A rotor (1) for an electric machine (2) includes at least one sensor element (3) configured for detecting condition variables of the rotor (1), a signal processing unit (4) connected to the at least one sensor element (3) and configured for generating measured data from the detected condition variables of the rotor (1) and transmitting the measured data to a control device (5), and a nanogenerator (6) configured for generating electrical energy from at least one surroundings variable and supplying the at least one sensor element (3) and the signal processing unit (4) with electrical energy.

A heat conversion apparatus according to one embodiment of the present invention comprises: a pipe which includes a first flat surface and a second flat surface disposed parallel to the first surface, and through which air having a lower temperature than entered air is discharged; a plurality of thermoelectric elements that have heat-absorbing surfaces disposed in external sides of the respective first and second surfaces; a plurality of printed circuit boards (PCBs) that are electrically connected to the plurality of thermoelectric elements; and coolant passing members that are disposed on heat-radiating surfaces of the plurality of thermoelectric elements, wherein an external floor surface of the coolant passing member includes a plurality of first external floor surfaces having a first height and a plurality of second external floor surfaces having a second height that is different from the first height, the plurality of first external floor surfaces are in contact with the heat-radiating surfaces of the plurality of thermoelectric elements, and the plurality of PCBs are disposed in the plurality of second external floor surfaces.

An exhaust-gas electricity generation unit is provided between an engine unit and a discharge unit. The exhaust-gas electricity generation unit includes a connecting pipe connecting the engine unit to the discharge unit and defining an exhaust-gas flow passage in which exhaust gas expelled from the engine unit flows, a plurality of thermoelectric conversion modules provided on an inner surface of the connecting pipe, along flow of heat, near the engine unit and near the discharge unit, and a flow-velocity increasing mechanism for causing the exhaust gas in the connecting pipe to have an increased flow velocity near the discharge unit than near the engine unit.

An energy recovery unit (8) for use in a vehicle exhaust system (6) comprises an inlet (24) for receiving exhaust gas from the exhaust system (6); an outlet (26) for returning exhaust gas to the exhaust system (6); a thermoelectric generator (20) disposed between the inlet (24) and the outlet (26); and a valve arrangement operable to direct exhaust gas entering the inlet (24) across the thermoelectric generator (20) to enable the thermoelectric generator (20) to generate electrical energy from thermal energy contained in the exhaust gas, wherein the valve arrangement is operable to vary the direction of exhaust gas flow across the thermoelectric generator (20).

The present invention relates to a feedback device and a thermal feedback provision method using the same. The thermal feedback provision method may include checking first operating power applied to a first thermoelectric couple group for a first thermoelectric operation and second operating power applied to a second thermoelectric couple group for a second thermoelectric operation when the first thermoelectric operation is initiated in the first thermoelectric couple group to initiate the output of the first thermal feedback after the second thermoelectric operation is initiated in the second thermoelectric couple group to initiate the output of the second thermal feedback and include applying cognitive enhancement power for enhancing a user's cognition to the first thermoelectric couple group from a time point at which the output of the first thermal feedback is initiated up to a first time point so that the user's cognition of the first thermal feedback is enhanced.

A light detection and measurement device comprises a silicon photomultiplier, at least one thermoelectric cooler thermally coupled to the silicon photomultiplier, a sealed enclosure surrounding the silicon photomultiplier and the at least one thermoelectric cooler, the enclosure including a substantially transparent window thermally coupled to the silicon photomultiplier, and a heat sinking device thermally coupled to the enclosure configured to remove waste heat. A method of cooling a silicon photomultiplier is also described.

A system on an integrated circuit (IC) chip includes an input terminal and a return terminal, a heater, a thermopile, and a switch device. The heater is coupled between the input terminal and the return terminal. The thermopile is spaced apart from the heater by a galvanic isolation region. The switch device includes a control input coupled to an output of the thermopile. The switch device is coupled to at least one output terminal of the IC chip.

The present disclosure is directed to materials, devices, and methods for resonant ambient thermal energy harvesting. Thermal energy can be harvested using thermoelectric resonators that capture and store ambient thermal fluctuations and convert the fluctuations to energy. The thermal resonators can include heat engines disposed between masses of varying sizes or diodes. The masses or diodes can be made of high and ultra-high effusivity materials to transfer thermal energy through the resonator and optimize power output. The masses or diodes of the resonator can be tuned to the dominant frequency of the temperature waveform to maximize the amount of energy being converted. The resonators can be added to existing structures to supply or generate power, and, in some embodiments, the structures themselves can be a mass of the thermal resonator. Methods for constructing and/or using such devices are also provided, as are methods for formulating ultra-high effusivity materials.

An air duct system comprising an air duct having a main body, a visible light source, an emitter configured to emit radio frequency waves, and one or more antennas. The main body of the air duct defines a passageway having a reflective inner surface. The visible light source is configured to generate visible light. The visible light source directs the visible light along the reflective inner surface of the air duct. The emitter directs the radio frequency waves along the reflective inner surface of the air duct. The one or more antennas are each connected to a corresponding power harvesting circuit, where the radio frequency waves are received by the one or more antennas and are converted into electrical power by the corresponding power harvesting circuit.

A lawn mower has an electrical port that receives current from an alternator powered by the lawn mower engine. The current and voltage sent the electrical port depend on a flywheel and stator arrangement operatively connected to the alternator. The stator may be replaceable or interchangeable to selectively determine the alternator current and voltage output. The port receives a plug from a garment worn by the lawn mower operator. The garment includes one or more thermo-electric elements that are powered from current extending through the port. The thermo-electric elements may be resistive heaters to warm the operator or TEC coolers to cool the operator. Furthermore, the garment may include a rechargeable battery that powers the thermo-electric elements when the plug is disconnected from the port.