Abstract: An energy source for supplying an autonomous electrical load system with electrical energy includes a thermogenerator device configured to generate a thermoelectric voltage to be fed to the electrical load system. The thermogenerator device is under the influence of a temperature difference between a warmer first thermal coupling device and a colder second thermal coupling device. The energy source further includes a microfluidic cooling device having a heat-absorption region, a heat-emission region, and a closed microfluidic circulation system configured to circulate a fluid between the heat-absorption region and the heat-emission region. The heat-absorption region has a thermally conductive connection to the second thermal coupling device.

Abstract: A heat exchanger includes a first plate and a second plate connected to the first plate to define a duct between the first plate and the second plate. At least one elastic cooling fin is disposed inside the duct between the first plate and the second plate. The at least one elastic fin exerts a load on the first plate.

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: Inexpensive, lightweight, flexible heating and cooling panels with highly distributed thermoelectric elements are provided. A thermoelectric “string” is described that may be woven or assembled into a variety of insulating panels such as seat cushions, mattresses, pillows, blankets, ceiling tiles, office partitions, under-desk panels, electronic enclosures, building walls, refrigerator walls, and heat conversion panels. The string contains spaced thermoelectric elements which are thermally and electrically connected to lengths of braided, meshed, stranded, foamed, or otherwise expandable and compressible conductor. The elements and a portion of compacted conductor are mounted within the insulating panel On the outsides of the panel, the conductor is expanded to provide a very large surface area of contact with air or other medium for heat absorption on the cold side and for heat dissipation on the hot side.

Abstract: A solar powered generator (100) has thermoelectric elements adjacent to and below solar cells. Concentrated sunlight is provided. A heat sink (104), which can be variable in temperature or efficiency, is in contact with the cold junction (108) of the thermoelectric device (103). The thermal resistivity is designed in relation to the energy flux, whereby the thermoelectric device (103) develops a gradient of several hundred Kelvin. Preferably the solar cell comprises a high band gap energy semi-conductor. The generator (100) maintains relatively consistent efficiency over a range of cold junction (108) temperatures. The heat sink (104) can be a hot water system. High efficiencies are achieved using nanocomposite thermoelectric materials. Evenly but thinly dispersing the thermoelectric segments in a matrix of highly insulating material reduces the amount of material required for the segments without sacrificing performance.

Abstract: A thermoelectric generator has a heat conducting body that exchanges heat with the environment according to environmental temperature changes, a heat storing body, and a thermoelectric conversion unit and thermal resistance body arranged between the heat conducting body and the heat storing body. One end of the thermal resistance body and one end of the thermoelectric conversion unit are in contact with each other. The other end of the thermal resistance body is in contact with the heat conducting body, and the other end of the thermoelectric conversion unit is in contact with the heat storing body. The surface of the heat storing body is covered by a covering layer having certain heat insulation properties. The temperature difference generated between the heat conducting body and the heat storing body is utilized to extract electric energy from the thermoelectric conversion unit.

Abstract: A fluid heat exchanger has an impeller assembly with first and second impeller bodies mated together, each having a substantially circular shape and at least one opening therethrough. Impeller vanes extend transversely from the first impeller body and away from the second impeller body. Impeller vanes extend transversely from the second impeller body away from the first impeller body. A thermoelectric module is disposed between the first impeller body and the second impeller body. Heat sinks are connected to each side of the thermoelectric module and extend through at least one opening in the first and second impeller bodies, where the impeller vanes are configured to move a fluid through the heat sinks during rotation of the first and second impeller bodies. Electrically-conductive windings disposed in the impeller assembly are configured to deliver induced electric current to the one or more thermoelectric modules.

Abstract: A thermoelectric module includes a first insulated substrate having a first opposing surface, a second insulated substrate having a second opposing surface, the second opposing surface faces the first opposing surface, a plurality of electrodes formed on the first and second opposing surfaces, a plurality of thermoelectric transducers provided between the first insulated substrate and the second insulated substrate, the plurality of thermoelectric transducers electrically connected with one another in series and/or in parallel via each electrode, and a conducting circuit electrically connecting the plurality of electrodes with an external power source, wherein the first insulated substrate includes a substrate body having the first opposing surface and a projecting portion being formed continuously from the substrate body and extending in a direction that intersects the substrate body, and the projecting portion includes a fixing surface extending in the direction that intersects the substrate body.

Abstract: An exhaust gas manifold having thermoelectric devices in the exhaust manifold of a stirling engine is disclosed.

Abstract: A thermoelectric element includes at least one thermopair and a pn-junction. The thermopair has a first material with a positive Seebeck coefficient and a second material with a negative Seebeck coefficient. The first material is selectively contacted by way of a conductor with the p-side of the pn-junction, and the second material is selectively contacted by way of a conductor with the n-side of the pn-junction.

Abstract: A thermoelectric conversion element comprising a thermoelectric conversion section and electrodes, wherein the thermoelectric conversion section includes at least: a thermoelectric conversion material section or a thermoelectric conversion material layer which is formed of a thermoelectric conversion material; and a charge transport section or a charge transport layer which is formed of a charge transport material having at least both semiconducting electric conduction properties and metallic electric conduction properties.

Abstract: The invention provides for a nanostructure, or an array of such nanostructures, each comprising a rough surface, and a doped or undoped semiconductor. The nanostructure is an one-dimensional (1-D) nanostructure, such a nanowire, or a two-dimensional (2-D) nanostructure. The nanostructure can be placed between two electrodes and used for thermoelectric power generation or thermoelectric cooling.

Abstract: A thermoelectric tempering device having a plurality of thermoelectrically operating tempering elements, including a cold surface, which forms upon the supply of an electric current, on one side thereof, and a warm surface on the opposite side thereof, including air/heat exchange bodies affixed on both sides and accommodated in a respective air flow chamber, and ventilators effecting an air flow along the same. Simple adjustment and expansion possibilities are provided with a unit of the tempering device configured as a tempering module and constructed so that the air flow chambers are configured as flow channels surrounding the heat exchange bodies parallel to the flow direction laterally and on the cover side facing away from the tempering elements, the flow channels having an air intake opening and an air discharge opening, wherein the ventilator of the respective flow channel is disposed on an intake opening or on a discharge opening.

Abstract: Techniques are provided for enhancing electrical properties of semiconductor structures. At a semiconductor structure, a heterojunction interface is provided between two dissimilar materials such that a two-dimensional electron gas (2DEG) region is present in the vicinity of the heterojunction. Energy is added to the semiconductor structure such that electrons that are present in the 2DEG region are promoted from below the Fermi level to energy states sufficiently high that the electrons can escape the structure. Electrons are emitted from the semiconductor structure in response to adding the energy such that electrons escape the surface of the semiconductor structure.

Abstract: An integrated micro-combustion power generator converts hydrocarbon fuel into electricity. The integrated micro-scale power generator includes a micro-machined combustor adapted to convert hydrocarbon fuel into thermal energy and a micro-machined thermoelectric generator adapted to convert the thermal energy into electrical energy. The combustion reaction in the combustor flows in a path in a first plane while the thermal energy flows in a second plane in the generator; the second plane being nearly orthogonal or orthogonal to the first plane. The fuel handler in the combustor is adjacent and thermally isolated from the thermoelectric generator. The fuel handler may include a nozzle and gas flow switch, where the frequency of activation of the gas flow switch controls the amount of the fuel ejected from the nozzle.

Abstract: A thermoelectric conversion module includes a pair of heat transfer plates, p-type semiconductor blocks and n-type semiconductor blocks arranged between the heat transfer plates, and terminal electrodes formed respectively on inner surfaces of the heat transfer plates and connecting the semiconductor blocks in series. The heat transfer plates include holes reaching from an outer surface to the terminal electrodes, and grooves each formed between the terminal electrodes and communicating between the adjacent holes. If a disconnection occurs, for example, a pin of a tester is brought into contact with the terminal electrode via the hole to specify a disconnected portion, and the terminal electrodes are electrically connected by injecting conductive paste into the holes in the disconnected portion as well as the groove.

Abstract: A thermoelectric apparatus includes a first and a second assemblies, at least a first and a second heat conductors. The first assembly includes a first and a second substrates, and several first thermoelectric material sets disposed between the first and second substrates. The first substrate has at least a first through hole. The second assembly includes a third and a fourth substrates, and several second thermoelectric material sets disposed between the third and fourth substrates. The fourth substrate has at least a second through hole. Each of the first and second thermoelectric material sets has a p-type and an n-type thermoelectric element. The first and second heat conductors respectively penetrate the first and second through holes. Two ends of the first heat conductor respectively connect the second and fourth substrates, while two ends of the second heat conductor respectively connect the first and third substrates.

Abstract: A device has a passive cooling device having a surface, at least one active cooling device on the surface of the passive cooling device, and a thermal switch coupled to the passive cooling device, the switch having a first position that connects the active cooling device to a path of high thermal conductivity and a second position that connects the passive cooling device to the path of high thermal conductivity.

Abstract: A circuit assembly generally includes a circuit board and at least one electrical pathway configured to couple a thermoelectric module to the circuit board for use as a heat pump in the circuit assembly. The circuit board and the at least one electrical pathway form part of the thermoelectric module when the thermoelectric module is coupled to the circuit board via the at least one electrical pathway. The thermoelectric module, including the portion of the circuit board forming part of the thermoelectric module, defines a footprint that is smaller than a footprint of the circuit board. As such, the circuit board is capable of supporting electrical components on the circuit board in a position outside the footprint defined by the thermoelectric module.

Abstract: The disclosure provides a thermoelectric conversion structure and its use in heat dissipation device. The thermoelectric conversion structure includes a thermoelectric element, a first electrode and an electrically conductive heat-blocking layer. The thermoelectric element includes a first end and a second end opposite to each other. The first electrode is located at the first end of the thermoelectric element. The electrically conductive heat-blocking layer is between the thermoelectric element and the first electrode.

Abstract: A solar power source is a multi-layer structure consisting of photovoltaic and quantum well thermoelectric modules in electrical contact with, but thermally insulating from, each other. The structure generates power when focused solar energy is directed at the photovoltaic module which generates power, heats up, and subsequently generates a thermal gradient in the thermoelectric module which generates additional power. The thermoelectric module may generate additional electrical energy using the Seebeck effect, or may cool the photovoltaic module using the Peltier effect.

Abstract: A thermoelectric device includes a thermoelectric element module arranged such that the vertically upper side is the cooling side and the vertically lower side is the heating side. On the cooling side of the thermoelectric element module, a DC-DC converter, a cooler, and a heat-transfer grease layer are arranged in this order from the vertically upper side.

Abstract: In a power electronics system of a next generation vehicle, a power module is provided including a thermoelectric device which is provided in a thermally conductive path between a power device and a cooling plate such that the thermoelectric device creates useful electric power from the waste heat of the power device.

Abstract: An integrated micro-scale power converter converts hydrocarbon fuel into electricity. The integrated micro-scale power converter includes a micromachined combustor adapted to convert hydrocarbon fuel into thermal energy and a micromachined thermoelectric generator adapted to convert the thermal energy into electrical energy. The combustion reaction in the combustor flows in a path in a first plane while the thermal energy flows in a second plane in the generator the second plane being nearly orthogonal or orthogonal to the first plane. The fuel handler in the combustor is adjacent and thermally isolated from the thermoelectric generator. The fuel handler may include a nozzle and gas flow switch, where the frequency of activation of the gas flow switch controls the amount of the fuel ejected from the nozzle.

Abstract: A circuit board with an embedded thermoelectric device with hard thermal bonds. A method of embedding a thermoelectric device in a circuit board and forming hard thermal bonds.

Abstract: A thermoelectric system is provided which includes at least one tubular conduit configured to be in thermal communication with at least one first fluid flowing through the at least one tubular coolant conduit in a first direction. A plurality of thermoelectric elements can be in thermal communication with the at least one tubular conduit. A heat exchanger in thermal communication with the plurality of thermoelectric elements is configured to be in thermal communication with at least one second fluid and to surround at least a portion of the tubular conduit and plurality of thermoelectric elements. The heat exchanger can include at least one coating configured to catalyze reactions of at least one portion of the second fluid.

Abstract: A system for adaptive cooling and energy harvesting comprising at least one thermoelectric device capable of acting as a thermoelectric cooler and as a thermoelectric generator, a hierarchical multiple-level control system, and electronics controlled by the control system and connected to the thermoelectric device. The electronics selectively configure the thermoelectric device in at least in a thermoelectric cooler operating mode and in a thermoelectric generation operating mode. The thermoelectric device can incorporate quantum-process and quantum-well materials for higher heat transfer and thermoelectric generation efficiencies. The invention provides for thermoelectric devices to additionally operate in temperature sensing mode. The hierarchical control system can comprise a plurality of control system, each of which can operate in isolation and can be interconnected with additional subsystems associated with other hierarchical levels.

Abstract: A thermoelectric structure including a thermoelectric material having a thickness less than 50 nm and a semi-insulating material in electrical contact with the thermoelectric material. The thermoelectric material and the semi-insulating materials have an equilibrium Fermi level, across a junction between the thermoelectric material and the semi-insulating material, which exists in a conduction band or a valence band of the thermoelectric material. The thermoelectric structure is for thermoelectric cooling and thermoelectric power generation.

Abstract: A thermoelectric conversion module which has a P-type thermoelectric conversion material and an N-type thermoelectric conversion material electrically connected to each other. The P-type thermoelectric conversion material and the N-type thermoelectric conversion material are joined with insulating material particles (ceramic spherical particles) interposed therebetween, so as not to be electrically connected to each other.

Abstract: In one embodiment, a thermoelectric device includes a plurality of thermoelectric elements arranged in a substantially polygonal pattern. The substantially polygonal pattern has more than four sides. The device includes a first dielectric plate coupled to the thermoelectric elements and a second dielectric plate coupled to the thermoelectric elements. The device also includes a first set of fins coupled to the first dielectric plate and a second set of fins coupled to the second dielectric plate.

Abstract: A thermoelectric element includes at least one thermopair and a pn-junction. The thermopair has a first material with a positive Seebeck coefficient and a second material with a negative Seebeck coefficient. The first material is selectively contacted by way of a conductor with the p-side of the pn-junction, and the second material is selectively contacted by way of a conductor with the n-side of the pn-junction.

Abstract: According to a first aspect, the invention relates to a TEG module, in particular for a power source (10), comprising a space (14) at least partially delimited by walls (16), at least one thermoelectric generator (20) for the conversion of heat into electricity, in which at least one electrically insulated wall part is in thermally conducting contact with a first side (52) of the thermo-electric generator (20), and the second side (54) is in heat-exchanging connection with an electrically insulated discharge element (12) for discharging heat used by the thermoelectric generator, as well as electrical conductors connected to the first and second side respectively (52, 54) for the conduction of generated electricity, with thermally conducting pressure means for applying pressure to the said second side being provided between the second side (54) and the discharge element (12), the said means comprises a thermally conducting flexible container (50), which is filled with a pressure medium in a state of over-press

Abstract: Systems and methods for converting engine heat energy to electricity using a thermoelectric conversion device are provided herein. One example system may include an engine heat source, a thermoelectric conversion device for converting heat into electricity, and a heat pipe. The heat pipe is positioned so that when the temperature of the engine exhaust is too high, the excess heat may be transferred away from the thermoelectric conversion device to the heat sink via the heat pipe.

Abstract: A semiconductor structure is provided that can be used for cooling, heating, and power generation. A first region of the semiconductor structure has a first length and comprises a first semiconductor material doped at a first concentration with a first dopant. A second region is disposed adjacent to the first region so as to define a first interface, has a second length which is longer than the first length, and comprises a second semiconductor material doped at a second concentration with a second dopant. At least one of the first material, second material, first concentration, second concentration, first length, second length, first dopant, and second dopant is selected to create, at the first interface, a forward electrical potential step having a barrier height dependent at least in part on an average temperature (T) of the semiconductor structure, e.g., a range of approximately 3-10 ?BT, where ?B is the Boltzmann constant.

Abstract: A system and method for generating electrical power from a heat source utilizing both photonic and thermal conversion are disclosed. Specifically, power is generated by coupling photon converters to thermoelectric pairs in a way such that the thermoelectric pairs gain not only the charge carriers (holes and electrons) generated by the photons absorbed by the photon converters, but also the charge carriers generated by excess heat in the photon converters and an added thermal gradient generated by excess energy in the absorbed photons. Heat exchanger variations for such a system are also disclosed. Specifically, heat exchangers with and without photon emitters are disclosed and variants of refractive indices for heat exchanger systems are disclosed.

Abstract: A thermoelectric device is provided. The thermoelectric device includes a P-type thermoelectric component, an N-type thermoelectric component, and an electrically conductive layer. Each of the P-type thermoelectric component and the N-type thermoelectric component includes a substrate and a nanowire structure. The conductive layer connects the P-type thermoelectric component set with the N-type thermoelectric component set. The thermoelectric device is adapted for recycling heat generated by the heat source, and for effectively converting the heat into electrical energy.

Abstract: A method of controlling engine exhaust flow through at least one of an exhaust bypass and a thermoelectric device via a bypass valve is provided. The method includes: determining a mass flow of exhaust exiting an engine; determining a desired exhaust pressure based on the mass flow of exhaust; comparing the desired exhaust pressure to a determined exhaust pressure; and determining a bypass valve control value based on the comparing, wherein the bypass valve control value is used to control the bypass valve.

Abstract: The invention relates to a light emitting diode (LED) which is electrically connected to an anode and a source. According to the invention one of the anode and the source is thermally coupled to a first heat conductor, the heat conductor being thermally coupled to a first Peltier element to convert thermal energy transmitted from and generated in the light emitting crystal when the light emitting crystal is provided with electrical energy into electrical energy.

Abstract: A method of forming a thermoelectric device may include providing a substrate having a surface, and thermally coupling a thermoelectric p-n couple to a first portion of the surface of a substrate. Moreover, the thermoelectric p-n couple may include a p-type thermoelectric element and an n-type thermoelectric element. In addition, a thermally conductive field layer may be formed on a second portion of the surface of the substrate adjacent the first portion of the surface of the substrate. Related structures are also discussed.

Abstract: A current source and method of producing the current source are provided. The current source includes a metal source, a buffer layer, a filter and a collector. An electrical connection is provided to the metal layer and semiconductor layer and a magnetic field applier may be also provided. The source metal has localized states at a bottom of the conduction band and probability amplification. The interaction of the various layers produces a spontaneous current. The movement of charge across the current source produces a voltage, which rises until a balancing reverse current appears. If a load is connected to the current source, current flows through the load and power is dissipated. The energy for this comes from the thermal energy in the current source, and the device gets cooler.

Abstract: The invention is directed to a thermoelectric module that utilizes a glass-ceramic material in place of the alumina and aluminum nitride that are commonly used in such modules. The glass-ceramic has a coefficient of thermal expansion of <10×10?7/° C. The p- and n-type thermoelectric materials can be any type of such materials that can withstand an operating environment of up to 1000° C., and they should have a CTE comparable to that of the glass-ceramic. The module of the invention is used to convert the energy wasted in the exhaust heat of hydrocarbon fueled engines to electrical power.

Abstract: The thermoelectric device of the present invention includes a first electrode and a second electrode that are disposed to be opposed to each other, and a laminate that is interposed between the first electrode and the second electrode, is connected electrically to both the first electrode and the second electrode, and is layered in the direction orthogonal to an electromotive-force extracting direction, which is the direction in which the first electrode and the second electrode are opposed to each other.

Abstract: A thermoelectric module has a first substrate, a second substrate spaced from the first substrate, a plurality of P type thermoelectric elements and N type thermoelectric elements arranged in the space between the first and second substrates, and a plurality of electrodes which connect the P type and N type thermoelectric elements in series. Each electrode is connected to a respective one of the plurality of P type thermoelectric elements at a first connection and a respective one of the plurality of N type thermoelectric elements in the space, and a sealant is located at an edge portion of the space. Each one of a series of first or outer electrodes closest to the edge portion of the space has a concave portion that is concaved in a direction departing from the edge portion of the space and is at a position between the first connection and the second connection.

Abstract: Heat transfer to refrigerate or heat uses a thermoelectric semiconductor structure including a P-type composite of dices of semiconductor material alloyed with P-type material forming spaced collector regions at junctions with a P-type conductive material for flux of electrical current and a N-type composite of dices of semiconductor material alloyed with N-type material forming spaced collector regions at junctions with a N-type conductive material for flux of electrical current. The thickness of each the dices is sufficient to form a PN junction. Electrically conductive buss bars form an electrical circuit between the dices of N-type conductivity and the dices of P-type conductivity. An electrically conductive buss bar forms an electrical circuit connection between the dices of N-type conductivity and the dices of P-type conductivity. An electrical potential is applied by terminals between the P-type composite and the N-type composite to induce a flux of heat concurrent with the flux of electrical current.

Abstract: Some embodiments provide a waste heat recovery apparatus including an exhaust tube having a cylindrical outer shell configured to contain a flow of exhaust fluid; a first heat exchanger extending through a first region of the exhaust tube, the first heat exchanger in thermal communication with the cylindrical outer shell; a second region of the exhaust tube extending through the exhaust tube, the second region having a low exhaust fluid pressure drop; an exhaust valve operatively disposed within the second region and configured to allow exhaust fluid to flow through the second region only when a flow rate of the exhaust fluid becomes great enough to result in back pressure beyond an allowable limit; and a plurality of thermoelectric elements in thermal communication with an outer surface of the outer shell.

Abstract: A thermoelectric tempering device having a plurality of thermoelectrically operating tempering elements, including a cold surface, which forms upon the supply of an electric current, on one side thereof, and a warm surface on the opposite side thereof, including air/heat exchange bodies affixed on both sides and accommodated in a respective air flow chamber, and ventilators effecting an air flow along the same. Simple adjustment and expansion possibilities are provided with a unit of the tempering device configured as a tempering module and constructed so that the air flow chambers are configured as flow channels surrounding the heat exchange bodies parallel to the flow direction laterally and on the cover side facing away from the tempering elements, the flow channels having an air intake opening and an air discharge opening, wherein the ventilator of the respective flow channel is disposed on an intake opening or on a discharge opening.

Abstract: Thermoelectric solar panel used to generate electrical power from solar power has a front part with a solar power collector panel, a middle part with a plurality of Seebeck-type thermoelectric generator modules, and a rear part with a cooling element. The parts are joined together under pressure by an appropriate fixing mechanism. This provides numerous advantages over equivalent devices that are currently available, the most important of them being that the collector surface or visible face of the panel may be made of practically any architectural material, it being capable of being built directly into the structure of a building, both in roofs and facades.

Abstract: A thermal transfer device having a first substrate layer, a second substrate layer and first and second electrodes disposed between the first substrate layer and the second substrate layer. The thermal transfer device also includes a release layer disposed between the first electrode and the second electrode and an actuator disposed adjacent the first and second electrodes. The actuator is adapted to separate the first and second electrodes from the release layer to open a thermotunneling gap between the first and second electrodes, and wherein the actuator is adapted to actively control the thermotunneling gap.

Abstract: A heating, ventilating and air conditioning (HVAC) system for a hybrid vehicle is disclosed, the HVAC system including at least one thermoelectric device for providing supplemental heating and cooling for air supplied to a passenger compartment of the vehicle. In some embodiments, the HVAC system has at least a first circuit and a second circuit. The first circuit can be configured to remove heat from an electric side of a hybrid vehicle. The second circuit can be configured to remove heat from a fuel-fed side of a hybrid vehicle.

Abstract: When electric power is obtained from a thermoelectric element, a value of electric current is changed, and two combinations of the electric current value and a voltage value (i1, V1) and (i2 and V2) are obtained. An electric current value it at which the maximum electric power Wmax can be obtained is obtained using an electric current-voltage characteristic estimated based on the obtained two combinations of the electric current value and the voltage value. The electric current is controlled such that the value of the electric current becomes equal to the obtained value it when the electric power is obtained from the thermoelectric element. The value it is represented by an equation, it=(i2V1?i1V2)/2(V1?V2).