Abstract: A thermocouple rake. The thermocouple rake may include a number of support rods extending through a number of support disks, a number of thermocouple tubes extending through the support disks, and with the thermocouple tubes and the support disks having a thermal compression bond when heated.

Abstract: A temperature sensor for measuring a temperature of a moving or stationary surface includes a main body portion and a probe head with thermocouple element, the probe head coupled to the main body portion such that the probe head reciprocates relative to the main body portion in a pulsed manner.

Abstract: A method of forming a thermoelectric device may include forming a plurality of islands of thermoelectric material on a deposition substrate. The plurality of islands of thermoelectric material may be bonded to a header substrate so that the plurality of islands are between the deposition substrate and the header substrate. More particularly, the islands of thermoelectric material may be epitaxial islands of thermoelectric material having crystal structures aligned with a crystal structure of the deposition substrate. Related structures are also discussed.

Abstract: The thermoelectric detector consists of an absorber structure supported by two electrically connected beams made of thermoelectric materials such as polysilicon, polysilicon/germanium, bismuth-telluride, skutterrides, superlattice structures, nano-composites and other materials. One end of the thermoelectric beam connects to the absorber structure; the other end connects to the substrate. Infrared radiation incident on the absorber heats up the absorber, resulting in a temperature gradient along the length of the thermoelectric legs, and generating an electrical voltage. The detector arrays are fabricated using micromachining process. The absorber structure is formed over a sacrificial material that is removed at the end of the processing, leaving the detector suspended and thermally isolated. The sacrificial processing method enables the production of small pixel thermoelectric detectors in large two-dimensional arrays with high sensitivity.

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: A thermocouple shield for use in radio frequency fields. In some embodiments the shield includes an electrically conductive tube that houses a standard thermocouple having a thermocouple junction. The electrically conductive tube protects the thermocouple from damage by an RF (including microwave) field and mitigates erroneous temperature readings due to the microwave or RF field. The thermocouple may be surrounded by a ceramic sheath to further protect the thermocouple. The ceramic sheath is generally formed from a material that is transparent to the wavelength of the microwave or RF energy. The microwave transparency property precludes heating of the ceramic sheath due to microwave coupling, which could affect the accuracy of temperature measurements. The ceramic sheath material is typically an electrically insulating material. The electrically insulative properties of the ceramic sheath help avert electrical arcing, which could damage the thermocouple junction.

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: The invention provides a temperature measurement system including a temperature sensor and means for biasing the temperature sensor in the direction of a thermal energy source in response to receiving thermal energy from the source. The invention also provides a continuous casting system including at least one temperature sensor disposed in the secondary cooling region and means for biasing the temperature sensor in the direction of the strand of metal in response to receiving thermal energy from the strand of metal.

Abstract: To provide a thermoelectric conversion module enabling cost reduction by reducing time and work required for assembly, and so on.

Abstract: Energy harvesting devices are disclosed. An illustrative embodiment of the energy harvesting devices includes a fastening device, a first thermally-conductive element engaging the fastening device, a thermoelectric device disposed in thermal contact with the first thermally-conductive element and a second thermally-conductive element disposed in thermal contact with the thermoelectric device.

Abstract: The invention relates to a dynamic solar tracking system for making optimal use of solar energy by means of panels of photovoltaic or thermal plates, in which a modular tracker adopting the configuration of a main beam which can be aligned with others of an identical nature is developed, this assembly of main beams being able to pivot with respect to its longitudinal axis, each of these beams being formed by a variable number of modules formed by profiles which as a whole provide each beam with a configuration by way of a tetrahedron mesh, and in each of which there is assembled a secondary beam structure for supporting the panels of plates, this secondary structure being supported by two side supports with respect to which it can rotate with respect to an axis transverse to the longitudinal direction of the main beams. The assembly incorporates control means for the automatic orientation of the panels, and a weather station for providing information to the control means.

Abstract: A thermoelectric structure may include first and second thermally conductive layers. The first and second thermally conductive layers may be laterally spaced apart in a direction parallel with respect to surfaces of the first and second thermally conductive layers so that a gap is defined between edges of the first and second thermally conductive layers. A thermoelectric element may bridge the gap between the first and second thermally conductive layers, and the thermoelectric element may include a thermoelectric material on respective surface portions of the first and second thermally conductive layers.

Abstract: According to one embodiment, a thermoelectric conversion module includes a thermoelectric conversion portion, a first external electrode, and a second external electrode. The thermoelectric conversion portion includes a single thermoelectric conversion portion element, or electrically connected thermoelectric conversion portion elements. The thermoelectric conversion portion element includes a high temperature electrode, low temperature electrodes, and an n-type and a p-type thermoelectric conversion semiconductor layer disposed between the high temperature electrode and the low temperature electrodes. The first and the second external electrode are electrically connected to one of the low temperature electrode and another one of the low temperature electrode respectively.

Abstract: A thermally insulated structure comprising a first surface and a second surface is provided. The second surface is disposed in a spaced apart relationship with the first surface to define a gap, within which a layer of thermal insulation is provided. The thermal insulation includes a thermoelectric material.

Abstract: A thermocouple produced by removing insulation from a distal end of each of at least first and second thermocouple conductors, forming a thermocouple junction at the distal ends of the at least first and second thermocouple conductors, placing the thermocouple junction into the heat shrinkable polymer material by sliding a second end of the tube of heat shrinkable polymer material over the thermocouple junction and sealing the thermocouple junction by heating and melting the polymer material.

Abstract: In some embodiments, the present invention is directed to thermoelectric devices comprising thermoelectric elements comprising nanotubes of thermoelectric material. The present invention is also directed to methods of making such thermoelectric elements and devices, particularly wherein the nanotubes are formed electrochemically in templates. The present invention is also directed to systems and applications incorporating and using such devices, respectfully.

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 disposed on a substrate comprises a first leg of thermoelectric material, a second leg of thermoelectric material, and a thermocouple junction electrically connecting the first leg and the second leg, wherein a height of the thermocouple junction is substantially a height of the first or second legs.

Abstract: A single thermoelectric device designed to operate both as an igniter and flame detector for gas burners is described. Ignition is performed via heating, by Joule effect, of a conductor which can have, preferably, catalytic activity on the combustion while the flame is detected by means of a “hot” thermal state via the seeback effect. Both functions are obtained via control of a circuit for delivery of the power and detection and amplification of the electrical signal correlated to the flame.

Abstract: Preferred electrode devices (10) including a substrate (11) and cathode (13) and anode material (12) coated thereon in discreet locations are described. The cathode materials desirably include multiple layers of thin metal films (14). Preferred cell devices including conductive elements and a solid state source of charged ions for migration into and through the conductive elements are also described.

Abstract: The present invention relates to a laminate for battery encasement comprising aluminum foil and an inner layer, wherein a resin film layer that comprises an aminated phenol polymer (A), a trivalent chromium compound (B), and a phosphorus compound (C) lies between the aluminum foil and the inner layer. The laminate for battery encasement of the present invention is excellent in adhesiveness, gas impermeability, etc., and therefore can be suitably used as a material for encasing a secondary battery, particularly a lithium ion polymer secondary battery.

Abstract: An apparatus and system is presented for partially compensating the cold junction of a thermocouple system using low cost semi-compensated conductors of system components accommodating various thermocouple types. The thermocouple system, comprises a thermocouple portion comprising two thermocouple types, each type composed of two different thermoelectric materials joined to form a hot junction, a semi-compensation portion comprising two substantially similar conductor pairs, each composed of a different material, wherein one conductor of each pair is composed of a material different than the thermoelectric materials of the respective thermocouple type of the thermocouple portion.

Abstract: A method for measurement of high temperatures of a process stream by means of a thermocouple arranged in a thermowell. The thermowell is at least partly covered by a layer of a catalytic material which is active in at least one endothermic reaction. The thermowell is installed in a reactor by inserting the thermowell through a hole penetrating the reactor wall so that the tip of the thermowell is in contact with the process stream. The invention is typically used where the reaction is a reforming reaction and the reactor is an autothermal reformer fed with a hydrocarbon stream and an oxygen containing stream.

Abstract: A thermocouple junction box for reducing EMF generated by a stud-and-cup configuration comprises a cup adapted to be electrically connected to a thermocouple sensing junction and a stud disposed, at least in part, within the cup, the stud being electrically isolated from the cup. In another aspect, a thermocouple junction box comprises a contact element adapted to be electrically connected to a thermocouple sensing junction and a stud mechanically coupled to the contact element by means of an insulating material and electrically isolated from the contact element by means of the insulating material. In a further aspect, a thermocouple assembly comprises a thermocouple sensing junction, a contact element, and a stud. The stud is adapted to receive thereon a conductive element electrically connected to a thermocouple cable, the stud being electrically isolated from and mechanically coupled to the contact element.

Abstract: In a two wire thermocouple, a hollow tip is formed of the material of one of the thermocouple wires, the tip being adapted to extend into a medium the temperature of which is to be measured, both wires extending into a passage in the tip through an open outer end of the passage toward an inner end of the passage, one of the two thermocouple wires, of a material different from said tip, extending entirely through the passage and being welded at the outside of said tip to form a thermocouple junction and the other of the wires, of the same material as the tip, being welded to the tip at a place spaced from the junction.

Abstract: A high-temperature connectorized thermocouple probe assembly for use in land gas turbine environments consistent with the present invention comprises a thermocouple junction having a plurality of conductors, a high temperature connector having at least one conductor, a length of cable having at least one conductor coupling at least one of the conductors of the thermocouple junction with at least one conductor of the high temperature connector; and a bushing disposed around the length of cable. In a further aspect, a land gas turbine system consistent with the present invention comprises a land gas turbine and a thermocouple probe assembly disposed at least partly within the land gas turbine, wherein the thermocouple probe assembly comprises a thermocouple junction and a high temperature connector coupled to the thermocouple junction, and wherein the thermocouple probe assembly is removably connected to, or is adapted for removable connection to, the land gas turbine via the high temperature connector.

Abstract: A millivoltage generator is provided in which a rod formed of a first metal extends in spaced relationship within a tubular sheath of a second metal, the rod being welded to the sheath at one end to form a conductive junction and held in place in the sheath by an epoxy seal proximate the other end of the rod which prevents moisture from collecting inside the sheath. The space between the sheath and the rod is filled with an insulating material. Preferably, a wire connector is fixed to the end of the rod which extends through and beyond the epoxy seal. It is also preferred that a bushing be welded to the outside of the sheath proximate the epoxy seal and that the bushing be externally threaded to facilitate mounting of the millivoltage generator. A second metal rod welded to the bushing extends from the bushing parallel to the first metal rod and beyond the epoxy seal. Another wire connector is fixed to the second metal rod to facilitate electrical connection of the millivoltage generator.

Abstract: A probe for measuring the surface temperature of a pipe includes a detector assembly and a rectangular strap. The detector assembly includes a rigid, unitary clamp member having a bottom, pipe engagement surface, an oppositely disposed upper surface, and first and second locking dogs extending upwardly from the upper surface. The locking dogs define a gap having a width WG. A temperature sensor assembly is carried on the pipe engagement surface. The proximal end portion of the strap is mounted to the clamp member. The strap is flexible, longitudinally resilient and has a thickness TU in an unstretched condition and a thickness TS in a stretched condition, where TU>TS, TU>WG, and WG>TS. The probe is mounted to the pipe by positioning the pipe engagement surface of the clamp member against the pipe, wrapping the strap around the pipe, and applying a tensile force to the distal end portion of the strap such that the thickness of the strap decreases from TU to TS.

Abstract: This invention concerns a thermocouple which is protected by an outer sheath comprising inner and outer tubes with the annular space filled with low temperature sintering refractory material which is preferably beaded before filling in the space and in which the outer tube is constricted to compact the material. The refractory material will include borosilicate and boric acid powder.

Abstract: A thermocouple holder assembly for a furnace tube including a heat sink block for welding to the furnace tube, the heat sink block having a first bore therein for slidably receiving the distal end of an elongated sheathed thermocouple, the heat sink block having a hollow heat sink tube extending from the first bore for receiving a portion of the thermocouple, and a heat shield for welding to the furnace tube having walls for shielding and completely enclosing the heat sink block to shield the heat sink block from ambient heat on the exterior of the heat shield, the heat shield having a cavity therein for receipt of the heat sink block and the heat sink tube and flexible insulation material placed over the heat sink block and the heat sink tube, one of the walls having a second bore extending therethrough to the cavity for slidably receiving the thermocouple, the second bore being positioned in the heat shield wall for alignment with the heat sink tube for conveying the thermocouple through the second bore to

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: A thermopile construction adapted for use as an electric generator capable of producing multiple EMF outputs in response to heat as from a pilot flame. A cluster of hot and cold thermocouple junctions are arrayed within a housing. The hot junction of one of the thermocouples, located at the beginning of the array, extends beyond the other hot junctions for greater sensitivity to changes in temperature as from a pilot flame and surrounding radiating surfaces. While being a part of the array, the longer thermocouple also has extension wires at the cold junction thereof to deliver the EMF of that couple alone to a control device requiring a small EMF. One such wire serves also as one of two leads for delivering the EMF of the entire array to an electromechanical device that requires a larger EMF. Additional extension wires can be added to obtain intermediate EMF values.

Abstract: A device for converting heat and/or radiation energy into electric energy. The device is comprised of a gastight chamber and at least one electrochemical cell arranged in said gastight chamber, which consists of an anode and a cathode, an electrolyte being placed between the former and the latter and the terminal leads being guided outward. The gastight chamber and the elctrochemical cell contain a gas or gas mixture, to which energy in the form of heat (&Dgr;) and/or radiation (h&ngr;) can be fed, wherein the gas or gas mixture comprises a molecular and a dissociated fraction, the proportion of which depends on the temperature and produces a difference in potential between the anode and the cathode.

Abstract: A radiation sensor which includes a thermopile for detecting radiant energy. The thermopile and a support rim for the thermopile are fabricated as an integrated unit to form a support chip. The support chip is mated to a mating chip so that the thermopile is positioned in an inner cavity region of the radiation sensor. The sensor has a window which permits the transmission of radiant energy into the enclosure such that the radiant energy impinges upon a central absorber region of the thermopile.

Abstract: A thermocouple protective tube for protecting a thermocouple wire, comprising a hollow cylinder-shaped body which has one end closed and is composed of pyrolytic boron nitride, and a coating layer which is formed on an outer surface of the cylinder-shaped body and is composed of at least one material selected from pyrolytic carbon, carbon-containing pyrolytic boron nitride, silicon nitride, silicon carbide and aluminum nitride. There is provided a thermocouple protective tube having excellent resistances even at a high temperature and in an oxidizing or other corrosive atmosphere for a long period and having high response to temperature change.

Abstract: An improved torus 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.

Abstract: A method and apparatus for maintaining a viewing window of a detector substantially clean includes enclosing the detector within a housing, and moving a target surface relative to the viewing window to create an airflow adjacent the viewing window. The housing can include an aperture through which the viewing window of the sensor views the target surface. Motion of the target surface creates an airflow velocity adjacent the viewing window for maintaining the viewing window substantially clean. To increase the accuracy of the detector, a high emissivity area is provided on an outside surface of the housing which faces the target surface.

Abstract: A thermocouple sensing element comprising a first electrically conductive member formed of one of two dissimilar metals and a second electrically conductive member formed of the second of the two dissimilar metals attached to the first electrically conductive member, and located within the first electrically conductive member, the first electrically conductive member and the second electrically conductive member forming two elements which generate an electrical potential difference under varying conditions of heat.

Abstract: A battery adapter (A) replaces two batteries (10) with a single battery (10) housed within a compartment (48) of a battery powered electrical device (D). An electrically conductive housing (40) adapted to replicate a selected battery and fit within a space adapted to house two of the selected sized batteries. A step up circuit (18) mounted within the battery housing (40) receives an electrical signal from a single battery (10) and transforms the voltage of the electrical signal to simulate an electrical signal from two electrically connected selected batteries (10).

Abstract: Preferred electrode devices (10) including a substrate (11) and cathode (13) and anode material (12) coated thereon in discreet locations are described. The cathode materials desirably include multiple layers of thin metal films (14). Preferred cell devices including conductive elements and a solid state source of charged ions for migration into and through the conductive elements are also described.

Abstract: A probe for temperature measurement, comprising a probe, body which has a cylindrical hole into which a thermocouple or a resistance thermometer can be inserted, whose thermosensitive tip projects from the forward section of the probe body, the forward section of the probe body being provided with an annular gap at a small distance from the cylindrical hole .

Abstract: The present invention relates to generation of electricity by high-pressure, high-enthalpy cryogenic vapor formed by absorption of heat from a geothermal heat source. The cryogen is injected into a U-tube or an open tube heat exchanger extending to the bottom of a geothermal well and thermal energy is gained by the cryogen, causing the cryogen to vaporize into high-enthalpy cryogenic vapor that returns to the surface to power a rotary vane motor that drives an electrical generator. Also, electricity is generated by a geothermal thermoelectric generator placed either underground or above ground using heat extracted from the bottom of the geothermal well via a U-tube or an open tube heat exchanger. The cryogenic vapor is capable of air-lift pumping water from the well. The electricity generated may be used to electrolyze the water into hydrogen and oxygen.

Abstract: An electronic module is provided having an integrated thermoelectric cooling assembly disposed therein coupled to the module's electronic device. The thermoelectric assembly includes one or more thermoelectric stages and a thermal space transformer, for example, disposed between a first thermoelectric stage and a second thermoelectric stage. The electronic device is mounted to a substrate with the thermoelectric assembly disposed in thermal contact with the electronic device and a thermally conductive cap is positioned over the thermoelectric assembly, and is also in thermal contact with the thermoelectric assembly. Power to the thermoelectric assembly can be provided using electrically conductive springs disposed between one or more stages of the assembly and pads on an upper surface of the substrate, which electrically connect to power planes disposed within the substrate.

Abstract: An improved apparatus comprising a thermocouple for measuring the temperature in a gasification process is provided. The improvement comprises a sapphire envelope for enclosing at least a portion of the thermocouple. The sapphire envelope may be in the form of a sapphire sheath fitted over the thermocouple. The apparatus may also comprise a thermowell, with the sapphire envelope being provided by the thermowell.

Abstract: A monitor, and method, for monitoring temperatures at various specific times and locations in a test or manufacturing process, and for comparing those temperatures with reference profiles of optimum temperatures. Both the monitor and the method are especially well suited for checking the temperatures of various zones of reflow ovens used in mass soldering the connections of electronic components on circuit boards. The monitor is designed to distinguish clearly among respective temperatures at several points on tops and bottoms of circuit boards.

Abstract: An electronic module is provided having an integrated thermoelectric cooling assembly disposed therein coupled to the module's electronic device. The thermoelectric assembly includes one or more thermoelectric stages and a thermal space transformer, for example, disposed between a first thermoelectric stage and a second thermoelectric stage. The electronic device is mounted to a substrate with the thermoelectric assembly disposed in thermal contact with the electronic device and a thermally conductive cap is positioned over the thermoelectric assembly, and is also in thermal contact with the thermoelectric assembly. Power to the thermoelectric assembly can be provided using electrically conductive springs disposed between one or more stages of the assembly and pads on an upper surface of the substrate, which electrically connect to power planes disposed within the substrate.

Abstract: A portable electronic device has a casing has an upper case body and a rear case cover both made of a thermally conductive material. A heat insulating member thermally insulates the rear case cover from the upper case body of the casing. A thermoelectric generator unit is disposed in the casing for generating an electromotive force based on the Seebeck effect. The thermoelectric generator unit has a heat radiating plate for transferring heat to the upper case body and a heat absorbing plate. A heat conductive spacer is made of a thermally conductive and elastically deformable sheet of material and has opposed main surfaces. One of the main surface is disposed in contact with the heat absorbing plate of the thermoelectric generator unit and the other main surface is disposed in contact with an inner side surface of the rear case cover for conducting heat from the rear case cover to the thermoelectric generator unit.

Abstract: The invention provides a temperature sensor on the basis of a thermocouple constituted by two different metals. The first metal is provided in the form of an electrically insulated wire, having a blank uninsulated portion. The second metal is constituted by a jacket member enclosing the insulated wire. The jacket member is in electrical contact with the insulated wire via the blank uninsulated portion to thereby form a measuring junction. As a feed line, an electrically insulated copper wire is provided whose free end has a blank portion. The first wire is wound around the copper wire and projects over the free end thereof. The jacket member extends over the blank uninsulated portion of the carrier wire and is in electrical contact therewith. Due to the fact that the same material is chosen for the jacket member and for the carrier wire, i.e. copper, the carrier wire can be used as electrical feed line.

Abstract: A thermocouple-type temperature-detecting device excellent in the temperature measurement responsiveness constituted of an outer protective pipe 1 and an inner protective pipe 2, the outer protective pipe 1 is formed in a laminated layer structure of a 2nd layer 10 made of a ceramic containing molten metal-repelling BN and a 1st layer 11 made of a ceramic, the inner protective pipe 2 is formed of a front protective pipe 3 made of a ceramic having a good heat conductivity and a heat-shielding rear protective pipe 4 extending into the outer protective pipe 1 through an air layer 17, furthermore, the head portion 5 of the front protective pipe 3 is projected from the outer protective pipe 1, and a temperature-sensitive portion 20 of a thermocouple is disposed in the inside of the head portion 5.

Abstract: An immersion measuring probe for measurement in liquids, in particular in molten metals, has a carrier tube, a measuring head mounted on one end of the carrier tube, and measuring elements as well as signal lines for the measuring signals generated by the measuring elements arranged on the measuring head. The signal lines are longer than the carrier tube and run from the end of the measuring head facing the inside of the carrier tube. In order to improve the handling of the immersion measuring probe, the signal lines are guided through the inside of the carrier tube and are wound up there around its longitudinal axis.