Abstract: Disclosed is a thermopile improved in its measurement sensitivity and manufacturing cost, which comprises a pillar-shaped substrate having a side extending in the parallel direction to an incident light to be measured so as not to be irradiated with the incident light, and first and second thermoelectric material layers arranged alternately on the side of the pillar-shaped substrate along the extending direction of the side of said pillar-shaped substrate.

Abstract: A measuring system has a pair of sensors with the response time of one sensor lagging the response time of the other. The output of each sensor is sampled periodically and the outputs for two successive samples are compared to calculate the actual value of the parameters based upon the change in the two outputs.

Abstract: An electricity-producing cell utilizing a foamed multiple thermocouple made of a conductive open-cellular foam matrix, a portion of which forms a first pole with a plurality of discrete conductors of a different material from the foam matrix embedded in the foam having a portion of each of the discrete conductors being exposed on the insides of the cells of the foam forming a plurality of thermocouples with means to contact the discrete conductors to convey current produced by the thermocouples to a second pole with means to heat the discrete conductors, in some embodiments, being radioactive isotopes.

Abstract: A method of producing a multiple thermocouple having a conductive open-cellular foam matrix, a portion of which forms a first pole with a plurality of discrete conductors of a different material from the foam matrix embedded in the foam having a portion of each of the discrete conductors being exposed on the insides of the cells of the foam forming a plurality of thermocouples. The remaining surface area inside the foam's cells not having an exposed discrete conductor thereon can be insulated. A second pole member is provided. Means to contact the discrete conductors in the foam and convey current produced by the thermocouples to the second pole of the thermocouple completes the multiple thermocouple. Such means to contact the discrete conductors can provide the heat to excite the thermocouples or such heat can come from other sources.

Abstract: A gas sensor has a 100-400 .mu.m thick gas-sensitive layer containing 5-30 mole % of a platinum group metal or an alloy thereof.

Abstract: A multiple thermocouple comprising a conductive open-cellular foam matrix, a portion of which forms a first pole with a plurality of discrete conductors of a different material from the foam matrix embedded in the foam having a portion of each of the discrete conductors being exposed on the insides of the cells of the foam forming a plurality of thermocouples. The remaining surface area inside the foam's cells not having an exposed discrete conductor thereon can be insulated. A second pole member is provided. Means to contact the discrete conductors in the foam and convey current produced by the thermocouples to the second pole of the thermocouple completes the multiple thermocouple. Such means to contact the discrete conductors may provide the heat to excite the thermocouples or such heat can come from other sources.

Abstract: A sensor for measurement of an energy flux and in particular a sensor for measurement of a heat flux or measurement of visible or infrared radiation. The energy flux sensor includes deposits of a first metal in the shape of plates on each of the faces of a substrate, metal-coated holes of the same first metal through the substrate joining one face to the other and surface elements of another metal having thermoelectric properties in relation to the first metal, placed in the thickness of the substrate. This sensor, alone or associated in series with other sensors, makes it possible to measure the thermal properties of certain construction materials, insulating materials in particular. It also makes it possible, when covered with an absorbing coating, to measure visible or infrared radiation.

Abstract: A method and apparatus for fabricating a thermoelectric device includes forming a matrix board (12) with an array of orifices (100) formed therein. A plurality of P-type thermoelements (96) are formed and then a vacuum chuck (92) is utilized to dispose alternating ones of the elements (96) into the alternating ones of the orifices (100). A plurality of N-type elements (108) is formed and a vacuum chuck (104) is utilized to dispose alternating ones of the elements (108) into the remaining orifices (100) of the matrix (12). This forms an assembled array (52). A plurality of conductive tabs (114) is placed onto the P-type elements (98) and N-type elements (108) by a vacuum chuck (116). A second set of conductive tabs (120) is disposed on the opposite side of the assembled array by a vacuum chuck (124). A solder flow oven (54) and a solder flow oven (76) are utilized to reflow the solder on the tabs between the two operations.

Abstract: A new and improved thermoelectric device of the type which provides electrical energy in response to a temperature gradient applied across the device exhibits both structural integrity and improved efficiency. The new thermoelectric device includes a plurality of thermoelectric elements, coupling means on opposite respective sides of the thermoelectric elements for interconnecting the elements electrically in accordance with a predetermined pattern, and encapsulant means including an encapsulant material covering the exposed surfaces of the thermoelectric elements. The encapsulant forms void spaces between the elements for providing effective thermal insulation between the elements and confining substantially all of the heat flow from the temperature gradient to through the elements. The coupling means includes electrically conductive plate segments for electrically interconnecting the thermoelectric elements.

Abstract: A method of operating a thermoelectric generator includes: cyclically producing increasing then decreasing temperature differences in the thermoelectric material of the generator; and generating a cyclically increasing then decreasing electrical generator output signal, in response to such temperature differences, to transmit electrical power generated by the generator from the generator. Part of the thermoelectric material reaches temperatures substantially above the melting temperature of the material. The thermoelectric material of the generator forms a part of a closed electrical loop about a transformer core so that the inductor voltage for the loop serves as the output signal of the generator. A thermoelectric generator, which can be driven by the described method of operation, incorporates fins into a thermopile to conduct heat toward or away from the alternating spaces between adjacent layers of different types of thermoelectric material.

Abstract: A thermoelectric device includes first and second sets of spaced apart copper plate segments. Thermoelectric elements which generate electricity are disposed between the sets of copper plate segments. The elements are electrically and thermally fastened thereto by a solder paste screen printed on the inner surfaces of the sets of copper plate segments. A ceramic potting compound which absorbs thermal expansion of the device fills the voids between the thermoelectric elements and the copper plate segments and a thick film ceramic insulator coats the outer surfaces of the sets of copper plate segments.Also disclosed is a method for manufacturing the device of the present invention.

Abstract: A generator of electric energy by the transformation of thermal, solar energy, or of heat of any source, consisting in one or more thermocouples combined with a cooling device, cooling down the weldings of the thermocouples on which heat is produced by the Peltier effect, also producing a very high thermal gradient. The cooling device exploits, for the functioning thereof, the phenomena which can be observed along the thermocouples. The system for the use of such a generator provides a particular disposition of the same in parabolic collectors, as to increase the sun ray concentration onto the weldings exposed to the heat and as to allow a decentralization in the electric energy supply by means of a plurality of generators consisting in only one thermocouple, said generators being interconnected.

Abstract: A thermal converter is constructed with thermoelectric element composed of a honeycomb structural body having a large number of parallel channels extending therethrough and separated by thin walls, a part of the channels forming a region for flowing a high temperature fluid and the other part of the channels forming a region for flowing a low temperature fluid. A honeycomb structural body to constitute P type thermoelectric element and a honeycomb structural body to constitute N type thermoelectric element are preferably alternately arranged in a plurality of numbers.

Abstract: Energy storage is accomplished for use with a thermoelectric generator in which thermopiles are provided. The source of solar energy irradiates upon the latent heat storage device to enable the heat to be stored at a relatively constant temperature to serve as the source of heat for a greater period of time than that which the solar source is providing energy. Apparatus is provided to enhance the temperature gradient in which the thermopile is located in order to increase the thermoelectric energy generated.

Abstract: An electricity generator which produces electrical energy from the random Brownian movement of molecules in a gas, and the uneven distribution of thermal energy in the different molecules of the gas, which is at an overall average uniform temperature. A plurality of sets of thermocouples are mounted on a surface in direct contact with the atmosphere, or a gas in a reservoir, with each thermocouple set consisting of a junction of molecular size of two dissimilar metals, and with each thermocouple set joined through a rectifier a similar thermocouple set. Alternatively, a plurality of separate molecular size metal anodes may be mounted on a surface with pairs of anodes converted by rectifiers to the output circuit.

Abstract: Combustible element analyzer for determining the combustible element concentration of a sample gas. The sample is routed through an inlet conduit, mixed with a source of air, heated to an elevated temperature and analyzed by the combustible element analyzer. The analyzer includes a number of series connected thermocouples forming a thermopile. Exothermic reactions induced in the sample by catalyst elements create temperature variations along the thermopile. These variations cause a voltage difference along the thermopile whose value can be correlated to the combustible element concentration within the sample. Means are included for maintaining uniform sample flow past the analyzer and for maintaining analyzer calibration should the flow rate vary.

Abstract: An improved thermopile construction particularly adapted for use as an electric generator for producing a signalin response to heat from a pilot flame. Groups of elongated elements of dissimilar metals are assembled or arrayed in a circle within a metal sleeve to produce a pilot generator. The first group of elements is arrayed against the inside wall of the metal sleeve and the second group of elements is assembled radially inwardly from the first group. Respective ends of the elements of the first group and the second group are joined with the opposite end of the respective end of the element of the second group being joined to the opposite end of the next adjacent element of the first group. Individual elements of each group have a cross-sectional configuration to provide for optimum heat transfer between the sleeve and elements of the first group and to provide for assembly of the elements of the second group in a circle of smaller diameter.

Abstract: Threads are interlaced with thermoelectric wires to provide a woven cloth in tape form, there being an intermediate layer of heat radiation reflecting material (e.g., aluminum foil) insulated electrically from said wires, which are of opposite thermoelectric polarity and connected as a plurality of thermocouples.

Abstract: In a thermoelectric generator, a component comprises a ceramic insulator, having over limited areas thereof, each area corresponding to a terminal end of thermoelectric wires, a coating of a first metal which adheres to the insulator, and an electrical thermoelectric junction including a second metal which wets said first metal and adheres to said terminal ends but does not wet said insulator, and a cloth composed of electrically insulating threads interlaced with thermoelectric wires.

Abstract: An improved thermal generator is described which includes a plurality of film thermocouples which are vapor-deposited on an insulating carrier material. The improvement resides in the fact that at least two rows of the thermocouples, arranged on the carrier with consecutive thermocouples alternating in polarity and serially connected to each other, are bridged together by a connecting layer which is vapor-deposited between two thermocouples in each row.

Abstract: Thermoelectric long-lasting microgenerator which may be implanted in the human body, using a cylinder containing a radioactive isotope as a heat source and the human body as a cold source. The connection between the heat source and the thermoelectric element is effected by means of a supple substance which is a poor conductor of electricity. The rest of the heat source is surrounded by a volume affording a very high impedance to the propagation of heat.