A magneto-caloric thermal diode assembly includes a magneto-caloric cylinder with a plurality of magneto-caloric stages. Each of the plurality of magneto-caloric stages has a respective Currie temperature. The magneto-caloric cylinder has a length along an axial direction. The plurality of magneto-caloric stages is distributed along the length of the magneto-caloric cylinder. A plurality of thermal stages also has a length along the axial direction. The length of the plurality of thermal stages is less than the length of the magneto-caloric cylinder. The magneto-caloric cylinder is received within the plurality of thermal stages such that the magneto-caloric cylinder is movable along the axial direction relative to the plurality of thermal stages.

The present invention provides a magnetic explosion engine comprising: a stator comprising a supporting disk and a plurality of low-temperature Curie point magnets provided on the supporting disk, wherein the supporting disk is of a disk-shaped structure, and the low-temperature Curie point magnets are all evenly distributed along the circumference of the supporting disk and are all centrally symmetrical about the center of a circle of the supporting disk. The low-temperature Curie point magnets are relative to the Curie point temperature of a normal magnet. The magnetic explosion engine provided by the present invention transmits heat and starts a high-temperature and low-temperature automatic switching procedure. With the use of a low-temperature Curie point magnet, the magnetic force disappears and recovers when its temperature changes, expressing a zero-resistance magnetic field motion.

Apparatus and method for converting thermal energy into electric energy, for example, in the automotive industry or geothermal energy. The apparatus and a method convert thermal energy into electric energy with an improved overall output and an increased maximum attainable output that is simple and cost-efficient to produce and use. The apparatus has one or more thermomagnetic generators, which contain at least one first and second thermomagnetic component, at least two components made of hard magnetic material, at least one coil and at least two connecting elements made of magnetic flux-conducting material; The magnetic north poles are connected to one of the two connecting elements made of magnetic flux-conducting material and the magnetic south poles thereof are connected to the other connecting element.

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.

A magneto-caloric thermal diode assembly includes a magneto-caloric cylinder with a plurality of magneto-caloric stages. Each of the plurality of magneto-caloric stages has a respective Currie temperature. The magneto-caloric cylinder has a length along an axial direction. The plurality of magneto-caloric stages is distributed along the length of the magneto-caloric cylinder. A plurality of thermal stages also has a length along the axial direction. The length of the plurality of thermal stages is less than the length of the magneto-caloric cylinder. The magneto-caloric cylinder is received within the plurality of thermal stages such that the magneto-caloric cylinder is movable along the axial direction relative to the plurality of thermal stages.

A magneto-caloric thermal diode assembly includes a magneto-caloric cylinder with a plurality of magneto-caloric stages. Each of the plurality of magneto-caloric stages has a respective Curie temperature. The magneto-caloric cylinder also includes a plurality of insulation blocks and a plurality of pins. The plurality of magneto-caloric stages and the plurality of insulation blocks are distributed sequentially along an axial direction in the order of magneto-caloric stage then insulation block. One or more the plurality of pins extends along the axial direction between each magneto-caloric stage and a respective insulation block within the magneto-caloric cylinder.

This invention relates to a cooling device which utilizes both thermoelectric and magnetocaloric mechanisms for enhanced cooling applications. Using high thermal conductivity magnetocaloric composites in conjunction with thermoelectric elements acting as thermal switches which are electrically coupled to a magnetization and demagnetization cycle enables the use of larger quantities of magnetocaloric material, and high efficiency solid state cooling can be achieved. Solid state cooling devices are useful for a variety of industrial applications which require cooling, such as, but not limited to cooling of microelectronic devices, cooling on space platforms, etc.

A thermoelectric conversion element includes: a magnetic body having a magnetization; and an electromotive body formed of material exhibiting a spin orbit coupling and jointed to the magnetic body. The magnetic body has an upper joint surface jointed to the electromotive body. The upper joint surface has concavities and convexities.

The purpose of the present invention is to provide a thermoelectric conversion element capable of achieving high-efficiency thermoelectric conversion using comparatively inexpensive materials. The present invention is accordingly provided with: a magnetic body layer, an electromotive film for generating electromotive force, and two terminal parts formed so that each is in contact with the electromotive film at two locations having different potentials due to the electromotive force. The electromotive film is formed on the magnetic body layer, said film comprising a Ni-containing magnetic alloy. Said film is doped with a 5d transition metal element, and Ni is the matrix.

An apparatus comprising: an active magnetic regenerative regenerator comprising multiple successive layers, wherein each layer comprises an independently compositionally distinct magnetic refrigerant material having Curie temperatures 18-22 K apart between successively adjacent layers, and the layers are arranged in successive Curie temperature order and magnetic refrigerant material mass order with a first layer having the highest Curie temperature layer and highest magnetic refrigerant material mass and the last layer having the lowest Curie temperature layer and lowest magnetic refrigerant material mass.