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WO/2015/039185A1 |
A modular unit attached to a solar panel. The modular unit comprises a heat exchanger having an inlet manifold and an outlet manifold and a plurality of spaced apart galleries extending there between, a plurality of thermoelectric module...
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WO/2015/041512A1 |
The invention relates to a system for harvesting electrical energy accumulated in the form of heat in the surfaces of urban paving and building claddings that are directly exposed to the infrared radiation of the sun, which system, using...
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WO/2015/037014A1 |
Present invention provides nanostructured p-type copper-selenide as a cost-effective thermoelectric material with a high thermoelectric figure-of-merit. The nanostructured copper-selenide claimed in this invention is a cost-effective p-t...
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WO/2015/033832A1 |
Provided are the following: a thermoelectric conversion element, comprising on a substrate a first electrode, a thermoelectric conversion layer, and a second electrode, wherein the thermoelectric conversion layer contains a thermally sti...
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WO/2015/034318A1 |
A thermoelectric conversion material having excellent performance is disclosed. A thermoelectric material according to the present invention comprises: a matrix including Cu and Se; and Cu-containing particles.
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WO/2015/033797A1 |
The present invention provides a thermoelectric conversion device which suppresses the deterioration over time in thermoelectric conversion performance. This thermoelectric conversion device is equipped with: a substrate; a thermoelectri...
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WO/2015/033868A1 |
A thermoelectric conversion element having: a lower electrode formed upon a substrate; a thermoelectric conversion layer formed covering some of the lower electrode; and an upper electrode formed upon the substrate away from the lower el...
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WO/2015/034294A1 |
Embodiments of the present invention relate to a thermoelectric module used for cooling, and provide a thermoelectric module comprising: substrates facing each other; and a first semiconductor element and a second semiconductor element a...
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WO/2015/034317A1 |
A thermoelectric material having excellent performance is disclosed. The thermoelectric material according to the present invention may be represented by chemical formula 1 below. CuxSe, wherein 2
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WO/2015/034320A1 |
A thermoelectric conversion material having excellent performance is disclosed. A thermoelectric material according to the present invention comprises Cu and Se, wherein crystals comprising Cu atoms and Se atoms have a plurality of diffe...
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WO/2015/034321A1 |
Disclosed is a method for manufacturing a thermoelectric material having high thermoelectric conversion performance across a broad temperature range. The method for manufacturing a thermoelectric material, according to the present invent...
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WO/2015/030218A1 |
This thermoelectric power generation module can suppress oxidation of a thermoelectric conversion element and diffusion into the thermoelectric conversion element of not only a solder layer material but also of a solder joint layer mater...
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WO/2015/030220A1 |
A thermoelectric power generation module that can be produced without compromising bonding strength or solderability when bonding a thermoelectric conversion element and an electrode by means of a solder, and that does not cause large in...
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WO/2015/029910A1 |
The present invention has the purpose of providing an organic semiconductor compound which increases crystallinity (packing properties) of an organic semiconductor polymer, achieves both carrier mobility and solubility at a higher level,...
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WO/2015/031584A1 |
A method includes preparing a thermoelectric material including p-type or n-type material and first and second caps including transition metal(s). A powder precursor of the first cap can be loaded into a sintering die, punches assembled ...
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WO/2015/026159A1 |
The embodiments of the present invention relate to a thermoelectric element and a thermoelectric module used for cooling, and the thermoelectric module can be made thin by having a first substrate and a second substrate with different su...
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WO/2015/026151A1 |
The embodiments of the present invention relate to a thermoelectric element and a thermoelectric module, and may provide a thermoelectric element and a thermoelectric module having notably improved cooling capacity (Qc) and rate of tempe...
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WO/2015/026433A1 |
A thermal energy harvester and power conversion system employs a bleed air duct (16) containing the flow of high temperature air from an engine. A lower temperature air source is included with an energy conversion device (38) having a ho...
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WO/2015/022197A1 |
The invention relates to a thermoelectric element having at least one tubular segment (2, 3) which in turn comprises a thermoplastic polymer (6, 7) of tubular form into which a semiconductive, p- or n-doped thermoelectric filler is store...
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WO/2015/022143A1 |
The invention relates to a method for deposition of thermoelectric material on a substrate. Nanoparticles of thermoelectric material are synthesized and provided in such a way that the printing operations (inkjet and laser printing proce...
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WO/2015/021956A1 |
The present invention relates to an electricity generation unit (100) equipped with: - at least one heat withdrawal chamber (23) for at least temporarily arranging a heat source (3) at least partially therein, - at least one shell (13) f...
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WO/2015/019871A1 |
The present invention provides a thermoelectric conversion material and a production method therefor, the thermoelectric conversion material having excellent thermoelectric performance and flexibility, and being capable of being produced...
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WO/2015/019811A1 |
This layered thermoelectric element (101) is a layered thermoelectric element having a first end surface (3) and a second end surface (4) which face one another, a heat-absorbing surface, and a heat-dissipating surface, wherein: a p-type...
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WO/2015/019810A1 |
This layered thermoelectric element (101) is a layered thermoelectric element configured so as to generate power from the temperature difference in a fixed heat-transmitting direction (91), the layered thermoelectric element having a fir...
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WO/2015/017087A1 |
Technologies are provided for employing electricity to control a combustion reaction. Energy is received from a combustion reaction. A portion of the received energy is converted to generated electricity. The generated electricity conver...
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WO/2015/015688A1 |
A thermal power generation unit of the present disclosure is equipped with a plurality of thermal power generation tubes. Each of the thermal power generation tubes has a flow path partitioned by the inner circumferential surface and is ...
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WO/2015/011856A1 |
A thermoelectric conversion material represented by the chemical formula X3-xX'xT3-yCuySb4 (0≤x<3, 0≤y<3.0, and x+y>0), wherein X comprises at least one element from Zr and Hf, X' comprises at least one element from Nb and Ta, and T ...
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WO/2015/013090A2 |
Systems and methods of generating power in a wellbore extending through a subterranean formation are described. A swirling flow of pressurized fluid is passed through a vortex tube to generate a temperature differential between first and...
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WO/2015/012113A1 |
[Problem] To produce a p-type semiconductor by sintering a material represented by the general chemical formula Mg2SiXSnYGeZ (wherein X+Y+Z=1, X≥0, Y≥0, and Z≥0). [Solution] X is in the range of 0.00≤X≤0.25, and Z satisfies the...
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WO/2015/008727A1 |
The present invention provides: a thermoelectric conversion element having excellent thermoelectric conversion performance; and a composition for forming a thermoelectric conversion layer, said composition making it possible to form a th...
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WO/2015/007960A1 |
The invention relates to a thermoelectric device (1) comprising a first conduit (10) sealingly housed in a second conduit (12). The first (10) and second (12) conduits extend along a longitudinal axis (11). In addition, the device (1) co...
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WO/2015/005065A1 |
This invention provides a method for manufacturing a nanocomposite thermoelectric conversion material in which phonon-scattering particles having a specific shape are dispersed, reducing thermal conductivity and increasing thermoelectric...
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WO/2015/004486A1 |
A method of generating electrical power from waste heat is disclosed comprising providing waste heat to a first (161) surface of a thermoelectric module (160) and cooling a second surface (162) of the thermoelectric module (160) using po...
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WO/2015/005340A1 |
The present invention provides a thermoelectric conversion element, thermoelectricity-generating article and a sensor-use power source in which said thermoelectric conversion element is used, and a thermoelectric conversion material for ...
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WO/2015/005362A1 |
A thermoelectric generation module in which increases in heat leakage between a high-temperature-side heat exchanger and a low-temperature-side heat exchanger can be minimized while both effectively preventing oxidation of a thermoelectr...
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WO/2015/004544A1 |
Provided is a portable, thermoelectrically powered device, such as a flashlight or headlamp. The device comprises at least one thermoelectric generator for extracting body heat from a user, the Thermoelectric generator located on and ext...
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WO/2015/001523A1 |
A conversion device (10) of thermic energy into electrical energy comprises a plurality of elementary pairs (1,2,3,..., n) connected by junctions (11) to form a circuit. Each elementary pair consists of an element (P) and an element (N),...
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WO/2015/001104A1 |
The invention relates to a thermoelectric device (80) comprising a plurality of thermoelectric modules (10) each comprising at least one thermoelectric element of annular form, able to generate an electric current under the action of a t...
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WO/2015/002029A1 |
The present invention addresses the problem of providing a thermoelectric conversion element having excellent thermoelectric properties and an excellent conversion efficiency. A thermoelectric conversion element having: a thermoelectric ...
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WO/2015/001899A1 |
This invention provides a thermoelectric conversion element, and a thermoelectric conversion module using same, in which a pair of electrodes are formed on a substrate, an insulating layer is formed between said electrodes, an n-type the...
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WO/2015/003157A1 |
Thermoelectric materials based on tetrahedrite structures for thermoelectric devices and methods for producing thermoelectric materials and devices are disclosed. The thermoelectric device has a pair of conductors and a p-type thermoelec...
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WO/2015/001720A1 |
The thermal power generation unit according to the present disclosure is provided with a plurality of thermal power generation tubes. Each of the thermal power generation tubes has a channel demarcated by the inner circumferential surfac...
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WO/2015/000471A1 |
The present invention relates to a thermogenerator (01) for motor vehicles, comprising a hollow body (02), which is integrated into a coolant circuit of the motor vehicle and through which heated coolant (03) of the coolant circuit flows...
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WO/2015/001865A1 |
The purpose of this invention is to provide the following: a thermoelectric-conversion-layer manufacturing method whereby thermoelectric conversion layers having excellent thermoelectric conversion performance can be manufactured efficie...
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WO/2014/208284A1 |
The objective of the present invention is to provide: a composition for forming a thermoelectric conversion layer, the composition having exceptional thermoelectric properties; a thermoelectric conversion element in which said compositio...
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WO/2014/210300A1 |
A controller for a plurality of system of solar panels is provided. An input connector is configured to receive (a) power from the plurality of solar panels, and (b) information from the individual solar panels. An output is configured t...
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WO/2014/206163A1 |
A method for manufacturing a P-type semiconductor element for a refrigeration or heating device. The method is characterized in that the P-type semiconductor element is made of tellurium material, bismuth material and antimony material. ...
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WO/2014/206164A1 |
A method for manufacturing an N-type semiconductor element for a refrigeration or heating device. The N-type semiconductor element is made of tellurium material, bismuth material and selenium material. The method comprises: firstly, smas...
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WO/2014/204711A2 |
A thermal management article includes a graphite sheet from between about 10 micron and 100 micron thick with an in-plane thermal conductivity at least 250 W/mK. The graphite sheet has a graphene oxide coating having a thickness from bet...
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WO/2014/204346A1 |
The invention relates to the electrical engineering industry and is an electrochemical cell which can be used for the electrolysis of electrolytes and/or for producing electrical energy using heat from the surrounding environment. Any el...
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