Abstract: Apparatuses, methods, and systems are disclosed to use thermoelectric generating (TEG) devices to generate electricity from heat generated by a power cable. An apparatus includes multiple thermoelectric generating (TEG) devices. Each of the TEG devices has a first surface configured to be positioned in thermal communication with an outer surface of the power cable and a second surface configured to be positioned proximate to an ambient environment around the power cable. The apparatus also includes a set of terminals electrically coupled to the TEG devices. When a temperature differential exists between the first surface and the second surface, the TEG devices convert heat into electricity presented at the set of terminals.

Abstract: Systems for producing electrical energy from heat are disclosed. The system may include a carbon-nanotube based pathway along which heat from a source can be directed. An array of thermoelectric elements for generating electrical energy may be situated about a surface of the pathway to enhance the generation of electrical energy. A carbon nanotube-based, heat-dissipating member may be in thermal communication with the array of thermoelectric elements and operative to create a heat differential between the thermoelectric elements and the pathway by dissipating heat from the thermoelectric elements. The heat differential may allow the thermoelectric elements to generate the electrical energy. Methods for producing electrical energy are also disclosed.

Abstract: A thermoelectric module (10) has a plurality of series-connected thermoelectric elements which are arranged between a first module housing plate defining a high-temperature side and a second module housing plate defining a low-temperature side, wherein laterally beside the thermoelectric elements and towards the end faces of the module housing plates at least one elastic compensating element is provided, which exerts a lateral holding force on the thermoelectric elements and extends from one inner side of the opposed module housing plates to the other. Such thermoelectric module (10) is contained in a thermoelectric generator unit (100), with a generator housing (102) in which at least one elastic compensating element (20) and at least one thermoelectric module (10) are accommodated, wherein the generator housing (102) exerts a pretension on the thermoelectric module (10) via the elastic compensating element (20).

Abstract: The invention provides a thermoelectric conversion module, which can implement a high power generation capacity and high reliability of electric connection between thermoelectric conversion elements and meet various diameters and lengths of a tube as a heat source. The thermoelectric conversion module includes a straight-chain module unit. In the module unit, plural P-type elements and plural N-type elements, which are alternately arrayed, are electrically connected in series by a braided wire A and a braided wire B. The braided wire A connects one end surface of the P-type element and one end surface of the N-type element. The braided wire B connects the other end surface of the P-type element and the other end surface of the N-type element. The braided wire B is shorter than the braided wire A. The thermoelectric conversion module including only the module unit is spirally wound around a tube as a heat source.

Abstract: A thermoelectric module device with thin film elements is disclosed. A pillar structure with a hollow region is formed by stacking a plurality of thin-film type thermoelectric module elements, each including a plurality thin-film thermoelectric pairs arranged in a ring. An insulating and thermal conducting layer covers the inner sidewalls of the hollow region of the pillar structure and the outer sidewalls of the pillar structure. A cool source and a heat source are disposed in the hollow region or outer side of the pillar structure, respectively.

Abstract: There is provided an AMTEC (alkali metal thermal-electric converter) with a heat pipe and more particularly, to an AMTEC with a heat pipe minimized a heating part and a condensation part of the AMTEC and improved in efficiency of thermal to electric conversion through installing the heating and cooling heat pipes in the AMTEC, in which a metal fluid is heated by latent heat of an operating fluid of the heat pipe, instead of the heat conduction from a heat source, thereby reducing a temperature difference needed for heat transfer to vaporize the metal fluid even by a heat source of a lower temperature than a conventional heat source; improving a cooling performance in a condensation part to result in the high efficiency of thermal to electric conversion; using no additional driving components for driving the heat pipe.

Abstract: An exemplary heat-distribution sensor includes a base and a number of thermocouples. The base includes a spherical surface and defines a number of receiving holes in the spherical surface. Each thermocouple has a sensing end which is received in a corresponding receiving hole and is configured for sensing heat generated by sunlight rays impinging on the sensing end.

Abstract: An apparatus for generating electrical power from the waste heat generated by an internal combustion engine includes a first pipe wall through which a heated medium flows, a thermoelectric generator disposed exteriorly to the inner pipe wall, and a second pipe wall disposed exteriorly to the thermoelectric generator. The first pipe wall and the second pipe wall form at least a partially double-walled pipe. The first pipe wall saves as a high-temperature source. The second pipe wall serves as a low-temperature source.

Abstract: A thermoelectric piping apparatus and method for generating electricity as a byproduct of heat exchange. A thermoelectric coating can be applied on a tubular heat exchanger wall (e.g., a pipe) utilizing a thermoelectric coating process (e.g., spray-on coating) in order to capture waste heat from a heat source and generate an electrical energy. The thermoelectric coating can be a semiconductor material that can be applied to the tubular heat exchanger wall in a printed circuit format. The charge carriers with respect to the semiconductor material can be excited when heat flows through the thermoelectric coating which can be harvested to generate the electrical power. Wires can be attached to the thermoelectric coating to transmit the electrical energy generated as a byproduct of heat exchange to an electrical grid.

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: An exhaust system for generating power includes a conduit in communication with a first atmosphere having a first temperature and through which said first atmosphere can flow, the conduit having an inner surface exposed to said first atmosphere and an exterior surface exposed to a second atmosphere having a second temperature external to the conduit; a thermoelectric power generating assembly mounted to the exterior surface of the conduit, said power generating assembly responsive to a temperature difference between the first and second atmospheres for providing electrical power.

Abstract: Thermoelectric devices, intended for placement in the exhaust of a hydrocarbon fuelled combustion device and particularly suited for use in the exhaust gas stream of an internal combustion engine propelling a vehicle, are described. Exhaust gas passing through the device is in thermal communication with one side of a thermoelectric module while the other side of the thermoelectric module is in thermal communication with a lower temperature environment. The heat extracted from the exhaust gasses is converted to electrical energy by the thermoelectric module. The performance of the generator is enhanced by thermally coupling the hot and cold junctions of the thermoelectric modules to phase-change materials which transform at a temperature compatible with the preferred operating temperatures of the thermoelectric modules.

Abstract: In one embodiment, a vortex tube has a gas inlet port, a cold gas outlet port and a hot gas outlet port. A thermoelectric potential generator having hot gas inlet port coupled to the hot gas outlet port of the vortex tube, a cold gas inlet port coupled to the cold gas outlet port of the vortex tube, and a thermoelectric element coupled in heat conducting relationship between the cold gas inlet port and the hot gas inlet port to promote the flow of heat/cold through the thermoelectric element from the hot gas flowing into the hot gas inlet port to the cold gas flowing through the cold gas inlet port. In another, a compressed gas source, a thermoelectric element having first and second sides, and an expansion nozzle are coupled in series. The expansion nozzle is coupled between the compressed gas source and the first side. The thermoelectric element includes an electrical output port.

Abstract: A generator device for converting thermal energy to electric energy. A magnetic circuit includes at least a portion made of a magnetic material. A temperature-varying device varied the temperature in the portion made of the magnetic material alternately above and below a phase transition temperature of the magnetic material to thereby vary the reluctance of the magnetic circuit. A coil is arranged around the magnetic circuit, in which electric energy is induced in response to a varying magnetic flux in the magnetic circuit. A magnetic flux generator creates magnetic flux in the magnetic circuit. The temperature-varying device alternately passes hot and cold fluid by, or through holes in, the portion made of the magnetic material of the magnetic circuit in a single direction to thereby vary the temperature in the portion made of the magnetic material alternately above and below the phase transition temperature of the magnetic material.

Abstract: Disclosed is a turbulated arrangement of thermoelectric elements for utilizing waste heat generated from a turbine engine. The turbulated arrangement of thermoelectric elements is located within the turbine casing at a heat exhaust end of the turbine engine. The turbulated arrangement of thermoelectric elements convert heat exhaust generated from the turbine engine into electrical energy. In one embodiment, the electrical energy generated from the turbulated arrangement of thermoelectric elements can be used to power electrical components located about the turbine engine.

Abstract: A device and a method for producing electrical energy from an exhaust gas of an internal combustion engine include a generator with an exhaust gas inlet, an exhaust gas outlet and a heat exchange portion therebetween. The heat exchange portion includes a plurality of flow paths for the exhaust gas. The flow paths are at least partially surrounded by thermoelectric elements which are in thermally conductive communication with a cooling device on a side facing away from the flow path. A motor vehicle having the device or carrying out the method, is also provided.

Abstract: A thermoelectric device contains at least one module having a first carrier layer and a second carrier layer, an interspace disposed between the first carrier layer and the second carrier layer, and an electrical insulation layer disposed on each of the first carrier layer and on the second carrier layer toward the interspace. The thermoelectric device further has a plurality of p and n-doped semiconductor elements, which are arranged alternately in the interspace between the insulation layers and are alternately electrically connected to one another.

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: In the thermoelectric module composed of p- and n-conductive thermoelectric material legs which are connected to one another alternately via electrically conductive contacts, at least some of the electrically conductive contacts on the cold and/or the warm side of the thermoelectric module are formed between, or embedded into, the thermoelectric material legs composed of porous metallic materials.

Abstract: A thermoelectric conversion module includes a tubular element unit having a plurality of ring-like thermoelectric elements coaxially arranged with air as an insulator sandwiched inbetween. The ring-like thermoelectric element is covered approximately entirely with electrodes at its outer circumference surface and inner circumference surface, respectively, and generates electricity by temperature difference between the outer circumference surface and the inner circumference surface. A lead wire electrically connects the electrode covered on the outer circumference surface of one ring-like thermoelectric element among the plurality of ring-like thermoelectric elements to the electrode covered on the inner circumference surface of another ring-like thermoelectric element adjacent to the one ring-like thermoelectric element.

Abstract: In one exemplary embodiment, an assembly includes one or more thermoelectric modules, a compliant thermal interface, and a heat spreader. The compliant thermal interface is configured such that it may substantially conform against and intimately thermally contact an outer surface of a fluid conduit. The heat spreader is disposed generally between and thermally coupled to the compliant thermal interface and the one or more thermoelectric modules. The heat spreader may have greater flexibility than the one or more thermoelectric modules. The heat spreader may also have a thermal conductivity greater than the compliant thermal interface. The assembly may have sufficient flexibility to be circumferentially wrapped at least partially around a portion of the fluid conduit's outer surface, with the compliant thermal interface in substantial conformance against and in intimate thermal contact with the fluid conduit's outer surface portion.

Abstract: An apparatus includes a thermoelectric cooler having a first set of one or more metal electrodes, a second set of one or more metal electrodes, and one or more doped semiconductor members. Each member physically joins a corresponding one electrode of the first set to a corresponding one electrode of the second set. Each member has a cross-sectional area that increases along a path from the one metal electrode of the first set to the one metal electrode of the second set.

Abstract: A thermoelectric device at least includes a ring-shaped insulated substrate and plural sets of thermoelectric thin film material pair (TEP) disposed thereon. The ring-shaped insulated substrate has an inner rim, an outer rim and a first surface. The sets of TEP electrically connected to each other are disposed on the first surface of the ring-shaped insulated substrate. Each set of TEP includes a P-type and an N-type thermoelectric thin film elements (TEE) electrically connected to each other. Also, the N-type TEE of each set is electrically connected to the P-type TEE of the adjacent set of TEP. When a current flows through the sets of TEP along a direction parallel to the surfaces of P-type and N-type thermoelectric thin film elements, a temperature difference is generated between the inner rim and the outer rim of the ring-shaped insulated substrate.

Abstract: A thermoelectric generator that reduces the size of an entire exhaust apparatus for an internal combustion engine, while ensuring the amount of electric power generated by a thermoelectric generation element and the purging effect of a catalyst device. The thermoelectric generator includes a catalyst device, arranged in the exhaust passage, for purging exhaust. A thermoelectric generation element, which is arranged on the catalyst device, converts thermal energy of the exhaust passing through the exhaust passage to electric energy. The thermoelectric generation element is arranged at a downstream portion of the catalyst device with respect to the flow of the exhaust.

Abstract: The invention relates to a thermoelectric-based power generation system designed to be clamped onto the outer wall of a steam pipe or other heating pipe. The system can include a number of assemblies mounted on the sides of a pipe. Each assembly can include a hot block, an array of thermoelectric modules, and a cold block system. The hot block can create a thermal channel to the hot plates of the modules. The cold block can include a heat pipe onto which fins are attached.

Abstract: Representative configurations for improved thermoelectric power generation systems to improve and increase thermal efficiency are disclosed.

Abstract: Apparatus providing at least one thermoelectric device for pressurizing a liquefied gas container and methods employing same are disclosed. A thermoelectric device including a heating surface and a cooling surface is used for pressurizing a container by vaporizing liquefied gas within the container by transferring heat energy from a portion of the liquefied gas in contact with the cooling surface to another portion of the liquefied gas in contact with the heating surface of the thermoelectric device to convert some of the liquefied gas to a vapor state. Liquefied gas vapor and/or liquid phase may be supplied by disclosed apparatus and methods. The apparatus may also be used as a vapor pump or a liquid pump, or fluid pump. Methods of operation are also disclosed.

Abstract: A fuel reforming system comprises a fuel reformer and a thermoelectric device positioned in thermal communication with the fuel reformer. A method of generating electrical energy is also disclosed.

Abstract: A thermoelectric module with a simple structure with less breakage by thermal stress is provided. For this purpose, the thermoelectric module includes p-type and n-type thermoelectric elements (13, 14) which are alternately placed, and outer electrodes (15) and inner electrodes (16), which are alternately placed between the thermoelectric elements (13, 14), and at least part of at least either one of the outer electrode (15) or the inner electrode (16) has a shape approximately along an object which exchanges heat with the electrodes (15, 16). The inner electrodes (16) surround an object which exchanges heat with the electrodes (15, 16).

Abstract: A Seebeck effect thermal sensor is formed in an integrated fashion with a power-dissipating device such as a power MOSFET. The integrated device generates a temperature difference between a relatively cold peripheral area and a relatively warm central area, the temperature difference having a known relationship to electrical operating conditions of the device. A structure for a power MOSFET includes two side-by-side arrays of source/drain diffusions. The Seebeck sensor has warm junctions at the central area and cold junctions at the peripheral area, and generates an electrical output signal having a known relationship to the temperature difference between the peripheral and central areas to provide an indication of the electrical operating conditions of the device. One Seebeck sensor includes alternating metal and polysilicon traces, wherein the polysilicon traces lie between source and drain diffusions of a power MOSFET just as do active polysilicon gates.

Abstract: The invention involves systems and methods of providing energy to land-based telemetry devices wherein the energy storage and power conditioning system is comprised of an input power supply, an energy storage element, an output supply and a control system. The input power supply provides energy to the output power supply and charges the energy storage element. The energy storage element is comprised of one or more UltraCaps and supplies energy to the output power supply at times of peak need and when the primary energy source to the input power supply is removed. The control system adjusts the voltage supplied to the energy storage element by the input power supply according to changes in the ambient temperature to compensate for changes in the internal equivalent series resistance of the UltraCaps caused by the change in ambient temperature. The output power supply provides energy to the land-based telemetry device.

Abstract: A combined thermocouple and thermopile capable of producing multiple EMF signals. The combined thermocouple and thermopile construction is particularly adapted for use as an electric generator capable of producing multiple EMF signals and able to respond faster to changes to the presence or absence of a pilot or gas burner flame. The conductors of the thermopile are comprised of dissimilar metals joined at each end to form hot and cold thermocouple junctions. The thermopile may provide multiple EMF signals when a third wire lead is affixed to a cold junction between either end of the array. The array of thermocouples is formed in a circle and enclosed in a metal sleeve or jacket.

Abstract: An improved efficiency thermoelectric system is disclosed wherein convection is actively facilitated through a thermoelectric array. Thermoelectrics are commonly used for cooling and heating applications. Thermal power is convected through a thermoelectric array toward at least one side of the thermoelectric array, which leads to increased efficiency. Several different configurations are disclosed to provide convective thermal power transport, using a convective medium. In addition, a control system is disclosed which responds to one or more inputs to make adjustments to the thermoelectric system.

Abstract: An improved efficiency thermoelectric system operates the thermoelectric elements in the system in a non-steady state manner. The thermoelectric elements are powered for predefined periods of time to obtain increased efficiency. This benefit can be improved by also altering the resistance of the thermoelectric elements during the power-on period such that resistive heating is minimized.

Abstract: The present invention incorporates the generation of electricity with the vaporization of a cryogen such that all of the available heat is beneficially used. The heat is either converted to electricity thermoelectrically or the heat is absorbed by the cryogen to vaporize the cryogen into cryogenic vapor and to increase the internal energy of the energetic cryogenic vapor, which is capable of performing work.

Abstract: A device for generating electric power in a wellbore formed in an earth formation, the wellbore being provided with a conduit for passage of a stream of hydrocarbon fluid produced from the earth formation, the power generator comprising a mandrel adapted to be incorporated in the conduit, the mandrel being provided with a side pocket arranged to receive a thermoelectric power generator having a first wall in thermal contact with the stream of hydrocarbon fluid and a second wall in thermal contact with the earth formation surrounding the wellbore.

Abstract: An improved thermopile infrared sensor is provided wherein thermoelectric elements are formed on a single crystalline silicon substrate containing a cavity therein. The thermopile infrared sensor contains a first dielectric film covering the cavity, a plurality of n-type polycrystalline silicon layers formed on the first dielectric film, extending radially from the vicinity of a chip center, and metal film layers formed in contact with the n-type polycrystalline silicon layers, wherein hot junctions are formed at the chip central side and cold junctions are formed at the chip peripheral side of the n-type polycrystalline silicon layers, respectively, by contacting the n-type polycrystalline silicon layer and the metal film layer, and at least one series of thermoelectric elements is formed on the first dielectric film by connecting alternately and successively, by the metal film layer, the hot junction and cold junction of the neighboring n-type polycrystalline silicon layer.

Abstract: A honeycomb-shaped electric element includes a honeycomb-shaped structural body, the honeycomb-shaped structural body including crossing partition walls defining a number of through-holes arranged thereamong, the through-holes being arranged in at least three lines extending laterally substantially in the same direction, wherein partition wall portions of the through-boles in the at least three lines are made of at least an electrically conductive material and an insulating material such that the partition wall portions of the through-holes made of the electrically conductive material and those of the insulating material are so arranged that a current flow passage may be continuously formed in the same direction as the continuous lines extend.

Abstract: Electric power is generated downhole in a well using a thermoelectric device. A temperature gradient or differential .DELTA.T present in the well is applied to the thermoelectric device to produce a voltage potential across the output terminals of the device. The thermoelectric device includes a first thermocouple coupled to a heat source and a second thermocouple coupled to a heat sink source. The electric power generated by the thermoelectric device is used to recharge battery packs located downhole or to power electrical devices or systems.

Abstract: A thermoelectric battery is disclosed which uses pipes connected in series made from two different metallic materials. The pipes are connected in an alternating manner and exposed to sunlight to increase the temperature therein. Other parts of the pipes are connected to a cooler temperature such as water or the ground to produce a temperature differential suitable to produce a voltage potential. The thermoelectric battery is also used to supply power to a swinging pendulum in which two different ionic chemicals are mixed at a selected time to generate electrical power. The thermoelectric battery, connected through a pacemaker circuit, produces a magnetic field at predetermined periods equal to a multiple of the period of oscillation of the pendulum, the field acting to give the pendulum a push in order to keep the pendulum from stopping.

Abstract: A thermoelectric module having a high thermoelectric performance is shown and described. A flat thermoelectric module comprises a multi-layered body provided with a thermoelectric material layer having output take-out faces on two opposite sides, an electrode layer present on each output take-out faces, a metallic layer present on each electrode layer, and an electrical insulating outer layer covering the surface of the body. Adjacent layers are pressure-welded to be in close contact with each other. No solder is used in the construction of a module in accordance with the present invention, and it is therefore possible to improve the thermoelectric performance of the module by raising the operating temperature without being restricted by the melting point of solder.

Abstract: A subsea thermoelectric generator has a plurality of flat thermoelectric modules attached concentrically to the outside wall of an undersea line in which petroleum products extracted from a subsea drilling well circulate. The thermoelectric modules are disposed in flat-bottomed pans machined into the outside wall of the line. The pans are sealed by lids made of heat-conducting material and in thermal contact with the thermoelectric modules. Each lid defines, with the walls of the corresponding pan, a peripheral sealed chamber. The various chambers in the pans communicate with each other through passages provided in partitions that separate the pans and are filled with a soft (compliant), preferably non-heat-conducting, resin. At least one of the pans is provided with an orifice closed by a sealed deformable element.

Abstract: The present invention provides an AMTEC cell having a more robust power conductance path (conduction, radiation, convection, and latent heat transfer) from the heat input surface of the cell to the working fluid, evaporation surface, and SES. More particularly, one embodiment of the present invention includes collars, post and/or bridges extending between the SES support plate and the heat input surface. In another embodiment, a plurality of channels or conduits extend between the heat input surface and SES support plate. These embodiments simultaneously increase the thermal conductance path between the heat input surface of the cell and the evaporation surface as well as between the heat input surface of the cell and the SES, and enables superheating of the working fluid.

Abstract: The present invention relates to an electric generator, of the type including thermoelectric cells electrically attached and insulated between both walls of a duct separating a moving internal fluid and an external fluid having a temperature different from that of the internal fluid. The thermoelectric cells are positioned in such a way that their surfaces of thermal exchange are approximately perpendicular to the outflow direction of the internal fluid. The thermoelectric cells are positioned on both faces of a flared flange radailly clamped onto the duct. An electric generator having these features provides increased electrical power and greater depth operation.

Abstract: A thermoelectric radiator for generating a direct current while providing at least a portion of the necessary cooling is formed with a first and second plurality of interdigitated thermoelectric lamella which are electrically joined and are connected to the positive and negative portions of the electrical system. The result is direct current flow when a heated coolant is passed over the lamella.

Abstract: A thermo-electric power generating element has the structure that two kinds of metal sheets, or foils, which form a thermocouple combination are laminated together and alternately connected at one end and the other end so as to form a plurality of thermocouples connected in series. When hot junctions are held at a high temperature, a temperature gap along the thermal flux is generated in the sheets, or foils. Electromotive force at every thermocouple derived from the temperature gap is summed up to a voltage level effective for outputting electric power through takeoff leads. This power generator is useful for converting waste heat to electric power. When the thermocouple pile is made from corrugated sheets, or foils, electric power is outputted with high efficiency.

Abstract: A thermopile detector for a temperature measuring instrument physically and electrically configured to supply an output signal which indicates a target temperature substantially independent of the influence of ambient temperature changes. The detector is comprised of a plurality of interleaved and electrically opposing thermocouples on a common surface of a substrate wherein the interleaved thermocouples are comprised of active thermocouples having a high emissivity coating to increase their sensitivity to infrared radiation and blind compensating thermocouples having a low emissivity coating to minimize their sensitivity to infrared radiation.

Abstract: The invention encompasses a torus formed by heated and cooled junctions of dissimilar metals such as copper and nickel to generate a low voltage current and form an electrical path of greatly enhanced conductivity wherein a greater current flow may be induced to form a stronger magnetic field. Current at higher voltage may be incrementally removed by magnetic field arrangements to act as magnetic variable switches while at the same time the magnetic field is contained and current also flows through the torus.

Abstract: A thermoelectric conversion member formed by a thermoelectric conversion element has a split ring shaped transverse cross section. Electrodes are disposed on ring ends of the thermoelectric conversion member facing each other. A magnetic field generating unit generates a magnetic field in a direction perpendicular to the transverse cross-sectional plane of the thermoelectric conversion member. A heating unit for heating one side of an annular wall of the thermoelectric conversion member and a cooling unit provided on the opposite side of the annular wall of the thermoelectric conversion member produces a temperature gradient in a direction radially of the thermoelectric conversion member. Electric field is induced in the direction perpendicular to both directions of the magnetic field and the temperature gradient, that is in the circumferential direction of the ring of the thermoelectric conversion member under the Nernst effect, enabling an electric voltage to be taken out at the electrodes.

Abstract: A thermoelectric generator includes a plurality of thermoelectric junctions embedded in each of a pair of thermally conductive and electrically non-conductive layers, these layers being separated by a thermally and electrically non-conductive layer. The junctions are connected to form a thermopile. An absorbent layer is provided adjacent one of the thermally conductive layers. A liquid such as water is applied to the absorbent layer, so that evaporation of the liquid from the absorbent layer enhances the temperature differential between the two thermally conductive layers.