Abstract: In one embodiment, a method for forming a metallized ceramic includes thermal spraying metal directly onto a first side of a ceramic plate. The metal comprising aluminum. The method also includes densifying the thermally ceramic plate after spraying the metal onto the first side of the ceramic plate.

Abstract: The invention relates to a solar module attachment, comprising a Z-support (2), the one Z-side (2.1) of which is used directly as a roof attachment or can be connected to roof hooks or support posts in the case of a mounting system, while clamps (5) can be displaced over the other Z-side (2.2), the attachment means engaging in said clamps in order to fix solar module frames (1).

Abstract: A method includes collecting site specific data, collecting field data at a site of an array of photovoltaic members, determining a current tracked irradiance of the array of photovoltaic members, calculating predicted irradiance for multiple orientations based on the site specific data and the sensed field data, or sensing an actual irradiance for multiple orientations. The method further includes determining a maximum predicted irradiance from the calculated predicted irradiance or a maximum actual irradiance from the sensed irradiance. The method further includes comparing the maximum predicted irradiance or the maximum sensed irradiance with the current tracked irradiance, and re-orienting the array of photovoltaic members to an orientation having the maximum predicted or actual irradiance if the maximum predicted or actual irradiance is greater than the current tracked irradiance.

Abstract: A thermoelectric converter is formed by a plenum divided into high and low pressure chambers by a partition and includes a stack of series-coupled alkali-metal thermoelectric cells that projects orthogonally from the partition into one of the chambers.

Abstract: A method for forming a thin film photovoltaic material. The method includes providing a plurality of substrates. Each of the substrates has a surface region, an overlying first electrode material, an absorber material including at least a copper species, an indium species, and a selenium species. The method immerses the plurality of substrates in an aqueous solution including an ammonia species, a cadmium species, and a organosulfur (for example, thiourea) species in a bath to form a cadmium sulfide window material having a thickness of less than about 200 Angstroms overlying the absorber material. The aqueous solution is maintained at a temperature ranging from about 50 to about 60 Degrees Celsius. The plurality of substrates having at least the absorber material and the window layer are removed from the aqueous solution. The aqueous solution is further subjected to a filter process to substantially remove one or more particles greater than about 5 microns.

Abstract: The present invention relates to a thermoelectric device, in particular an all-organic thermoelectric device, and to an array of such thermoelectric devices. Furthermore, the present invention relates to a method of manufacturing a thermoelectric device, in particular an all-organic thermoelectric device. Moreover, the present invention relates to uses of the thermoelectric device and/or the array in accordance with the present invention.

Abstract: A thermoelectric conversion device includes a first board, a second board, which is arranged to face the first board, and thermoelectric elements. One end of each thermoelectric element is joined to a first electrode layer on the first board, and the other end is joined to a second electrode layer on the second board. The thermoelectric conversion device includes reinforcing members. One end of each reinforcing members joined to the first insulating plate, and the other end is joined a second insulating plate. In the thermoelectric conversion device, the coefficient of linear expansion of the reinforcing members is greater than the coefficient of linear expansion of the thermoelectric elements.

Abstract: A thermoelectric energy harvesting system may include a thermoelectric generator and an electronics module. The thermoelectric generator may produce a voltage in response to a temperature difference across the thermoelectric generator and generate power when coupled to a load. The system may include a housing mounted on top of the thermoelectric generator. The housing may include a cavity containing the electronics module. The electronics module may condition the power generated by the thermoelectric generator. The cavity may be enclosed by an inner surface of the housing. A radiation shield may cover at least a portion of the inner surface and may block radiative heating of the cavity from the housing.

Abstract: An electric power generation device equipped with an apparatus which vibrates and generates heat includes a thermoelectric power generation module and a piezoelectric power generation module which are formed integrally. The thermoelectric power generation module has a first surface combining thermally and mechanically with the apparatus's outer surface and a second surface opposite to the first surface, and generates electric power from temperature differences between the first surface and the second surface caused by the apparatus's generating heat. The piezoelectric power generation module has a fixed end combining mechanically with the apparatus's outer surface and a movable end opposite to the fixed end, and generates electric power from displacement of the movable end to the fixed end caused by the apparatus's vibrating.

Abstract: A power converter is provided and includes a heat collector surface, n- and p-legs formed of n- and p-type thermoelectric materials, respectively, which are each disposed in thermal communication with the heat collector surface, parallel electric busses electrically coupled to the n- and p-legs and a housing, which is electrically decoupled from the busses, to support the heat collector surface at a predefined distance from a heat pipe.

Abstract: Disclosed is a thermoelectric module, including: a first substrate; a plurality of thermoelectric elements arranged on a first surface of the first substrate; and a temperature detector disposed on the first surface or a second surface of the first substrate via a thermal transfer member.

Abstract: Provided is a high-voltage electrical component unit for vehicles, including: an electrical storage device; a power control block disposed above the electrical storage device for controlling input-output power of the electrical storage device; and a power distribution block disposed across both side portions of the electrical storage device and the power control block for electrically connecting the electrical storage device and the power control block, the electrical storage device, the power control block and the power distribution block being fastened to one another, wherein a temporarily fastening section is provided at a separately-provided conductive functional component which electrically connects a connection terminal of the power distribution block and a connection terminal of the power control block, the temporarily fastening section engaging to both the power control block and the power distribution block to hold relative positions thereof.

Abstract: Energy harvesting devices, wherein one illustrative embodiment includes a crease beam, a thermoelectric element disposed in thermally-conductive contact with the crease beam and a heat exchanger disposed in thermally-conductive contact with the thermoelectric element. An energy harvesting system and a method of harvesting electrical power are also disclosed.

Abstract: Disclosed is an article having: a porous thermally insulating material, an electrically conductive coating on the thermally insulating material, and a thermoelectric coating on the electrically conductive coating. Also disclosed is a method of forming an article by: providing a porous thermally insulating material, coating an electrically conductive coating on the thermally insulating material, and coating a thermoelectric coating on the electrically conductive coating. The articles may be useful in thermoelectric devices.

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: A thermoelectric conversion module includes: a first substrate having water permeability and thermal conductivity; a thermoelectric conversion element provided on the first substrate; a heat insulator having water permeability provided around the thermoelectric conversion element on the first substrate; and a second substrate disposed on the thermoelectric conversion element and the heat insulator and having water permeability and thermal conductivity.

Abstract: An example thermoelectric module generally includes a first laminate having a dielectric layer and an electrically conductive layer coupled to the dielectric layer, a second laminate having a dielectric layer and an electrically conductive layer coupled to the dielectric layer, and thermoelectric elements disposed generally between the first and second laminates. At least one of the dielectric layers is a polymeric dielectric layer. The electrically conductive layers of the first and second laminates are at least partially removed to form electrically conductive pads on the respective first and second laminates. The thermoelectric elements are coupled to the electrically conductive pads of the first and second laminates for electrically coupling the thermoelectric elements together.

Abstract: A thermoelectric module includes a first and a second substrates, plural thermoelectric elements, plural first and second metal electrodes, plural first and second solder layers, and spacers. The thermoelectric elements are disposed between the first and second substrates, and each pair includes a P-type and an N-type thermoelectric elements. An N-type thermoelectric element is electrically connected to the other P-type thermoelectric element of the adjacent pair of thermoelectric element by the second metal electrode. The first metal electrodes and the lower end surfaces of the P/N type thermoelectric elements are jointed by the first solder layers. The second metal electrodes and the upper end surfaces of the P/N type thermoelectric elements are jointed by the second solder layers. The spacers are positioned at one of the first and second solder layers. The melting point of the spacer is higher than the liquidus temperatures of the first and second solder layers.

Abstract: A wrapped thermoelectric power source having an inner and an outer insulator is provided within a housing formed, at least partially, by an upper and lower thermal transfer elements. The thermoelectric power source including a plurality of coupled pairs of thin film materials possessing thermoelectric properties, the pairs disposed on a flexible substrate and electrically coupled in any series/parallel combination, with the flexible substrate wrapped around an inner thermal insulator. The thermoelectric power source may be sized such that at least a portion of an electronics module may be disposed at least partly within the inner thermal insulator. The electronics module is electrically coupled to the thermoelectric power source, and includes components for voltage regulation and/or power conditioning.

Abstract: A thermoelectric generator assembly includes a thermoelectric generator with hot and cold junction flanges. The hot junction flange includes an adapter shaped for thermally coupling to a process vessel. The thermoelectric generator producing a thermoelectric power output. A heat sink thermally couples to ambient air and has a heat sink flange. A heat pipe assembly includes fluid in a circulation chamber. The circulation chamber has an evaporator flange mounted to the cold junction flange and a condenser flange mounted to the heat sink flange. At least a portion of the fluid transports heat from the evaporator flange to the condenser flange. When a heat pipe assembly on a cold junction flange is used with many of the types of heat flows that are available in process industries, more efficient thermoelectric power generation can be provided in the process industries.

Abstract: A thermoelectric conversion device includes a hot terminal substrate, a cold terminal substrate and a stacked structure. The stacked structure is disposed between the hot terminal substrate and the cold terminal substrate. The stacked structure includes thermoelectric conversion layers each including a thermoelectric couple layer, a first conductive layer and a second conductive layer, a first heat-conductive and electrically insulating structure and a second heat-conductive and electrically insulating structure. Each of the thermoelectric conversion layers is arranged in the stacked structure. The first conductive layer includes first conductive materials and is arranged on tops of P/N type thermoelectric conversion elements. The second conductive layer includes second conductive materials and is arranged on bottoms of the P/N type thermoelectric conversion elements. The first heat-conductive and electrically insulating structure is connected between two adjacent first conductive layers.

Abstract: An improved circular multi-element semiconductor thermoelectric hybrid utilizes a make-before-break high frequency switching output component to provide nominal alternating current voltage outputs. Overall efficiency of heat conversion is improved by coupling a chiller to the thermoelectric generator where exhaust heat produces chilled liquid or air that is conveyed to the cold side of the thermoelectric device. The thermoelectric generator is used in a variety of transportation vehicles including manufactured vehicles, retrofitted vehicles and vehicle power combinations.

Abstract: In a thermoelectric generator (30) a layer (48) of a phase change material is introduced between a pipe (32), which conducts an offgas, and at least one thermoelectric module (40). This phase change material layer stores excess heat QE at excessively high offgas temperatures and thus protects the thermoelectric modules (40) and at the same time keeps the thermoelectric generator (30) at a constant temperature level, thus improving the efficiency thereof.

Abstract: A thermoelectric power generation apparatus includes a thermoelectric device having a first surface, an opposed second surface, and a first thermal energy storage unit operatively coupled to the first surface of the thermoelectric device setting the first surface at a first temperature. The thermoelectric power generation apparatus also includes a second thermal energy storage unit having a second temperature, the second thermal energy unit for setting the second surface of the thermoelectric device at an operative temperature in response to a temperature difference between the first temperature of the first surface and the second temperature of the second thermal energy storage unit. The thermoelectric device generates power in response to a temperature differential between the first temperature of the first surface and the operative temperature of the second surface.

Abstract: The invention relates to a device for thermal adaptation, comprising at least one surface element arranged to assume a determined thermal distribution, said surface element comprising a first heat conducting layer, a second heat conducting layer, said first and second heat conducting layers being mutually thermally isolated by means of an intermediate insulation layer, wherein at least one thermoelectric element is arranged to generate a predetermined temperature gradient to a portion of said first layer. The invention also relates to an object such as a craft.

Abstract: The present invention according to one preferred embodiment provides a thermoelectric element device comprising a first electrode including an electrode member, an elastic member that has electrically conductive and is provided on the electrode member, and a heat uniforming member that has electrically conductive and is provided on the elastic member; a thermoelectric element that is made of a thermoelectric material having thermoelectric effect and arranged on the first electrode so as to contact the heat uniforming member; and a second electrode arranged on the thermoelectric element.

Abstract: A thermocouple having at least one inner alignment feature or at least one outer alignment feature, or a combination thereof for positively positioning and aligning at least one thermocouple junction within a bore formed in a susceptor ring of a semiconductor substrate processing reactor. The outer alignment feature is configured to positively align the junction(s) longitudinally within the bore. The inner alignment feature configured to positively position the junction(s) rotationally within the sheath of the thermocouple relative to the bore.

Abstract: A unit thermionic electric converter. The unit thermionic electric converter includes a case having a first end portion and a second end portion; a working fluid disposed inside the case; a solid electrolyte dividing the inside of the case; a first electrode disposed on a surface of the solid electrolyte; and a second electrode disposed on another surface of the solid electrolyte; wherein the first end portion and the second end portion are alternately heated by a heat source.

Abstract: In one aspect, the present invention relates to a thermocouple device comprising a flexible non-planar substrate, a first printed thermocouple element comprising a first metal containing ink composition applied to the flexible non-planar substrate, and a second printed thermocouple element in electrical contact with the first printed thermocouple element making a thermocouple junction. The second printed thermocouple element comprises a second metal containing ink composition with a Seebeck coefficient sufficiently different from the first metal containing ink composition for the first and second printed thermocouple elements to together produce a thermocouple effect. The present application further relates to medical devices comprising the thermocouple and methods of making such devices.

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: One embodiment of the present subject matter includes an apparatus with a first housing portion which is thermally conductive and which has a first case opening; a second housing portion which is thermally conductive and which has a second case opening, the second case opening being hermetically sealed to the first case opening, with the first housing portion and the second housing portion at least partially defining an interior volume; cardiac rhythm management electronics disposed in the interior volume; a thermal shunt disposed in the interior volume; and a thermoelectric energy converter disposed in the interior volume and adjacent the thermal shunt, the thermoelectric energy converter having a first pole and a second pole, with the first pole thermally connected to the first housing portion, and the second pole thermally connected to the shunt.

Abstract: A thermocouple mounting assembly is provided. A plurality of retainers includes portions that are interengageable, some portions carried by a body and some portions carried by a thermocouple assembly to effect releasable mounting of a thermocouple assembly to a body. The retainers are constructed and shaped to provide for their formation by a molding process such as die-casting or investment casting, eliminating or substantially eliminating the need for machining of the retainer components. Preferably, there is an audible sound, e.g., click, present to signify when the retainers are interengaged.

Abstract: In various embodiments of the present invention, a thermoelectric device is provided. The thermoelectric device includes one or more thermoelements that transfer heat across the ends of the thermoelectric device. A method for creating the thermoelectric device includes forming a metal substrate, and etching one or more surfaces of the metal substrate to form etched portions. The unetched flat portions on the metal substrate are referred to as mesa cores. Thereafter, thermoelectric films are deposited on the one or more surfaces of the metal substrate. The deposition of the thermoelectric films on the mesa cores results in the formation of a thermoelement.

Abstract: The present subject matter includes a first housing portion which is thermally conductive and which has a first housing opening, a second housing portion which is thermally conductive and which has a second housing opening, the second housing opening being hermetically sealed to the first housing opening, with the first housing portion and the second housing portion at least partially defining an interior volume, cardiac rhythm management electronics disposed in the interior volume, and a thermoelectric energy converter disposed in the interior volume, the thermoelectric energy converter having a hot pole and a cold pole, with the hot pole thermally connected to the first housing portion, and the cold pole thermally connected to the second housing portion.

Abstract: A flexible thermoelectric device and a manufacturing method thereof are provided. Flexible substrates are formed by using LIGA process, micro-electro-mechanical process or electroforming technique. The flexible substrates are used to produce thermoelectric device. The structure and the material property of the substrates offer flexible property and tensile property to the thermoelectric device. Thermal transfer enhancement structures such as thermal via or metal diffusion layer are formed on the flexible substrates to overcome the low thermal transfer property of the flexible substrates.

Abstract: A set of electrical connector pins for a thermocouple includes two materially similar conductor pairs, each conductor pair having conductors composed of a different material, and carried by an electrically insulating connector housing. The different materials of the conductor pairs provide a partial compensation to the thermocouple EMF developed between the hot junction and the cold junction when engaged thereto for the different type thermocouples. The conductors of each pair are operable to engage with two thermoelement conductors that form a thermocouple of differing types. The thermocouples provide a hot junction electrical interconnection therebetween at one end and are coupled to a cold junction at another end.

Abstract: A thermoelectric element for use in a thermoelectric device, the thermoelectric element includes a porous substrate coated with one or more materials, at least one of which is a thermoelectric material. There is also a method for making a thermoelectric element including providing a porous substrate and applying a coating of a thermoelectric material to the porous substrate.

Abstract: According to one embodiment, a thermoelectric device is provided with thermoelectric elements and formed of a material capable of exhibiting the thermoelectric effect and a first electrode located at end portions of the thermoelectric elements. The first electrode includes an electrode member, a soaking member having electrical conductivity, located between the electrode member and the thermoelectric elements, and including facing portions facing the thermoelectric elements and folded portions folded back at peripheral edges of the facing portions so as to lie on the opposite side to the thermoelectric elements, and an elastic member located on the opposite side of the facing portions to the thermoelectric elements, at least a part of the peripheral edge of the elastic member being held between the folded portions and the facing portions of the soaking member.

Abstract: A thermocouple for use in a semiconductor processing reactor is described. The thermocouple includes a sheath having a measuring tip at one end and an opening at the other end. A support member having bores formed along the length is disposed within the sheath. A pair of wires formed of dissimilar metals are disposed within the bores, and one end of the wires is fused together to form a junction. The wires extend along the length of the bores. As the wires exit the bore, they are spatially or physically separated to prevent a short circuit therebetween. The ends of the wires exiting the bore are also free to thermally expand in the longitudinal manner, thereby reducing or eliminating the potential for the wires to fail due to grain slip.

Abstract: The invention relates to Seebeck/Peltier bidirectional thermoelectric conversion devices and in particular to devices employing nanowires of conductive or semiconductive material defined on a substrate by common planar technologies.

Abstract: A thermocouple shield assembly comprising a first tube having an upper portion and a lower portion with a lower end, the first tube including a first elongated cavity closed at the lower end and receiving the thermocouple, a second tube having a second elongated cavity with at least one open end and receiving the upper portion while a part of the lower portion containing the thermocouple extends out of the open end, and a gap between adjacent walls of the second elongated cavity and of the first tube such as to allow independent thermal deformations of the first and second tubes. In use, at least a portion of the part of the lower portion of the first tube is subjected to a given temperature while the second tube is subjected to a different temperature. Methods of manufacturing and of assembling such a thermocouple shield assembly are also presented.

Abstract: What is described is a thermoelectric module composed of p- and n-conductive thermoelectric material legs which are connected to one another alternately via electrically conductive metallic contacts, wherein the electrically conductive metallic contacts are connected to the thermoelectric material legs by hard soldering or high-temperature soldering with a solder comprising metal and glass.

Abstract: A thermocouple having a support tube configured to receive a pair of wires of dissimilar metals. The pair of wires of the thermocouple connected at a junction adjacent to one end of the support tube. The thermocouple further including a cap attached to the opposing end of the support tube, wherein the cap receives the free ends of the pair of wires. The cap allowing the pair of wires to translate freely therethrough to accommodate the difference in thermal expansion and contraction of the pair of wires relative to the thermal expansion and contraction of the support tube.

Abstract: A high-temperature thermocouple and methods for fabricating a thermocouple capable of long-term operation in high-temperature, hostile environments without significant signal degradation or shortened thermocouple lifetime due to heat induced brittleness.

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: An electronic assembly may include a packaging substrate, an integrated circuit (IC) semiconductor chip, a plurality of metal interconnection structures, and a thermoelectric heat pump. The integrated circuit (IC) semiconductor chip may have an active side including input/output pads thereon and a back side opposite the active side, and the IC semiconductor chip may be arranged with the active side facing the first surface of the packaging substrate. The plurality of metal interconnection structures may be between the active side of the IC semiconductor chip and the first surface of the packaging substrate, and the plurality of metal interconnection structures may provide mechanical connection between the active side of the IC semiconductor chip and the first surface of the packaging substrate. The thermoelectric heat pump may be coupled to the packaging substrate with the thermoelectric heat pump being configured to actively pump heat between the IC semiconductor chip and the packaging substrate.

Abstract: One-dimensional nanostructures having uniform diameters of less than approximately 200 nm. These inventive nanostructures, which we refer to as “nanowires”, include single-crystalline homostructures as well as heterostructures of at least two single-crystalline materials having different chemical compositions. Because single-crystalline materials are used to form the heterostructure, the resultant heterostructure will be single-crystalline as well. The nanowire heterostructures are generally based on a semiconducting wire wherein the doping and composition are controlled in either the longitudinal or radial directions, or in both directions, to yield a wire that comprises different materials. Examples of resulting nanowire heterostructures include a longitudinal heterostructure nanowire (LOHN) and a coaxial heterostructure nanowire (COHN).

Abstract: A thermoelectric conversion device and a manufacture method thereof are provided. The manufacture method includes an electrode board stamping process, an insulating frame molding process, a punching process, an element fixing process, a bending process and an insulating frame integrating process. Band-shaped plate members which function as heat radiating fins and heat absorbing fins and are integrated with insulating frame members are respectively folded-back in such a manner that the folding-back directions of the band-shaped plate members are alternately reverse to each other in the longitudinal direction of the band-shaped plate member. The insulating frame members are joined to each other to be arranged substantially in line, to construct an insulating frame unit. Thus, the component number and the assembly labor can be reduced, while the manufacture quality and the product quality can be improved.

Abstract: The present invention comprises an arrangement adapted for an absorption of primarily thermal and/or luminous energy arising from received sunbeams, and having a sunbeam-reflecting reflector unit faceable toward the sunbeams and a thermal and/or luminous energy-absorbing means related to the reflector unit, said reflector unit and said thermal and/or luminous energy-absorbing means being coverable by a transparent protection, said reflector unit, in particular the reflector surface thereof, being formed from a thin and easily bendable material.

Abstract: An anisotropically elongated thermoelectric nanocomposite includes a thermoelectric material.