To protect the surface of a member exposed to a high-temperature environment and detect surface temperature or heat flow distribution, this magnetic thermoelectric conversion element, which is provided on the surface of a support in contact with a heat source, has: a magnetic body; an electromotive body which is magnetically coupled to the magnetic body and has electrical conductivity; and a heat-resistant metal oxide film covering the magnetic body and the electromotive body.

A generator configured to generate electrical energy from heat, for example from sunlight. The generator includes: a moveable carrier connected to a kinetic-electric converter; and a stationary support. One of the carrier and the support is provided with a magnet and the other is provided with separate ferromagnetic elements. A heat supply is associated with the one of the carrier and the support that is provided with the magnet to direct heat onto successively at least one of the ferromagnetic elements to warm the ferromagnetic element to above a Curie temperature thereof, to thereby impart reciprocal movement of the carrier relative to the support through magnetic interaction between the magnet and the ferromagnetic elements. A cooling system such as a thermo-electric generator or a heat sink is configured for cooling at least one of the magnet and the ferromagnetic elements.

A generator configured to generate electrical energy from heat, for example from sunlight. The generator includes: a moveable carrier connected to a kinetic-electric converter; and a stationary support. One of the carrier and the support is provided with a magnet and the other is provided with separate ferromagnetic elements. A heat supply is associated with the one of the carrier and the support that is provided with the magnet to direct heat onto successively at least one of the ferromagnetic elements to warm the ferromagnetic element to above a Curie temperature thereof, to thereby impart reciprocal movement of the carrier relative to the support through magnetic interaction between the magnet and the ferromagnetic elements. A cooling system such as a thermo-electric generator or a heat sink is configured for cooling at least one of the magnet and the ferromagnetic elements.

Provided are an exterior body and an abnormality detector capable of suppressing bulking even when a heat generation detection function is provided. The exterior body of an electronic device generates heat during operation and is characterized by being provided with a magnetic body that is at least a portion of the exterior body, that has spontaneous magnetization, and that generates an electromotive force by exhibiting an abnormal Nernst effect through heat generation of the electronic device, wherein an electrode for extracting power is provided to the magnetic body.

Provided are an exterior body and an abnormality detector capable of suppressing bulking even when a heat generation detection function is provided. The exterior body of an electronic device generates heat during operation and is characterized by being provided with a magnetic body that is at least a portion of the exterior body, that has spontaneous magnetization, and that generates an electromotive force by exhibiting an abnormal Nernst effect through heat generation of the electronic device, wherein an electrode for extracting power is provided to the magnetic body.

A magneto-caloric thermal diode assembly includes a magneto-caloric cylinder. Each of a plurality of thermal stages includes a plurality of magnets and a non-magnetic ring. The plurality of magnets is distributed along a circumferential direction within the non-magnetic ring in each of the plurality of thermal stages. A variable speed motor is coupled to one of the magneto-caloric cylinder and the plurality of thermal stages. The variable speed motor is operable to rotate the one of the magneto-caloric cylinder and the plurality of thermal stages relative to the other of the magneto-caloric cylinder and the plurality of thermal stages.

The purpose of the present invention is to make it possible to ensure a strength that allows thermoelectric evaluation to be performed even when sintering is carried out at a temperature lower than the minimum sintering temperature of a power generation layer, in a thermoelectric conversion element. For this purpose, this thermoelectric conversion element is characterized by being provided with a power generation layer and support layers including a sintered body, wherein the power generation layer is provided with a metal-magnetic insulator composite structure in which metal is formed in a net shape around a granulated magnetic body, the support layers are formed so as to be in contact with the top and bottom or the right and left of the power generation layer, and the minimum sintering temperature of the support layers is lower than the minimum sintering temperature of the power generation layer.

A thermoelectric conversion element 10 includes an anomalous Nernst material 11 having the anomalous Nernst effect, in which: the anomalous Nernst material 11 includes at least an element having the inverse spin-Hall effect; and the element is spin-polarized. By applying, for example, a magnetic field to such the thermoelectric conversion element 10 in the x direction and a temperature gradient thereto in the z direction, thermoelectromotive force can be taken out from terminals 12.

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

Magnetic cooling device comprising a magnetocaloric element, the magnetocaloric element comprising a paramagnetic garnet ceramic.

The density of the paramagnetic garnet ceramic is preferably greater than or equal to 90%.

The garnet ceramic is preferably a gadolinium gallium garnet ceramic or an ytterbium gallium garnet ceramic.