There is provided a far infrared (FIR) sensor device including a substrate, a thermopile structure and a heat absorption layer. The thermopile structure is arranged on the substrate. The heat absorption layer covers upon the thermopile structure, wherein the heat absorption layer has a hollow space which is formed by etching a metal layer in the heat absorption layer.

A heat conversion apparatus according to one embodiment of the present invention comprises: a duct through which cooling fluid passes; a first thermoelectric module disposed on a first surface of the duct; a second thermoelectric module disposed on a second surface, which is disposed in parallel to the first surface, of the duct; and a gas guide member disposed above a third surface disposed between the first surface and the second surface of the duct so as to be spaced from the third surface, wherein the gas guide member includes one end thereof coming in contact with the first thermoelectric module, the other end thereof coming in contact with the second thermoelectric module, and an extended part for connecting the one end and the other end, and the gas guide member can have a form in which the distance thereof from the third surface gradually increases toward the center between the one end and the other end.

Embodiments relate to systems designed for thermal transfer augmentation and thermionic energy harvesting. Thermionic energy harvesters are configured to supply electricity for applications such as electronics, communications, and other electrical devices. Thermal transfer may be used for a variety of heating/cooling and power generation/heat recovery systems, such as, refrigeration, air conditioning, electronics cooling, industrial temperature control, waste heat recovery, off-grid and mobile refrigeration, and cold storage.

A thermionic energy converter, preferably including an anode and a cathode. An anode of a thermionic energy converter, preferably including an n-type semiconductor, one or more supplemental layers, and an electrical contact. A method for work function reduction and/or thermionic energy conversion, preferably including inputting thermal energy to a thermionic energy converter, illuminating an anode of the thermionic energy converter, thereby preferably reducing a work function of the anode, and extracting electrical power from the system.

A lawn mower or stand-on powered drivable machine has an electrical port that receives current from an alternator powered by the engine or motor. 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 (TEC) 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.

A cooling sub-assembly for cooling a heat dissipating electronic device. The sub-assembly may include a vapor chamber, a peltier element and a coldplate placed on top of each other forming a stack such that the peltier element is sandwiched between the vapor chamber and the coldplate. The vapor chamber has a head facing the peltier element, a foot for facing the heat dissipating electronic device, and a wall extending between the foot and the head. The area of the head is larger than the area of the foot.

A thermoelectric conversion module includes: a first substrate and a second substrate that positionally oppose each other; a thermoelectric element group that is located between the first substrate and the second substrate and is connected to the first substrate and the second substrate; a first temperature detection element that is located between the first substrate and the second substrate and is connected to the first substrate; and a second temperature detection element that is located between the first substrate and the second substrate and is connected to the second substrate.

A method of manufacturing an integrated circuit structure includes forming active regions, forming source/drain regions, and forming conductive segments resulting in a thermoelectric structure including a p-type region positioned on a front side of the substrate, an n-type region positioned on the front side of the substrate, and a wire on the front side of the substrate configured to electrically couple the p-type region to the n-type region. The method includes forming a first via configured to thermally couple the p-type region to a first power structure on a back side of the substrate, forming a second via configured to thermally couple the n-type region to a second power structure on the back side of the substrate, and electrically coupling an energy device to each of the first and second power structures.

A thermoelectric power generation system includes a first flow path, along which a first fluid flows, a second flow path, along which a second fluid having a lower temperature than the first fluid flows, a thermoelectric module arranged between the first flow path and the second flow path, and a controller that switches between a power generation mode and a heating mode. In the power generation mode, the thermoelectric module is caused to generate electric power, based on a difference between a temperature of the first fluid and a temperature of the second fluid. In the heating mode, a first surface of the thermoelectric module is heated using the Peltier effect caused by supplying electric power to the thermoelectric module. A distance between the first surface and the first flow path is shorter than a distance between the first surface and the second flow path.

With a thermo-siphon type heat exchanger including a heating section of and a heat transfer pipe of a thermoelectric power generation unit, the thermoelectric power generator recovers a heat from a hot gas flowing through a flow path and generates electricity. To the thermo-siphon type heat exchanger, a storage tank that stores a heat medium is connected in a communication state; transferring of the heat medium from the thermo-siphon type heat exchanger to the storage tank, and returning of the heat medium from the storage tank to the thermo-siphon type heat exchanger can adjust the heat medium amount in the thermo-siphon type heat exchanger. At least a part of the storage tank is placed in the flow path so that the stored heat medium is heated, and the stored heat medium can be cooled with a cooler that is capable of turning a cooling function ON/OFF.