Abstract: An electrical power generation system has a thermal battery and a thermoelectric module positioned proximate to the thermal battery. The thermoelectric module has a first side thermally coupled to the exterior of the housing; and an electrical circuit configured to conduct electrical current from the thermoelectric module to an electrical load. The electrical circuit can be configured to conduct electrical current from the thermal battery to the electrical load while the voltage produced by the thermal battery is above a threshold and to conduct electrical power from the thermoelectric module when the voltage produced by thermal battery drops below the threshold.

Abstract: Aspects of this disclosure relate to a biometric sensing device that combines sensing with an actuator for two way communication between a finger on a surface and the device. The sensor can also function as an actuator. A finger can be authenticated based on an image of the finger generated by the sensor and also based on a response to energy delivered to the finger by the actuator. Two way communication can provide more robust authentication than fingerprint sensing alone.

Abstract: Optical fibers are described that include integrated Photovoltaic (PV) cells. One embodiment comprises a method of integrating a photon converter into an optical fiber. The method comprises acquiring an optical fiber having a core that is configured to convey light. The method further comprises cleaving the optical fiber to form a first length and a second length, and fabricating a photon converter onto an end of the first length of optical fiber, where the photon converter includes a void that allows the light through the core to traverse across the splice. The method further comprises splicing the end of the first length of the optical fiber to an end of the second length of the optical fiber.

Abstract: Optical fibers are described that include integrated Photovoltaic (PV) cells. The PV cells do not interfere with the optical signals that are transmitted along a core of an optical fiber. Further, the PV cells are able to convert light scattered from the core of the optical fiber into electricity. The PV cells may then be used to power remote optical amplifiers disposed along the optical fiber. For instance, the PV cells may be used to supplement or fully power the remote optical amplifiers. In one implementation, an apparatus includes an optical fiber and a PV cell. The optical fiber includes a first length and a second length that that are joined together at a splice. The optical fiber includes a core that conveys light, an inner cladding surrounding the core that is optically transparent, and an outer cladding surrounding the inner cladding that redirects scattered light from the core into the inner cladding.

Abstract: System and method for generating and storing electricity by electromagnetic induction using a magnetic field modulated by the formation, dissipation, and movement of vortices produced by a vortex material such as a type II superconductor and further including a vortex flux generator in cryostat and a refrigerant compartment having bi-directionally thermal transfer to the vortex flux generator. Magnetic field modulation occurs at the microscopic level, facilitating the production of high frequency electric power. Generator inductors are manufactured using microelectronic fabrication, in at least one dimension corresponding to the spacing of vortices. The vortex material fabrication method establishes the alignment of vortices and generator coils, permitting the electromagnetic induction of energy from many vortices into many coils simultaneously as a cumulative output of electricity. A thermoelectric cycle is used to convert heat energy into electricity.

Abstract: Traditional power generation systems using thermoelectric power generators are designed to operate most efficiently for a single operating condition. The present invention provides a power generation system in which the characteristics of the thermoelectrics, the flow of the thermal power, and the operational characteristics of the power generator are monitored and controlled such that higher operation efficiencies and/or higher output powers can be maintained with variably thermal power input. Such a system is particularly beneficial in variable thermal power source systems, such as recovering power from the waste heat generated in the exhaust of combustion engines.

Abstract: Systems, methods and/or apparatus for the conversion of various types of energy into thermal energy that may be stored and/or then converted into electrical energy. The electrical energy may be available on demand and/or at a user's desired power requirements (e.g., power level and/or type). For example, the energy may be available at a particular voltage and either as direct current (DC) energy or alternating current (AC) energy. The electrical energy may be easily transported and therefore available at a user's desired location. For example, the systems, methods and/or devices may eliminate or reduce the need for electricity transmission, at least for certain applications. In exemplary embodiments, the system may include an organic phase change material for storing the thermal energy.

Abstract: A thermoelectric generator utilizing a number of thermoelectric modules to produce electric power from waste heat when waste heat is available and from an alternate heat source when waste heat is not available. In both cases hot gasses are directed along several separate paths so that all of the modules are provided with approximately equal hot side temperatures. In a preferred embodiment the engine exhaust exits into an octagonally-shaped plenum into eight separate heat exchangers. Eight modules are mounted in each of the heat exchangers for a total of 64 modules. Preferred embodiments of the present invention include an auxiliary combustion burner-blower unit producing a hot exhaust that exits into the plenum to provide electric power when the truck is not operating. Valve features are provided to control the temperature and exhaust flow rate through the generator.

Abstract: Electrical energy is generated in a device that includes an integrated circuit which produces thermal flux when operated. A substrate supports the integrated circuit. A structure is formed in the substrate, that structure having a semiconductor p-n junction thermally coupled to the integrated circuit. Responsive to the thermal flux produced by the integrated circuit, the structure generates electrical energy. The generated electrical energy may be stored for use by the integrated circuit.

Abstract: Systems and methods for harvesting dissipated heat from integrated circuits (ICs) in electronic devices into electrical energy for providing power for the electronic devices are disclosed. In one embodiment, energy transferred from one or more ICs in the form of dissipated heat is harvested to convert at least a portion of this dissipated heat into electricity. This power can be used to provide power to the ICs to reduce overall power consumption by the electronic device. The harvested dissipated heat can be supplied to ICs in the electronic device to provide power to the ICs. Alternatively, or in addition, the harvested dissipated heat can be stored in an energy storage device to provide power to the ICs at a later time.

Abstract: A thermoelectric generator utilizing a number of thermoelectric modules to produce electric power from waste heat when waste heat is available and from an alternate heat source when waste heat is not available. In both cases hot gasses are directed along several separate paths so that all of the modules are provided with approximately equal hot side temperatures. In a preferred embodiment the engine exhaust exits into an octagonally-shaped plenum into eight separate heat exchangers. Eight modules are mounted in each of the heat exchangers for a total of 64 modules. Preferred embodiments of the present invention include an auxiliary combustion burner-blower unit producing a hot exhaust that exits into the plenum to provide electric power when the truck is not operating. Valve features are provided to control the temperature and exhaust flow rate through the generator.

Abstract: A thermoelectric device is disclosed which includes metal thermal terminals protruding from a top surface of an IC, connected to vertical thermally conductive conduits made of interconnect elements of the IC. Lateral thermoelectric elements are connected to the vertical conduits at one end and heatsinked to the IC substrate at the other end. The lateral thermoelectric elements are thermally isolated by interconnect dielectric materials on the top side and field oxide on the bottom side. When operated in a generator mode, the metal thermal terminals are connected to a heat source and the IC substrate is connected to a heat sink. Thermal power flows through the vertical conduits to the lateral thermoelectric elements, which generate an electrical potential. The electrical potential may be applied to a component or circuit in the IC. The thermoelectric device may be integrated into an IC without adding fabrication cost or complexity.

Abstract: A portable device for supplying with power of at least one portable electrical load or gadget (70), wherein the device (10) is adapted to be manually heated and comprises at least one thermoelectric element (20) having one hot or warm side (21) and one cold side (22), a container (30) attached to the cold side (22) and adapted for holding or keeping a cooling medium or fluid (90) therein, a power converter (60) and a set of cables (65) coming out of the thermoelectric element (20) and connected to the electrical load (70) via the power converter (60).

Abstract: A lamp having a light emitting diode, a Peltier device, a heat sink, a translucent, thermally conductive window, and an optical fluid. The Peltier device is in thermal communication with the light emitting diode and converts a waste thermal energy discharged by the light emitting diode into an electrical energy. Conductors transfer the electrical energy from the Peltier device to a boost circuit which converts a level of a voltage associated with the electrical energy output from the Peltier device to a higher, more useful value. The heat sink transfers a second thermal energy from the Peltier device. The optical fluid is located between the translucent, thermally conductive window and the light emitting diode. The optical fluid has an angle of diffraction having an intermediate value relative to an angle of diffraction associated with the light emitting diode and an angle of diffraction associated with the translucent, thermally conductive window.

Abstract: An object of the invention is to provide a thermoelectric conversion material that can have a balance between flexibility and high thermoelectric conversion capacity, a thermoelectric conversion element using the material, and a device that uses waste heat of, for example, an electronic apparatus and a vehicle by using the element. Provided is a thermoelectric conversion element that includes a layer constituted by an organic material in which a fine particle of a carbon nanotube is dispersed and which has flexibility, preferably, a high glass transition temperature and low thermal conductivity, and in which a mass ratio of the carbon nanotube to the organic material is 50% by mass to 90% by mass, and a device in which the thermoelectric conversion element is installed to a heat release portion of an apparatus.

Abstract: A lamp having a light emitting diode, a Peltier device, a heat sink, a translucent, thermally conductive window, and an optical fluid. The Peltier device is in thermal communication with the light emitting diode and converts a waste thermal energy discharged by the light emitting diode into an electrical energy. Conductors transfer the electrical energy from the Peltier device to a boost circuit which converts a level of a voltage associated with the electrical energy output from the Peltier device to a higher, more useful value. The heat sink transfers a second thermal energy from the Peltier device. The optical fluid is located between the translucent, thermally conductive window and the light emitting diode. The optical fluid has an angle of diffraction having an intermediate value relative to an angle of diffraction associated with the light emitting diode and an angle of diffraction associated with the translucent, thermally conductive window.

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: An integrated circuit with an embedded heat exchanger for coupling heat to an embedded thermoelectric device from a thermal source that is electrically isolated from a thermoelectric device. A method for forming an integrated circuit with an embedded heat exchanger.

Abstract: A thermoelectric conversion module which has a P-type thermoelectric conversion material and an N-type thermoelectric conversion material electrically connected to each other. The P-type thermoelectric conversion material and the N-type thermoelectric conversion material are joined with insulating material particles (ceramic spherical particles) interposed therebetween, so as not to be electrically connected to each other.

Abstract: A thermoelectric generator has a hot side heat exchanger having a silicon carbide (SiC) honeycomb support with a plurality of passages. The passage walls are coated with a pyrophoric solid fuel such as red oxide (Fe2O3) in combination with a silicon (Si) binder. A quantum well thermoelectric device is positioned between the hot side heat exchanger and heat sink. The performance of the thermoelectric generator is comparable to fuel cells. The thermoelectric generator is small and portable.

Abstract: In accordance with the invention, there are electrocaloric devices, pyroelectric devices and methods of forming them. A device which can be a pyroelectric energy generator or an electrocaloric cooling device, can include a first reservoir at a first temperature and a second reservoir at a second temperature, wherein the second temperature is higher than the first temperature. The device can also include a plurality of liquid crystal thermal switches disposed between the first reservoir and the second reservoir and one or more active layers disposed between the first reservoir and the second reservoir, such that each of the one or more active layers is sandwiched between two liquid crystal thermal switches. The device can further include one or more power supplies to apply voltage to the plurality of liquid crystal thermal switches and the one or more the active layers.

Abstract: A portable device for supplying with power of at least one portable electrical load or gadget (70), wherein the device (10) is adapted to be manually heated and comprises at least one thermoelectric element (20) having one hot or warm side (21) and one cold side (22), a container (30) attached to the cold side (22) and adapted for holding or keeping a cooling medium or fluid (90) therein, a power converter (60) and a set of cables (65) coming out of the thermoelectric element (20) and connected to the electrical load (70) via the power converter (60).

Abstract: The present invention relates to a thermoelectric conversion device using a solvating material, the device comprising: a cell with a closed structure, comprising a metal ammonia or metal amine compound as a solvating material; a polarization or porous separation membrane; and a heating unit, which prevents the outflow of the solvating material and thus maintains the solvating material in a reversible state.

Abstract: A thermoelectric device is provided. The thermoelectric device includes a P-type thermoelectric component, an N-type thermoelectric component, and an electrically conductive layer. Each of the P-type thermoelectric component and the N-type thermoelectric component includes a substrate and a nanowire structure. The conductive layer connects the P-type thermoelectric component set with the N-type thermoelectric component set. The thermoelectric device is adapted for recycling heat generated by the heat source, and for effectively converting the heat into electrical energy.

Abstract: Traditional power generation systems using thermoelectric power generators are designed to operate most efficiently for a single operating condition. The present invention provides a power generation system in which the characteristics of the thermoelectrics, the flow of the thermal power, and the operational characteristics of the power generator are monitored and controlled such that higher operation efficiencies and/or higher output powers can be maintained with variably thermal power input. Such a system is particularly beneficial in variable thermal power source systems, such as recovering power from the waste heat generated in the exhaust of combustion engines.

Abstract: A computer system has a chassis, a plurality of interconnected panels mounted on the chassis in a manner defining an interior space at least partially encompassed by the panels, a circuit assembly, an electrically-powered fan within the interior space, and an energy conversion device mounted within the interior space. One or more of the panels has an airflow opening therein. The circuit assembly is mounted on the chassis within the interior space and includes a heat generating system component. The heat generating system component includes a surface from which energy in the infrared (IR) electromagnetic spectrum is emitted during operation thereof. The energy conversion device is configured for converting the emitted infrared energy to electrical energy and is electrically connected to the electrically-powered fan for providing the electrical energy thereto.

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

Abstract: Electrical energy is generated in a device that includes an integrated circuit which produces thermal flux when operated. A substrate supports the integrated circuit. A structure is formed in the substrate, that structure having a semiconductor p-n junction thermally coupled to the integrated circuit. Responsive to the thermal flux produced by the integrated circuit, the structure generates electrical energy. The generated electrical energy may be stored for use by the integrated circuit.

Abstract: The present invention provides an energy converting device, which includes: a base substrate; and a plurality of thermoelectric element structures which are sequentially stacked on the base substrate and electrically interconnected in parallel to one another.

Abstract: A semiconductor device is disclosed that can operate utilizing thermoelectric concepts. According to an embodiment, the semiconductor device can comprise: a source/drain conductor formed of a line of metal material on a substrate; a first gate conductor formed of a second line of metal material; and a second gate conductor formed of a third line of metal material, wherein the first gate conductor is disposed adjacent a first portion of the source/drain conductor at one end of the source/drain conductor and the second gate conductor is disposed spaced apart from the first gate conductor and adjacent a second portion of the source/drain conductor at the other end of the source/drain conductor. By applying current to the first gate conductor and the second gate conductor, current can be supplied from the one end of the source/drain conductor to the other end of the source/drain conductor.

Abstract: A temperature power generation device includes a temperature reactive layer made of high thermal energy absorbing material and a thermal electron generation layer made of low work function material. A temperature power generation method by using the temperature reactive layer and the thermal electron generation layer to absorb heat and generate thermal electrons which are then induced to a conductive layer through an externally applied electric field, and the generated thermal electrons are then further transferred via an electricity output component to an output load for providing power.

Abstract: Conversion of solar heat into electrical energy is achieved using a parabolic reflector, a heat transfer medium, a high-density heat store and a thermoelectric generator. The system is useful for various forms of stationary and moving applications. Using stored heat derived from sunlight provides day and night electrical supply over many days depending on the size of the solar collector and heat store. Moving applications are achieved using a mobile heat store with attached thermoelectric generator.

Abstract: Provided are, a power supplier including an assistant power supply unit, an electronic device including the power supplier, and a method of operating the electronic device using the power supplier in a power-saving mode. The assistant power supply unit includes: a heat source to generate heat during operation of the electronic device; a cooler to dissipate the heat generated by the heat source; a thermoelectric generator interposed between the heat source and the cooler; and a secondary battery to store power generated by the thermoelectric generator.

Abstract: In a heat tracing system using heat from a radiant heater to heat a circulating fluid, thermoelectric generation modules are used to generate electricity for powering a circulating pump. Thermoelectric power generation modules are sandwiched between a heat-absorbing plate and a heat sink, and this assembly is positioned with the heat-absorbing plate adjacent to a radiant heater. A conduit loop passes through the heat sink, such that a fluid circulating through the conduit is heated from heat drawn from the heater into the heat sink. Due to the temperature differential between the hot and cold sides of the thermoelectric modules, the modules produce electricity to power the pump circulating the fluid through the conduit loop. Supplementary heat exchanger components may be provided for additional fluid-heating capacity, and thereby increasing the amount of heat available for the heat tracing loop.

Abstract: Thermoelectric materials, devices, and systems are presented. One embodiment is a composite material comprising a matrix comprising a thermoelectric material; and an electrically conducting phase disposed within the matrix. The electrically conducting phase has a lower electrical resistivity than the thermoelectric material, and it forms a continuous electrically conducting path through the matrix from a first surface of the material to a second surface of the material. Another embodiment is a device, comprising a thermoelectric element. This element is made of the above composite material. A further embodiment is a thermoelectric system, made of a heat source, a heat sink, and the thermoelectric device disposed in thermal communication with the heat source and heat sink. The system may be configured for power generation or for thermal management.

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: Methods and apparatus for generating an information signal. Exemplary methods and apparatus may comprise (A) electrically associating at least one LED with a Seebeck power generator; (B) thermally associating the Seebeck power generator with a surface; and (C) heating the surface to cause the Seebeck power generator to generate electricity to energize the at least one LED. In one example, such methods and apparatus may be used to provide an indication of the temperature of a surface.

Abstract: A heat of fusion thermoelectric generator. A heat source is in thermal contact with a phase change material, wherein the heat source is capable of providing sufficient heat so as to be able to melt the phase change material. The phase change material is in thermal contact with a hot side heat sink. At least one thermoelectric module is disposed between and in thermal contact with the hot side heat sink and a cold side heat sink. Electric power is generated by the thermoelectric module from a temperature difference between the hot side heat sink and the cold side heat sink.

Abstract: A method and apparatus for the comparision of AC signals by electrothermal means in which both signals are applied to an electrothermal converter, such as a thermocouple converter or a thermoresistive converter, and the temperature produced by the signals is converted to a difference signal. The DC component of the difference signal is used to maintain the electrothermal converter at a stable operating temperature. The AC component of the difference signal is used to indicate the difference between two signals when used as a comparator, to control the amplitude of a reference standard's output when used as a voltmeter or calibration standard, and also to control the amplitude of an oscillator when used as a calibration standard.

Abstract: An apparatus for use in connecting adjacent cells of storage batteries electrically and mechanically by passing an electric current through electrical resistance elements to cause a rapid heating of said elements and of battery terminal parts disposed in engagement therewith.