to be disposed between the thermoelectric units and the skin and is formed of a hygroscopic and exothermic material; and a heat dissipating unit that is provided on other side of the thermoelectric units such that the heat dissipating unit faces the heating unit and the thermoelectric units are disposed between the heat dissipating unit and the heating unit; wherein the heating unit and the heat dissipating unit are flexible. Due to such a configuration, the flexible thermoelectric system may be flexibly attached to the skin and temperature difference between upper and lower surfaces of the thermoelectric units may be maximized. Accordingly, power generation or cooling performance may be improved.

A thermoelectric device having a flat tube, a first thermoelectric module, and a second thermoelectric module. The thermoelectric modules each have a housing that includes at least two opposite first walls. A plurality of thermoelectric elements is arranged between the first walls of the housing. The thermoelectric elements have opposite surfaces, each of which is in thermal contact with one of the first walls of the housing of the thermoelectric module.

The present disclosure relates to a photoelectric conversion apparatus. The photoelectric conversion apparatus includes a carbon nanotube layer, a first thermoelectric conversion layer, a second thermoelectric conversion layer, a first electrode and a second electrode. The carbon nanotube layer includes a plurality of carbon nanotubes. An areal density of the carbon nanotube layer is in a range from about 0.16 g/m.sup.2 to about 0.32 g/m.sup.2.

A thermoelectric conversion element is made of a material with a band structure having Weyl points in the vicinity of Fermi energy. The thermoelectric conversion element has a thermoelectric mechanism for generating electromotive force by the anomalous Nernst effect. A thermoelectric conversion device includes a substrate; and a power generator provided on the substrate and including a plurality of thermoelectric conversion elements. Each of the plurality of thermoelectric conversion elements has a shape extending in one direction, and is made of a material identical to that of the above-mentioned thermoelectric conversion element. The plurality of thermoelectric conversion elements is arranged in parallel to one another in a direction perpendicular to the one direction and electrically connected in series to one another in a serpentine shape.

A flexible Peltier device in which emitting heat conversion properties between Peltier elements and an object transferring heat may be improved and a flexible heat-emitting sheet having the Peltier elements bonded thereto may be bent without worrying the separation there between. A flexible Peltier device includes a single or plural Peltier element which is disposed on one surface side of a heat-emitting sheet having flexibility made from heat-conductive rubber containing a heat conductive filler and each semiconductor element which has a heating side and a cooling side and composes the Peltier element at least one of the heating side and the cooling side is bonded integrally to the heat-emitting sheet by a direct covalent bond and/or by an indirect covalent bond through a molecular adhesive at active groups existing on each other surfaces.