The disclosed subject matter relates to a suspension device for use with a low temperature refrigeration system, such as an adiabatic demagnetization refrigerator. A support ring is included with three spring-loaded tension assemblies equally spaced about the periphery of the support ring in which the tension assemblies each have a pulley, about which is positioned a plurality of bands of material made of a material having a low coefficient of thermal conductivity and high strength. Connected to this hand is a ring that laterally supports a cylindrical salt pill

A magnetic refrigeration apparatus according to the present disclosure includes a magnetic-field source and two or more bed rings. The bed rings can be arranged in pairs with shared cold and hot fluid plenums. A flow of heat transfer fluid may pass at least partially radially through the shared fluid plenum or through a connection between the fluid plenum and one or more flow tubes. The MR apparatus and systems of the present disclosure may further include one or more circumferential flux returns with radial through-hole passageways to accommodate flow tubing. For apparatus configurations with an even number of bed rings, the axial dimension of the passageways may be smaller than the circumferential dimension of the passageways.

A magnetocaloric device (1), comprises: at least one magnetocaloric material (5) embedded between two heat transfer structures (TD.sub.hot, TD.sub.cold); at least one electric source for generating a magnetic field; and at least one hydraulic circuit in which the working fluid flows in a constant direction and which comprises at least one propulsion means (6) for the working fluid, wherein the heat transfer structures (TD.sub.hot, TD.sub.cold) are adapted to control the transfer or transport of heat between the magnetocaloric material (5) and the working fluid.

A magnetic field application device applying a magnetic field to a magnetocaloric material includes: a magnetic field generating component; a first yoke connected to both poles of the magnetic field generating component; and a second yoke movably disposed between a first position and a second position. A first closed magnetic circuit formed by the magnetic field generating component and the first yoke passes through a magnetic field application region in which the magnetocaloric material is accommodated. A second closed magnetic circuit formed by the magnetic field generating component, the first yoke, and the second yoke bypasses the magnetic field application region. Magnetic resistance of the second closed magnetic circuit when the second yoke is located at the second position is smaller than the magnetic resistance of the second closed magnetic circuit when the second yoke is located at the first position.

A magnetic refrigeration apparatus includes a main channel, a magnetic refrigerator, a fluid transfer mechanism connected to the main channel, and at least one control valve. A heating medium flows through the main channel. The magnetic refrigerator includes a magnetic working substance, a casing having a channel connected to the main channel, and a magnetic field modulator that applies a magnetic field variation to the magnetic working substance. The fluid transfer mechanism alternately performs a first operation of transferring the heating medium in the main channel in a first direction, and a second operation of transferring the heating medium in a second direction opposite to the first direction. The main channel includes at least one branch channel branching from a portion of the main channel between the magnetic refrigerator and the fluid transfer mechanism. The at least one control valve is connected to the at least one branch channel.

A refrigerator appliance includes a cabinet that defines a chilled chamber. The cabinet has a duct with an inlet and an outlet. The inlet and outlet of the duct is contiguous with the chilled chamber of the cabinet such that air within the chilled chamber is flowable into the duct at the inlet of the duct and air within the duct is flowable into the chilled chamber at the outlet of the duct. A heat pump system is operable to cool the chilled chamber of the cabinet. The heat pump system includes a cold side heat exchanger in thermal communication with the air within the duct. The heat pump system also includes features for condensing water vapor from the air within the duct prior to the cold side heat exchanger.

A magneto-caloric assembly can include a first region including a first magneto-caloric material, a second region disposed on the first region and including a second magneto-caloric material and a first matrix material, and a third region disposed on the second region and including a thermally conductive material.

A magnetic field application device applying a magnetic field to a magnetocaloric material includes: a magnetic field generating component; a first yoke connected to both poles of the magnetic field generating component; and a second yoke movably disposed between a first position and a second position. A first closed magnetic circuit formed by the magnetic field generating component and the first yoke passes through a magnetic field application region in which the magnetocaloric material is accommodated. A second closed magnetic circuit formed by the magnetic field generating component, the first yoke, and the second yoke bypasses the magnetic field application region. Magnetic resistance of the second closed magnetic circuit when the second yoke is located at the second position is smaller than the magnetic resistance of the second closed magnetic circuit when the second yoke is located at the first position.

A heat pump includes a magnet assembly which creates a magnetic field, and a regenerator housing which includes a body defining a plurality of chambers, each of the plurality of chambers extending along a transverse direction orthogonal to the vertical direction. The heat pump further includes a plurality of stages, each of the plurality of stages including a magnetocaloric material disposed within one of the plurality of chambers and extending along the transverse direction between a first end and a second end.

A heat pump includes a magnet assembly which creates a magnetic field, and a regenerator housing which includes a body defining a plurality of chambers, each of the plurality of chambers extending along a transverse direction orthogonal to the vertical direction. The heat pump further includes a plurality of stages, each of the plurality of stages including a magnetocaloric material disposed within one of the plurality of chambers and extending along the transverse direction between a first end and a second end.