Abstract: A thermoelectric conversion module according to the present disclosure includes a first substrate, a second substrate, and a peripheral thermoelectric conversion element group and a central thermoelectric conversion element group, each of which groups is disposed between the first substrate and the second substrate, and contains a plurality of thermoelectric conversion elements. The peripheral thermoelectric conversion element group is disposed in an area including peripheries of the first substrate and the second substrate, and the central thermoelectric conversion element group is disposed closer to a center of the first substrate and a center of the second substrate than the peripheral thermoelectric conversion element group. The plurality of thermoelectric conversion elements of the central thermoelectric conversion element group are disposed more densely than the plurality of thermoelectric conversion elements of the peripheral thermoelectric conversion element group.

Abstract: A structure of a thermoelectric film including a thermoelectric substrate and a pair of first diamond-like carbon (DLC) layers is provided. The first DLC layers are respectively located on two opposite surfaces of the thermoelectric substrate and have electrical conductivity.

Abstract: A solar energy heat to electricity conversion device is provided that includes a thermally conductive solar receiver having a cylinder with an open end and a cup-shape closed end and a thermally conductive fin disposed on an outside surface of the cup-shape closed end, where the thermally conductive solar receiver is capable of absorbing solar energy directed into the cylinder, a thermoelectric module (TEM) that includes a first plate and a second plate, where the first plate is in contact with a surface of the thermally conductive fin, where the conductive fin is capable of transferring heat to the first plate, and a thermally conductive water block in contact with the TEM that is capable of cooling the TEM, where the water block includes a fluid input and a fluid output, where the TEM generates electricity according to a temperature difference between the first plate and the second plate.

Abstract: The non-aqueous electrolyte battery includes an outer case, a positive electrode housed in the outer case, a negative electrode housed in the outer case such that the negative electrode is separated from the positive electrode, and a non-aqueous electrolyte accommodated in the outer case. The negative electrode comprises a current collector and negative electrode layer formed on one surface or both surfaces of the current collector. The negative electrode layer includes at least one main negative electrode layer which is formed on the surface of the current collector and contains a first active material, and a surface layer which is formed on the surface of the main negative electrode layer and contains a second active material different from the first active material, the second active material being a lithium titanium composite oxide having a spinel structure.

Abstract: A semiconductor element includes at least a thermoelectric material and a first frame part which are force-lockingly connected to one another, with the frame part forming a diffusion barrier for the thermoelectric material and an electrical conductor. A method for producing the semiconductor element as well as a thermoelectric module having at least two semiconductor elements, are also provided.

Abstract: In a lead-acid battery including an electrode plate group housed in a cell chamber 6 with an electrolyte, each positive electrode plate includes a positive electrode grid made of lead or a lead alloy containing no antimony, and a positive electrode active material with which the positive electrode grid is filled. Each negative electrode plate includes a negative electrode grid made of lead or a lead alloy containing no antimony, a surface layer formed on a surface of the negative electrode grid and made of a lead alloy containing antimony, and a negative electrode active material with which the negative electrode grid is filled. A mass ratio MN/MP falls within a range of 0.70 to 1.10, where MP represents the mass of the positive electrode active material per cell chamber, and MN represents the mass of the negative electrode active material per cell chamber.

Abstract: A bifacial solar cell module includes a solar cell panel including a plurality of strings arranged in a row direction. Each of the plurality of strings is formed by electrically connecting a plurality of bifacial solar cells arranged adjacent to one another in a column direction using an interconnector. The bifacial solar cell module further includes a plurality of lead wires electrically connecting an interconnector of the bifacial solar cell positioned at an end of each string to a junction box. At least one of the plurality of strings includes the n bifacial solar cells, and other strings not including the n bifacial solar cells include more than n bifacial solar cells, where n is a positive integer equal to or greater than 1.

Abstract: A fixing device thermally fixes an unfixed image onto a sheet through heat of a heating body that is heated through electromagnetic induction, the fixing device including an excitation coil generating flux for heating the heating body; one or more core members disposed opposite the heating body with respect to the excitation coil; a thermo-electric conversion element disposed farther from the excitation coil than the core members; and a thermally conductive member connected to the excitation coil and to a heat-absorbing face of the thermo-electric conversion element, transferring heat from the excitation coil to the thermo-electric conversion element.

Abstract: The present invention provides a method of preparing a nanocomposite thermoelectric material. The method includes heating a reaction mixture of a semiconductor material and a metal complex to a temperature greater than the decomposition temperature of the metal complex. The heating forms metallic inclusions having a size less than about 100 nm that are substantially evenly distributed throughout the semiconductor material forming the nanocomposite thermoelectric material. The present invention also provides a nanocomposite thermoelectric material prepared by this method.

Abstract: A thermoelectric conversion device includes: a substrate; two magnetic layers having a fixed magnetization direction with respect to the substrate; and at least one electrode including a material having a spin orbit interaction, wherein a gap (or dielectric layer of low thermal conductivity) is provided between the magnetic layers. A thickness of the gap (or dielectric layer) is of a distance within the range at that a magnetic dipole interaction is exerted, and a film thickness of the magnetic layers is of about a characteristic length determined by diffusion or the like of a magnetic excitation.

Abstract: Embodiments of a low resistivity ohmic contact are disclosed. In some embodiments, a method of fabricating a low resistivity ohmic contact includes providing a semiconductor material layer and intentionally roughening the semiconductor material layer to create a characteristic surface roughness. The method also includes providing an ohmic contact metal layer on a surface of the semiconductor material layer and providing a diffusion barrier metal layer on a surface of the ohmic contact metal layer opposite the semiconductor material layer. In this way, the adhesive force between the semiconductor material layer and the ohmic contact metal layer may be increased.

Abstract: A thermoelectric module includes an inner circumferential surface and an outer circumferential surface each being assigned to a respective hot side or cold side and forming an intermediate space therebetween, a geometric axis and at least one sealing element. The sealing element at least partially forms the inner circumferential surface or is separated from the hot side or cold side disposed there only by an electric insulation layer. The sealing element seals the intermediate space at least with respect to the cold side and has at least one electric conductor connecting at least one thermoelectric element disposed in the thermoelectric module to at least one other electric conductor disposed outside the thermoelectric module. A vehicle having the thermoelectric module is also provided.

Abstract: A thermoelectric material including: a thermoelectric matrix; and a plurality of metal nanoparticles disposed in the thermoelectric matrix, wherein a difference between a work function of thermoelectric matrix and a work function of a metal particle of the metal nanoparticles is about ?1.0 electron volt to about 1.0 electron volt.

Abstract: A method for coating workpieces which consist of two different metallic materials includes providing the workpiece in a nickel strike electrolyte with a nickel layer as substrate before the application of a corrosion-resistant layer.

Abstract: Thermoelectric devices with interface materials and methods of manufacturing the same are provided. A thermoelectric device can include at least one shunt, at least one thermoelectric element in thermal and electrical communication with the at least one shunt, and at least one interface material between the at least one shunt and the at least one thermoelectric element. The at least one interface material can comprise a plurality of regions comprising a core material with each region separated from one another and surrounded by a shell material. The interface material can be configured to undergo deformation under (i) a normal load between the at least one shunt and the at least one thermoelectric element or (ii) a shear load between the at least one shunt and the at least one thermoelectric element. The deformation can reduce interface stress between the at least one shunt and the at least one thermoelectric element.

Abstract: A thermoelectric material and a method for manufacturing the same are provided. The thermoelectric material includes a mixture of nano-thermoelectric crystal particles, micron-thermoelectric crystal particles and nano-metal particles.

Abstract: A system for generating electrical energy is disclosed. The system includes at least one device having a plurality of heat radiating components each having a cooling component. The system includes a converter system comprising a plurality of thermal electric generators contained in each of the at least one device, each of the plurality of thermal electric generators integrated between a respective one of the plurality of heat radiating components and its respective cooling component, the plurality of thermal electric generators electrically interconnected according to power requirements of the at least one device, and the plurality of thermal electric generators generating power used to power the at least one device.

Abstract: As the first conductive paste, a paste is used which is made by adding an organic solvent to powder of alloy in which a plurality of atoms keep a given crystal structure constant. As the second conductive paste, a paste is used which is made by adding an organic solvent to powder of metal different in kind from the alloy. In a step of making the stack body, cavities are formed in the stack body. In a uniting step, the cavities work to facilitate flow of thermoplastic resin to absorb pressure acting in a direction different from a direction in which pressure exerted on the first conductive paste to unite the stack body, thereby resulting in an increase in pressure for the uniting to solid-state sinter the first conductive paste to make the first layer-to-layer connecting member.

Abstract: A method for converting heat to electric energy is described which involves thermally cycling an electrically polarizable material sandwiched between electrodes. The material is heated by extracting thermal energy from a gas to condense the gas into a liquid and transferring the thermal energy to the electrically polarizable material. An apparatus is also described which includes an electrically polarizable material sandwiched between electrodes and a heat exchanger for heating the material in thermal communication with a heat source, wherein the heat source is a condenser. An apparatus is also described which comprises a chamber, one or more conduits inside the chamber for conveying a cooling fluid and an electrically polarizable material sandwiched between electrodes on an outer surface of the conduit. A gas introduced into the chamber condenses on the conduits and thermal energy is thereby transferred from the gas to the electrically polarizable material.

Abstract: According to a first aspect, the invention relates to a thermoelectric module (10) that comprises a thermoelectric layer (15) comprising one p-type (7p) and one n-type (7n) portions presenting together an upper and a lower main surfaces (11,12). The thermoelectric module (10) further comprises a first and a second thermal resistor elements (1r, 2r), and a first thermal bridge element (3c), between and adjacent to the first and second thermal resistor elements (1r, 2r). The first and second thermal resistor elements (1r, 2r) and the first thermal bridge element (3c) cover the whole lower main surface (12). The p-type (7p) and the n-type (7n) portions are adjacent and directly coupled by an interface (7i). The first thermal bridge element (3c) spans at least over the orthogonal projection of the interface (7i) on the lower main surface (12).

Abstract: A hybrid device (80) comprises, in a first zone (91), at least one thermoelectric element (3) allowing an electric current to be generated from a temperature gradient applied between two of its active faces (4a, 4p). The device (80) further comprises a first circuit (1) able to allow the circulation of a first fluid, and a second circuit (2) able to allow the circulation of a second fluid of a temperature lower than that of the first fluid so as to create the gradient. The device (80) also comprises a second zone (92) so as to allow an exchange of heat between the second fluid and the first fluid. The device (80) is designed so that the first fluid passes through it by travelling in a single direction, referred to as first direction (L), wherein the first zone (91) and the second zone (92) are situated in series in the first direction (L).

Abstract: A heat exchanger (7) for an exhaust gas system (5) of an internal combustion engine (1) includes a thermoelectric generator (13) with plural thermoelectric elements (15) that each have a hot side (16) and a cold side (17). A heating channel (18) conducts a heating medium on the hot sides and a cooling channel (19) conducts cooling medium on the cold sides (17). The thermoelectric generator (13), the heating channel (18), and the cooling channel (19) are arranged adjacent in a stacking direction (20) and form a channel stack (21). A housing (8) that encloses an interior (22) accommodates the channel stack (21) and has medium inlets (9, 11), outlets (10, 12) and electrical connections (14). The thermoelectric elements are arranged in a double-walled intermediate bottom (15) that separates the cooling channel (19) from the heating channel (18), adjacent to said cooling channel, in regard to fluid flow.

Abstract: A thermoelectric module includes at least mutually opposite first and second walls and elements made of thermoelectric material disposed therebetween. A filler material spaces all of the elements apart from one another and a main heat flow direction extends from the first wall to the second wall. A method for operating the thermoelectric module, a thermoelectric generator and a motor vehicle are also provided.

Abstract: A thermoelectric generation system for turbine engines and the like has at least one thermoelectric generator disposed proximate the turbine engine such that waste heat from the turbine engine can be converted into electricity. Vehicle performance and efficiency can be enhanced by mitigating the need for mechanically driven electric power generators, which undesirably drain power from the turbine engine thus adversely affect the vehicle's performance.

Abstract: In a thermoelectric conversion element comprising a thermoelectric conversion layer formed by using a thermoelectric conversion material, the thermoelectric conversion material includes a polythiophene polymer, which includes a main chain made of a repeating unit represented by the following formula (1), and has a side chain R in a regiorandom array with respect to the main chain, a carbon nanotube, and a non-conjugated macromolecule. In Formula (1), R represents an alkyl group having 1 to 20 carbon atoms.

Abstract: The present disclosure relates to an energy recovery system for a vehicle. The vehicle includes a plurality of heat sources generating waste heat. The energy recovery system includes at least one thermoelectric module interfaced with each of the plurality of heat sources. Further, the waste heat provides a high temperature heat source for each of the thermoelectric modules. A low temperature heat source is interfaced with each of the thermoelectric modules. A temperature difference between the high temperature heat source and low temperature heat source produces a thermoelectric power. A controller is configured to monitor the thermoelectric power generated by each of the thermoelectric modules. The controller is further configured to optimize a utilization of the thermoelectric power generated by each of the thermoelectric modules.

Abstract: A thermoelectric conversion element includes a cable. The cable includes a first member extended in the axis direction of the cable, and a second member extended in the axis direction to cover at least a part of the outer face of the first member. One of the first and second members is a magnetic body. The other of the first and second members is a conductive body formed of material exhibiting a spin orbit coupling.

Abstract: The present disclosure relates to a energy recovery system for a vehicle. The waste recovery system includes a thermoelectric module which is interfaced with a heat source of the vehicle. The heat source generates waste heat. Further, the waste heat provides a high temperature heat source for the thermoelectric module. A low temperature heat source is also interfaced with the thermoelectric module. A temperature difference between the high temperature heat source and the low temperature heat source generates thermoelectric power. A controller is configured to select the low temperature heat source based on at least one of the temperature difference associated with the thermoelectric module, and an operating parameter of the vehicle.

Abstract: A module for a thermoelectric generator includes first and second ends, at least one inner tube and one outer tube disposed around the outside of the inner tube and at least one thermoelectric element disposed between the inner and outer tubes. The inner and outer tubes are each electrically insulated from the at least one thermoelectric element. At least one electrically conductive first contact is provided on each of the first and second ends, for electrically conductively connecting the at least one thermoelectric element to an electrical conductor. The module can conduct a fluid or coolant flow through the module from the first end to the second end. An electrical conductor, a thermoelectric generator, a motor vehicle and a method for producing a module, are also provided.

Abstract: Traditional power generation systems using thermoelectric power generators are designed to operate most efficiently for a single operating condition. The present invention provides a power generation system in which the characteristics of the thermoelectrics, the flow of the thermal power, and the operational characteristics of the power generator are monitored and controlled such that higher operation efficiencies and/or higher output powers can be maintained with variably thermal power input. Such a system is particularly beneficial in variable thermal power source systems, such as recovering power from the waste heat generated in the exhaust of combustion engines.

Abstract: A thermoelectric converting thin line includes a thin line extending in one direction, a first ferromagnetic layer formed on a side of the thin line having a magnetization fixed in a plane in a direction intersecting with a direction along which the thin line extends, and a first nonmagnetic metal layer formed on the first ferromagnetic layer.

Abstract: The present invention relates to a thermoelectric conversion material including a carbon nanotube, a thermoelectric conversion element including the same, an article for thermoelectric power generation, and a method for manufacturing the thermoelectric conversion element. The thermoelectric conversion material comprising: a carbon nanotube; and a polythiophene polymer constituted of a repeating unit represented by the following formula (1), in Formula (1), each of R1 and R2 independently represents an alkyl group having 1 to 20 carbon atoms.

Abstract: A thermionic generator for converting thermal energy to electric energy includes: an emitter electrode for emitting thermal electrons from a thermal electron emitting surface when heat is applied to the emitter electrode; a collector electrode facing the emitter electrode spaced apart from the emitter electrode by a predetermined distance, and receiving the thermal electrons from the emitter electrode via a facing surface of the collector electrode; and a substrate having one surface. The emitter electrode and the collector electrode are disposed on the one surface of the substrate, and are electrically insulated from each other. The thermal electron emitting surface and the facing surface are perpendicular to the one surface.

Abstract: A remote water meter monitoring system is provided. A mesh network-type transceiver unit is coupled to a water meter housing having a water counting mechanism inside to transmit water consumption information as well as other sensor information, such as backflow detection, water pressure, and water metrics (e.g., residual chlorine and temperature) to a central server system via a bridge device and a corresponding mesh network. Mechanical energy from the water flowing through the water meter housing is converted to electrical energy via an energy conversion unit. An electrically powered shut off valve is remote addressable via the transceiver unit.

Abstract: A power generating bearing assembly (100) comprises a bearing subassembly (120) retained by a bearing housing (110). During operation, friction and other factors increase a temperature of the bearing assembly (100). The housing (110) can optionally include a bearing cooling passage system comprising at least one liquid cooling passage (134) formed internally therein. The liquid cooling passage (134) would be routed proximate the bearing subassembly (120) to remove heat therefrom. A thermal energy transfer media (204) is inserted into a thermal transfer conduit (180), wherein the thermal transfer conduit (180) passes across a heated section of the housing (110). The transfer media (204) conveys the thermal energy to a Thermo-Electric Generator (TEG) (200) located in a thermoelectric generator housing (250) attached to the bearing housing (110). The Thermo-Electric Generator (TEG) (200) utilizes a temperature difference between the transfer media (204) and the ambient air to generated electric power.

Abstract: An exemplary thermoelectric generator disclosed herein includes: a first electrode and a second electrode opposing each other; and a stacked body having a first end face and a second end face. The stacked body is structured so that first layers made of a first material and second layers made of a second material are alternately stacked, the first material containing a metal and particles having a lower thermal conductivity than that of the metal, the particles being dispersed in the metal, and the second material having a higher Seebeck coefficient and a lower thermal conductivity than those of the first material. Planes of stacking between the first layers and the second layers are inclined with respect to a direction in which the first electrode and the second electrode oppose each other.

Abstract: Thermoelectric devices are provided. In one embodiment, a thermoelectric device may include a glass wafer defined by conductive vias, a second wafer, and a plurality of metal film disposed between the glass wafer and the second wafer and against solid, conductive, integral, end surfaces of the conductive vias. A nanogap may be disposed between the metal film and the second wafer. The nanogap may have been created by applying a voltage extending between the conductive vias and the second wafer. Methods of forming the devices, along with methods of using the devices to transform heat energy to electricity, and for refrigeration, are also provided.

Abstract: A heat exchanger (9), of e.g. an exhaust gas system (5) for an internal combustion engine (1), includes a thermoelectric generator (12) having a hot side (13) and a cold side (14) and including a heating tube (15) on a hot side of a heating device (10), and a cooling tube (16) on a cold side of a cooling device (11). The heating tube and the cooling tube are stacked on one another and form a tube stack (18), with the heating tube and the cooling tube extending parallel to one another in a longitudinal direction (19) of the tube stack. For energy efficiency, a housing (21) of the heat exchanger has a jacket (23) with an integral re-tensioning section (25) that is resiliently adjustable between a relaxed state and a tensioned state. The pre-tensioning section generates a pre-tensioning force (26) pressing the tube stack in a stacking direction (17).

Abstract: A thermionic power generator includes an emitter generating thermions and a collector collecting the thermions. The emitter includes an emitter substrate having an electric conductivity, a low resistance layer stacked to the emitter substrate and made of an n-type diamond semiconductor that includes phosphorus as a donor, and an electron emission layer stacked to the low resistance layer and made of an n-type diamond semiconductor that includes nitrogen as a donor. The collector includes a collector substrate having an electric conductivity and is disposed opposite to the emitter via a clearance. The electron emission layer has a thickness equal to or less than 40 nm.

Abstract: The present invention provides a thermoelectric conversion material having a reduced thermal conductivity and having an improved figure of merit, and a method for producing the material. The thermoelectric conversion material has, as formed on a resin substrate having recesses, a thermoelectric semiconductor layer formed of a thermoelectric semiconductor material, wherein the resin substrate comprises one formed by curing a resin layer of a curable resin composition. The production method for the thermoelectric conversion material comprises a resin substrate formation step of transcribing a protruding structure from an original plate having the protruding structure onto a resin layer of a curable resin composition and curing the layer, and a film formation step of forming a thermoelectric semiconductor layer of a thermoelectric semiconductor material on the resin substrate.

Abstract: A gas oven has an oven muffle and a gas burner for said oven muffle. The gas oven has a thermogenerator for generating electrical energy during operation of the gas burner for the purpose of supplying electrical energy to an electrical functional unit, for example for supplying said electrical energy to a fan or a control of the gas oven. In this case, the thermogenerator is designed and arranged to be heated, and for heat to be introduced by the gas burner.

Abstract: An embedded optical element package module uses a thermocouple, which increases the optical output efficiency of an optical element, dissipates high-temperature heat generated by the optical element having high output to prevent degradation, converts waste heat into electrical energy, and supplies the electrical energy as a power source for the optical element to reutilize resources, thereby reducing the amount of power consumed by the optical element and minimizing costs.

Abstract: An apparatus comprising a structure and an energy harvesting device. The structure is configured to have a first portion and a second. The energy harvesting device is formed as part of the structure. The energy harvesting device is configured to generate an electrical current when a difference in temperature occurs between the first portion and the second portion.

Abstract: An annular semiconductor element for producing a thermoelectric module includes at least one groove extending in a radial direction from an internal circumferential face to an external circumferential face. An annular insulation material insulates n-doped and p-doped semiconductor elements and is accordingly disposed on a lateral face of the semiconductor elements. The insulation material has a slit which extends in the radial direction and divides the insulation material. A thermoelectric module and a method for manufacturing the thermoelectric module are also provided.

Abstract: A thermoelectric conversion device includes a stack in which a first perovskite dielectric film, which includes Sr and Ti and has a first bandgap, and a second perovskite dielectric film, which includes Sr and Ti and has a second bandgap smaller than the first bandgap, are stacked alternately, each of the first and second perovskite dielectric films being doped to have an electric conductivity, the first and the second perovskite dielectric films having respective compositions such that there appears a bandoffset of 0.54 eV in maximum between a conduction band of the first perovskite dielectric film and a conduction band of the second perovskite dielectric film.

Abstract: A method for making a thermoelectric microstructure includes: forming an insulating substrate; forming, on the substrate, a first assembly of conductor or semiconductor elements extending in parallel and in a first direction from first to second connection areas, and having a first Seebeck coefficient; forming, on the substrate, a second assembly of conductor or semiconductor elements electrically insulated from the first assembly and extending in parallel and in a second direction other than the first one, from the first to second connection areas, and having a second Seebeck coefficient other than the first one; providing, in the first and second connection areas, electric connection elements, each of which electrically connects at least one element of first and second assemblies; two conductor or semiconductor elements of a single assembly are separated in a predetermined direction by a predetermined average distance in the connection areas.

Abstract: The invention relates to a method for producing a thermoelectric component or at least a semifinished version thereof, in which at least one thermoelectric active material in dry powder form is introduced into at least some of the holes of a perforated template. It addresses the problem of specifying a method which can be conducted in a particularly economically viable manner. The problem is solved by virtue of the active material remaining in the holes of the template, and the template filled with active material becoming a constituent of the thermoelectric component produced.

Abstract: A thermal energy harvester and power conversion system employs a bleed air duct containing the flow of high temperature air from an engine. A lower temperature air source is included with an energy conversion device having a hot interface operably engaged to the bleed air duct and a cold interface operably engaged to the lower temperature air source. The energy conversion device generates electrical power from a thermal gradient between the bleed air duct and the lower temperature air source and the electrical power is routed to a power feeder.

Abstract: The present disclosure describes systems and methods to increase the speed of engine warm up by heating oil with a thermoelectric device and also to generate electricity using the same thermoelectric device, exploiting a temperature gradient between engine oil and exhaust gases. The disclosure describes a vehicle engine, comprising: an engine oil reservoir; an exhaust gas system; and a thermoelectric device having a hot side and a cold side and connected to a battery, wherein, the thermoelectric device is configured such that the hot side is thermally coupled to the exhaust gas system and the cold side is thermally coupled to the engine oil reservoir. A diverter valve and duct are provided in the exhaust gas system to selectively convey exhaust gases to the thermoelectric device located in or adjacent to the engine oil reservoir.

Abstract: Systems and methods are operable to generate electric power from heat. Embodiments employ one or more direct thermal electric converters that have at least a first recombination material having a first recombination rate, a second recombination material adjacent to the first recombination material and having a second recombination rate, wherein the second recombination rate is different from the first recombination rate, and a third recombination material adjacent to the second recombination material and having a third recombination rate substantially the same as the first recombination rate. Application of heat generates at least first charge carriers that migrate between the first recombination material and the second recombination material, and generates at least second charge carriers that migrate between the third recombination material and the second recombination material. The migration of the first charge carriers and the migration of the second charge carriers generates an electrical current.