Abstract: A thermionic converter for converting thermal energy to electrical energy includes an emitter and a collector. The emitter emits thermionic electrons upon receipt of heat from a heat source. The emitter is made of a first semiconductor material to which a first semiconductor impurity is doped with a first concentration. The collector is spaced and opposite to the emitter to receive the thermionic electrons emitted from the emitter so that the thermal energy is converted to electrical energy. The collector is made of a second semiconductor material to which a second semiconductor impurity is doped with a second concentration less than the first concentration.

Abstract: Methods and devices for increase power output from solar devices. In one embodiment, the technique enables the front hot solar panel surface to be cooled by attachment of a thermoelectric multilayer stack to the back solar panel surface. The thermoelectric stack cools the solar panel front surface by drawing heat from the front to the back of the panel. That heat is transformed into mechanical vibrations using an inverse Peltier effect and that mechanical energy then transformed into electrical energy using a piezoelectric effect. Power output is first increased by lower operating temperature on front, resulting in a higher power conversion efficiency for the photovoltaic effect taking place in the CIGS/CdS active layers or other thin films, then from an additional power output from secondary electrical energy created from mechanical arising from the temperature-gradient driven occurrence of the thermoelectric effect.

Abstract: A method for converting heat to electric energy is described which involves thermally cycling an electrically polarizable material sandwiched between electrodes. The material is heated by extracting thermal energy from a gas to condense the gas into a liquid and transferring the thermal energy to the electrically polarizable material. An apparatus is also described which includes an electrically polarizable material sandwiched between electrodes and a heat exchanger for heating the material in thermal communication with a heat source, wherein the heat source is a condenser. An apparatus is also described which comprises a chamber, one or more conduits inside the chamber for conveying a cooling fluid and an electrically polarizable material sandwiched between electrodes on an outer surface of the conduit. A gas introduced into the chamber condenses on the conduits and thermal energy is thereby transferred from the gas to the electrically polarizable material.

Abstract: A thermo-mechano-electric converter including a plurality of shape memory bistable elements embedded in a resilient material intimately associated with a piezoelectric material.

Abstract: A device for converting heat energy into electrical energy including cells, the cells including: a first cavity with one wall for contacting a heat source; a second cavity with one wall for contacting a cold source; a primary channel between the first cavity and the second cavity transporting a fluid as liquid drops, the primary channel providing transport of liquid fluid drops from the second cavity to the first cavity; at least one secondary channel between the first cavity and the second cavity transporting the fluid as a gas; a piezoelectric material provided in one of the cavities; and a fluid as a liquid and gas contained within the cell.

Abstract: A power-generating system includes a heat source which is able to produce temporal temperature variation; a first device which is able to produce temporal temperature variation based on the temperature change of the heat source and in which polarization occurs; a second device for taking out a net generating power from the first device; a detection unit that detects the temperature of the first device; an electric field application unit that applies an electric field to the first device; and a control unit for activating the electric field application unit when the temperature detected by the detection unit is the Curie temperature of the first device or higher.

Abstract: An apparatus harvests electrical power from mechanical energy. The apparatus includes first and second load-bearing structures, a plurality of magnetostrictive elements, and an electrical circuit or coil. The load-bearing structures experience a force from an external source. The magnetostrictive elements are arranged between the load-bearing structures. The load-bearing structures transfer at least a portion of the force to at least one of the magnetostrictive elements. In this way, at least one of the magnetostrictive elements experiences the force transferred from the load-bearing structures. The force on the magnetostrictive element causes a change in magnetic flux of the magnetostrictive element. The electrical circuit or coil is disposed within a vicinity of the magnetostrictive element which experiences the force. The electrical circuit or coil generates electric power in response to the change in the magnetic flux of the magnetostrictive element.

Abstract: A float operated lever device for wave energy conversion comprising at least one force amplifying lever, a pivot secured on a secured platform, a buoyant float attached to said lever and a latch means secured in position for obstructing the motion of said force amplifying lever for a fraction of half wave's period, when said float is nearly at its highest and lowest positions whereby said force amplifying lever travels downward or upward respectively, at a greater velocity and for a greater distance than in the case of free floating thus producing an amplified output force, pivoting speed and angular displacement. A method for thermal energy storage and retrieval of electricity in phase change material.

Abstract: A device and method for producing electricity by harnessing sunlight to produce an amplified voltage signal, the device including: (a) a sealed chamber, defined by a transparent housing; (b) an excitable medium, disposed within the chamber, in which, when the medium is exposed to solar light having wavelengths in a range of 0.

Abstract: A thermoelectric generator including a membrane maintained by lateral ends and capable of taking a first shape when its temperature reaches a first threshold and a second shape when its temperature reaches a second threshold greater than the first threshold; and mechanism capable of converting the motions and the deformations of the membrane into electricity.

Abstract: In one aspect of the invention, a thermionic energy converter comprises an anode, a cathode spaced from the anode to define a gap therebetween, and molecular hydrogen incorporated into the gap.

Abstract: A device is described wherein a pair of thermal or electrothermal actuators (3, 4; 103, 104) actuate a member, such as a pinion (5), between two stable positions. The actuators are alternately activated for moving the pinion between the stable positions. For this purpose, they are arranged close to each other, so that they can act upon the pinion on opposite sides, the pinion being held in the stable positions by a releasable engagement element. The device of the invention ensures low energy consumption because the actuators (3, 4) operate only for moving the pinion from one stable position to the other.

Abstract: A system for generating electrical energy includes a thermal source, an electric field source, a stress source, a piezoelectric component, and a cycle controller coupled to the thermal source, the electric field source, and the stress source. The cycle controller provides control signals to the thermal source, the electric field source, and the stress source to repeatedly cycle the piezoelectric component through the sequence: (a) application of: a first temperature, a first electric field, and a first stress; (b) application of: the first temperature, a second electric field greater than the first electric field, and the first stress; (c) application of: a second temperature, the second electric field, and a second stress greater than the first stress; and (d) application of: the second temperature, the first electric field, and the second stress.

Abstract: A three-dimensional microelectromechanical systems (MEMS) structure includes a substrate and having a height extending outwardly from the substrate and a largest lateral dimension orthogonal to the height. The largest lateral dimension is smaller than the height. A transducing element is operatively connected to the hair-like core and embedded within, formed on an outer surface of, or disposed at a root of the hair-like core. The transducing element is to receive an electrical core signal or a non-electrical core signal conveyed by the hair-like core. The transducing element is to convert the non-electrical core signal to an electrical output signal, convert the electrical core signal to an electrical output signal in a different format, convert the non-electrical core signal to a different non-electrical output signal, or convert the electrical core signal to a non-electrical output signal.

Abstract: One variation may include a vehicle underhood heat absorber comprising at least one electrically conductive heat absorbing layer constructed and arranged to be connected to a vehicle battery to recharge the battery.

Abstract: A method and device for generating electrical energy in a motor vehicle involves thermoelectric generator having a plurality of thermoelectric modules and coupled to at least one electrical consumer. Module open-circuit voltages of the modules are determined and those modules for which a sum of their module open-circuit voltages attains twice a predefined generator output voltage with the smallest possible deviation are determined and electrically connected to one another in series.

Abstract: A method and system for using a method of pre-equilibrium ballistic charge carrier refraction comprises fabricating one or more solid-state electric generators. The solid-state electric generators include one or more of a chemically energized solid-state electric generator and a thermionic solid-state electric generator. A first material having a first charge carrier effective mass is used in a solid-state junction. A second material having a second charge carrier effective mass greater than the first charge carrier effective mass is used in the solid-state junction. A charge carrier effective mass ratio between the second effective mass and the first effective mass is greater than or equal to two.

Abstract: In a control valve for adjusting a process medium flow of a technical process installation, a housing is provided with an interior to be traversed by a process medium. A valve seat is disposed inside the housing interior. A valve member is provided obstructing or clearing the valve seat wherein a flow cross section of the control valve can be altered according to a relative position between the valve member and the valve seat for adjusting the process medium flow to initiate a pressure change in the process medium flow between an upstream and a downstream duct section. An electrical consumer is provided. A thermoelectric element is coupled to supply electrical power to the electrical consumer. The thermoelectric element is disposed at a position in the housing interior for generating the electrical power resulting from a temperature difference that accompanies a pressure difference at a location of said position of the thermoelectric element.

Abstract: A power-generating system includes a heat source which is able to produce temporal temperature variation, a first device in which polarization occurs based on the temperature change of the heat source, and a second device for taking out a net generating power from the first device, wherein 80% or higher of the total surface area of the first device is heated and/or cooled with the heat source.

Abstract: A reduction in power generation efficiency is suppressed in a mounted state to a living body, and a desired power generation capacity is ensured. A thermal power generation portable device 10 is mounted to the living body, is capable of generating power by the heat of this living body, and includes a thermal power generating member 20 that generates power on the basis of a temperature difference between a temperature at a heat-source-side position and a temperature at a heat release destination-side position between the living body that is a heat source and a heat release destination of heat released from the thermal power generation portable device 10, and a movable member 22 capable of changing the thermal resistance of at least a portion of a heat transfer path between the living body and the heat release destination.

Abstract: A power-generating system includes a heat source which is able to produce temporal temperature variation; a first device which is able to produce temporal temperature variation so as to include at least partially a temperature range of ?20° C. relative to the Curie temperature to +10° C. relative to the Curie temperature based on the temperature change of the heat source, and in which polarization occurs; and a second device for taking out a net generating power from the first device.

Abstract: The invention provides apparatus and methods for heating and cooling ferroelectric materials during a conversion between thermal and electrical energy. One method comprises the use of a fluid that performs repeated heating and cooling cycles, e.g., ‘thermal cycling’, of ferroelectric materials during the evaporation and condensation of a phase changing fluid. The systems, devices, and methods eliminate the need for external inputs such electrical or mechanical power, thereby improving the overall efficiency of the energy conversion. One apparatus comprises liquid-retaining wicks that helps fluid distribution and expands the range of operational environment for the energy system. Ultimately, the uniformity and speed of various embodiments of the thermal cycler apparatus and method provide improvements in conversion efficiency and reductions in parasitic loss over current thermal cyclers.

Abstract: A thermoelectric generator including a sheet of a deformable material containing closed cavities, each of which contains a drop of a vaporizable liquid, and a mechanism for transforming into electricity the power resulting from the deformation of the sheet linked to the evaporation/condensation of the liquid.

Abstract: Pulsed plasma engine and method in which a noncombustible gas is introduced into an explosion chamber, the gas is ionized to form a plasma within the chamber, an electrical pulse is applied to the plasma to heat the plasma, the pulse is turned off to produce an explosive pressure pulse in the plasma, and the plasma is confined in the chamber by a magnetic field that directs the pressure pulse toward an output member which is driven by the pressure pulse.

Abstract: Examples are generally described that include monitoring an electrocaloric effect device. A varying voltage may be applied across an electrocaloric effect material. A capacitance change of the electrocaloric effect material at least in part responsive to the varying voltage may be measured. A temperature change of the electrocaloric effect material may be calculated based, at least in part, on the capacitance change.

Abstract: A thermo-magnetic power generation system includes a thermo-magnetic power generation device, a first circulating device, and a second circulating device. The first circulating device and the second circulating device are connected to the thermo-magnetic power generation device. The liquid is heated by the first circulating device and cooled by the second circulating device. The heated liquid and the cooled liquid transmitted to the thermo-magnetic element are recycled by the first circulating device and the second circulating device.

Abstract: A wasted heat harvesting device for harvesting electricity including a switching device configured to convey a magnetic field from a first region to at least a second region when the temperature of the switching device crosses a predetermined temperature.

Abstract: A carbon nanotube MEMS assembly comprises a plurality of carbon nanotubes oriented into a patterned frame, the patterned frame defining at least two components of a MEMS device. An interstitial material at least partially binds adjacent carbon nanotubes one to another. At least one component of the frame is fixed and at least one component of the frame is movable relative to the fixed component.

Abstract: A power-generating device is disclosed that includes a pyroelectric material having first and second surfaces on opposite sides of the pyroelectric material. The device also includes a first conductive electrode coupled to a first support element that is configured to intermittently bring the first electrode into proximity with the first surface and a second conductive electrode proximate to the second surface at least while the first electrode is proximate to the first surface. The device also includes a power module that is electrically coupled between the first and second electrodes. The power module is configured to capture power from an electrical current flowing between the first and second electrodes.

Abstract: A power generation device is disclosed, which includes a plurality of thermomagnetic generator and a flow controller. The thermomagnetic generators can acquire first fluids respectively. The flow controller can control flow rates of the second fluids flowing into the thermomagnetic generators respectively, wherein a fluid temperature of the first fluid is different from a fluid temperature of the second fluid.

Abstract: A method and apparatus for generating 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. 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: Techniques herein describe a pumping system, adapted to reduce or eliminate fluid cavitation. Optionally, the pumping system is adapted for application to a passive fluid recovery system. In one example, the pumping system includes a pump and a thermal sub-cooling device. The thermal sub-cooling device may sub-cool fluid input to a pump and heat fluid output from the pump, particularly under start-up conditions. In a further example, a controller manages power supplied to both the pump and the thermal sub-cooling device, to transition from an ambient temperature start-up condition to an elevated temperature operating condition.

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 thermoelectric generator comprises an electrical circuit having two or more thermocouple junctions (600, 615), a switch (620), a controller (640), and a series resonant circuit consisting of a capacitor (625) and an inductor in the form of a transformer (630). The thermocouple junctions operate between two temperature reservoirs (605, 610) operating at temperatures T2 and T1, respectively, that are sufficiently different to enable the circuit to supply power to a load (635). Using sense lines (650, 655) the controller forces the switch to advance to the next throw at the proper time, forcing the circuit to operate at or near resonance. With each operation of the switch, one junction at a time is connected to the resonant circuit, while one or more junctions are left in an open-circuit condition. By allowing the temporarily disconnected junctions sufficient time to reach thermal equilibrium with the temperature reservoirs, isothermal equilibrium is achieved.

Abstract: A thermionic energy converter is provided that includes an anode, a cathode, where the anode is disposed opposite the cathode, and a suspension, where a first end of the suspension is connected to the cathode and a second end of the suspension is connected to the anode, where the suspension moveably supports the cathode above the anode to form a variable gap between the anode and the cathode, where the variable gap is capable of enabling a variable thermionic current between the anode and the cathode, where the thermionic converter is capable of an AC power output.

Abstract: The invention discloses a heat-power conversion magnetism device. The heat-power conversion magnetism device includes a magneto caloric effect material so that the magnetic field thereof can be changed according to the temperature difference. The heat-power conversion magnetism device rotates by changing the magnetic field of the magneto caloric effect material.

Abstract: A microelectromechanical resonator includes a resonator body anchored to a substrate by at least a pair of tethers that suspend the resonator body opposite an underlying opening in the substrate. A first thermally-actuated tuning beam is provided, which is mechanically coupled to a first portion of the resonator body that is spaced apart from the pair of tethers. The first thermally-actuated tuning beam is configured to induce a mechanical stress in the resonator body by establishing a thermal expansion difference between the first thermally-actuated tuning beam and the resonator body in response to a passing of current through the first thermally-actuated tuning beam.

Abstract: An object of the invention is to provide a cheap, efficient and polyvalent energy harvesting system able to exploit several energy sources. The invention proposes an energy harvesting system (100) comprising a frame, at least one permanent magnet (101) having a North/South direction, and at least one winding (107, 108) wound according to a winding direction around a core (103a-103b) comprising a high magnetic permeability material, at least said at least one permanent magnet being mounted on the frame to be able to oscillate relatively to the winding, characterized in that the system comprises a magnetic flux divider arranged between said at least one permanent magnet and said at least one winding in order to concentrate the magnetic flux at discrete positions of maximum magnetic flux then forming equilibrium positions where the winding faces one of the said discrete positions of maximum magnetic flux.

Abstract: A thermoacoustic energy converter for converting heat energy to electricity includes an annular resonator with a regenerator disposed therein. An electro-mechanical transducer is coupled to the annular resonator and in fluid communication with the working fluid. When heat is applied to one end of the annular resonator, a traveling acoustic wave is generated in the annular resonator causing vibrations in the working fluid that actuate the electro-mechanical transducer to generate electricity.

Abstract: A current source and method of producing the current source are provided. The current source includes a metal source, a buffer layer, a filter and a collector. An electrical connection is provided to the metal layer and semiconductor layer and a magnetic field applier may be also provided. The source metal has localized states at a bottom of the conduction band and probability amplification. The interaction of the various layers produces a spontaneous current. The movement of charge across the current source produces a voltage, which rises until a balancing reverse current appears. If a load is connected to the current source, current flows through the load and power is dissipated. The energy for this comes from the thermal energy in the current source, and the device gets cooler.

Abstract: Provided is an energy harvesting device using pyroelectric materials. The energy harvesting device includes a first heat source; a second heat source having a temperature higher than a temperature of the first heat source; and a cantilever which is interposed between the first heat source and the second heat source, the cantilever including a first film formed of a pyroelectric material and a second film, where the first film is disposed on the second film and a thermal expansion coefficient of the second film is different from that of the pyroelectric material of the first film. Electric energy is generated by periodically changing a temperature within the first film.

Abstract: An energy harvester including first and second sheets; and a plurality of walls, each wall being sandwiched between the first and second sheets and surrounding a cavity, wherein each cavity houses at least one curved plate adapted to change from a first shape to a second shape when its temperature reaches a first threshold and to return to the first shape when its temperature falls to a second threshold lower than said first threshold.

Abstract: A sensing system, sensing method, and method of producing a sensing system capable of providing a cumulative measurement capability, such as in the form of a RFID tag capable of measuring cumulative heat and humidity for continuous monitoring of storage and shipping conditions of various goods. The system includes integrated circuitry and a plurality of sensing elements, preferably having cantilevered bimorph beams. Each sensing element is responsive to an environmental condition so as to deflect toward and away from open contacts in response to changes in the environmental condition. Each sensing element produces a digital output when it contacts and closes its open contacts. The integrated circuitry interfaces with the sensing elements so that the digital outputs of the sensing elements are processed to generate a system output of the sensing system.

Abstract: A suppressor grid is configured proximate to an anode to produce a suppressor electric field selected to provide a force on an electron in a direction pointing away from the anode, wherein the suppressor electric field is further selected to pass electrons from the suppressor grid to the anode.

Abstract: A method, an apparatus and/or a system of non-decaying electric power generation from pyroelectric materials is disclosed. In one aspect, a method includes generating a substantially continuous electric energy from an at least one layer of pyroelectric material when the at least one layer of pyroelectric material is subjected to a temporal temperature gradient, a varying electric field and/or a mechanical oscillation.

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: A storing section (70) stores a second initial contact instruction value, which is predefined as an instruction value for positioning a movable portion (5) to a second contact position where the movable portion (5) is contacted with a stopper (8), and an initial standby instruction value, which is predefined as an instruction value for positioning the movable portion (5) to a specified standby position within a moving range of the movable portion (5). A correcting section (42) calculates an actual standby instruction value by correcting the initial standby instruction value, based on a second actual contact instruction value obtained when a contact detection section (41) has detected that the movable portion (5) is positioned to the second contact position, and the second initial contact instruction value. A setting section (43) sets a standby position corresponding to the actual standby instruction value, as an actual standby position of the movable portion (5).

Abstract: A thermomagnetic generator which converts thermal energy to electrical energy without intermediate conversion to mechanical work and which works at temperatures in the range from ?20° C. to 200° C. comprises a thermomagnetic material selected from, for example, (1) compounds of the general formula (I) (AyBy?1)2+?CwDxEz??(I) where A is Mn or Co, B is Fe, Cr or Ni, C, D and E at least two of C, D and E are different, have a non-vanishing concentration and are selected from P, B, Se, Ge, Ga, Si, Sn, N, As and Sb, where at least one of C, D and E is Ge or Si, ? is a number in the range from ?0.1 to 0.1, w, x, y, z are numbers in the range from 0 to 1, where w+x+z=1.

Abstract: An energy harvester (100) comprising a base (110); one or more first resilient means (120) mounted on the base (110); a hollow chamber (130) having a mounting point (131) pivotally attached to the first resilient means (120) in static equilibrium in such a way that centre of mass of the hollow chamber (130) is aligned with the first resilient means (120) at the vertical axis; a hollow member (140) enclosed within the hollow chamber (130) being attached to one or more second resilient means (150) extending from the mounting point (131) in static equilibrium that centre of mass of the hollow member (140) is aligned with the second resilient means (150) at the vertical axis; a plurality of piezoelectric material-built cantilevers (160) mounted on the hollow member (140) and spaced apart from one another in a predetermined gap at the vertical planar that the piezoelectric material-built cantilevers (160) are varied in length and/or centre of mass; a primary storage (170) associated with the hollow chamber (130),

Abstract: A method and system for using a method of pre-equilibrium ballistic charge carrier refraction comprises fabricating one or more solid-state electric generators. The solid-state electric generators include one or more of a chemically energized solid-state electric generator and a thermionic solid-state electric generator. A first material having a first charge carrier effective mass is used in a solid-state junction. A second material having a second charge carrier effective mass greater than the first charge carrier effective mass is used in the solid-state junction. A charge carrier effective mass ratio between the second effective mass and the first effective mass is greater than or equal to two.