Abstract: A method for operating an elasto-caloric heat pump includes running the elasto-caloric heat pump with a pre-strain in an elasto-caloric stage of the elasto-caloric heat pump set to an initial pre-strain setting, and gradually shifting the pre-strain in the elasto-caloric stage of the elasto-caloric heat pump set away from the initial pre-strain setting and towards a final pre-strain setting over a time interval.

Abstract: 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.

Abstract: A magneto-caloric thermal diode assembly includes a first magneto-caloric cylinder and a second magneto-caloric cylinder. First and second pluralities of thermal stages are stacked along an axial direction between a cold side and a hot side. The second magneto-caloric cylinder and the second plurality of thermal stages are nested concentrically within the first magneto-caloric cylinder and the first plurality of thermal stages. Each thermal stage of the first and second pluralities 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 thermal stage of the first and second pluralities of thermal stages.

Abstract: A magneto-caloric thermal diode assembly includes a magneto-caloric regenerator with a plurality of magneto-caloric stages. Each of the plurality of magneto-caloric stages has a respective Curie temperature. Each of the plurality of magneto-caloric stages also has a stack of magneto-caloric material blocks and metal foil layers distributed sequentially along an axial direction in the order of magneto-caloric material block then metal foil layer.

Abstract: A magneto-caloric thermal diode assembly includes a plurality of thermal stages stacked along an axial direction between a cold side and a hot side. A plurality of magnets is distributed along a circumferential direction within a non-magnetic ring in each of the plurality of thermal stages. Each of the plurality of thermal stages between a cold side thermal stage and a hot side thermal stage is positioned between a respective pair of the plurality of thermal stages along the axial direction. The plurality of magnets of each of the plurality of thermal stages between the cold side thermal stage and the hot side thermal stage is spaced from the non-magnetic ring of one of the respective pair of the plurality of thermal stages along the axial direction and is in conductive thermal contact with the non-magnetic ring of the other of the respective pair of the plurality of thermal stages.

Abstract: A magneto-caloric thermal diode assembly includes a plurality of elongated magneto-caloric members. Each of a plurality of thermal stages includes a plurality of magnets and a plurality of non-magnetic blocks distributed in a sequence of magnet then non-magnetic block along a transverse direction. The plurality of thermal stages and the plurality of elongated magneto-caloric members are configured for relative motion along the transverse direction. The plurality of magnets and the plurality of non-magnetic blocks are spaced along the transverse direction within each of the plurality of thermal stages. Each of the plurality of magnets in the plurality of thermal stages is spaced from a respective non-magnetic block in an adjacent thermal stage towards a cold side thermal stage along the lateral direction and is in conductive thermal contact with a respective non-magnetic block in an adjacent thermal stage towards a hot side thermal stage along the lateral direction.

Abstract: 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.

Abstract: 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.

Abstract: A refrigerator appliance includes a cold side working fluid circuit that couples a cold side heat exchanger and a regenerator housing. A first hot side working fluid circuit couples a first hot side heat exchanger and the regenerator housing. A second hot side working fluid circuit couples a second hot side heat exchanger and the regenerator housing such that working fluid is flowable between the second hot side heat exchanger and the regenerator housing. An inlet of the second hot side working fluid circuit is positioned on the regenerator housing such that a temperature of the working fluid at the inlet of the second hot side working fluid circuit is greater than a temperature of the chilled chamber.

Abstract: A pump for a heat pump system includes a piston having a cam follower positioned on a bearing surface of a cam. A casing includes a first casing portion and a second casing that are mounted to each other. A piston head of the piston is disposed within the first casing portion, and the piston extends through the second casing portion. A spring urges the cam follower of the piston towards the bearing surface of the cam.

Abstract: A refrigerator appliance includes a fresh food working fluid circuit and a freezer working fluid circuit. The fresh food working fluid circuit couples a fresh food cold side heat exchanger and a first chamber of a regenerator housing such that a first working fluid is flowable between the fresh food cold side heat exchanger and the first chamber. The freezer working fluid circuit couples the freezer cold side heat exchanger and a second chamber of the regenerator housing such that a second working fluid is flowable between the freezer cold side heat exchanger and the second chamber. A liquid-to-liquid heat exchanger connects the fresh food working fluid circuit and the freezer working fluid circuit for heat transfer between the first and second working fluid. A freezing temperature of the first working fluid is greater than a freezing temperature of the second working fluid.

Abstract: A refrigerator, including a sealed refrigeration system, is provided herein. The sealed refrigeration system may include a compressor, a phase separator, and a rotatable heat exchanger. The phase separator may be in fluid communication with the compressor and include a separator body defining an inner face and an outer face. The inner face may define a refrigerant cavity. The outer face may be directed away from the refrigerant cavity opposite the inner face. The rotatable heat exchanger may include a thermally conductive body and a plurality of spaced planar fins. The thermally conductive body may be positioned about the outer face along a rotation axis. The planar fins may extend from the thermally conductive body in a radial direction away from the phase separator. The plurality of spaced planar fins may define an axial intake channel extending parallel to the rotation axis through one or more planar fins.

Abstract: A refrigerator, including a sealed refrigeration system, is provided herein. The sealed refrigeration system may include a compressor, a phase separator, and a rotatable heat exchanger. The compressor may compress a refrigerant fluid through the sealed refrigeration system. The phase separator may be in fluid communication with the compressor. The phase separator may include a separator body defining an inner face and an outer face. The inner face may define a refrigerant cavity within the phase separator body. The outer face may be directed away from the refrigerant cavity opposite the inner face. The rotatable heat exchanger may include a thermally conductive body defining a dynamic shear surface directed toward the outer face of the separator body. Moreover, a set fluid gap may be defined between the dynamic shear surface and the outer face.

Abstract: A magnet assembly for a magneto-caloric heat pump includes a first frame that extends between first and third magnets and a second frame that extends between second and fourth magnets. Each of the first and second frames includes a series of metal layers arranged such that a thermal break is formed between adjacent metal layers in the series of metal layers.

Abstract: A caloric heat pump includes a plurality of elasto-caloric stages. The plurality of elasto-caloric stages is distributed between along an axial direction within a chamber of a housing. Each elasto-caloric stage includes a hub, a rim and a plurality of elasto-caloric spokes. The plurality of elasto-caloric spokes extend between the hub and the rim along a radial direction. The plurality of elasto-caloric stages is rotatable about the axial direction.

Abstract: A heat pump system includes a magneto-caloric material disposed within a chamber of a regenerator housing. A back iron extends between an outer magnet and an inner magnet in order to provide a flux path between the outer and inner magnets. At least a portion of the back iron extends between the outer and inner magnets along the radial direction and is not positioned coplanar with the inner and outer magnets in a plane that is perpendicular to the axial direction. A related refrigerator appliance is also provided.

Abstract: A caloric heat pump system includes a pair of caps mounted to a regenerator housing. Each cap of the pair of caps defines an inlet and an outlet. The outlet of each cap of the pair of caps is positioned at a chamber of the regenerator housing. The inlet and outlet of each cap of the pair of caps defines an area in a respective plane that is perpendicular to the longitudinal direction. The area of the inlet of each cap of the pair of caps is less than the area of the outlet of each cap of the pair of caps.

Abstract: A heat pump system includes a caloric heat pump with a regenerator housing that is rotatable about an axial direction. A caloric material is disposed within a chamber of the regenerator housing. The caloric material defines a plurality of channels that extend along the axial direction through the caloric material. The channels of the plurality of channels are spaced from one another along a circumferential direction within the caloric material. A working fluid is flowable through the plurality of channels between end portions of the regenerator housing. A related refrigerator appliance is also provided.

Abstract: A conduction heat pump includes a first plate, a second plate and a third plate. The second plate includes a caloric material and is positioned between the first and third plates. The first, second and third plates of the conduction heat pump also includes features for conductively transferring heat from the third plate to the first plate during relative rotation between the second plate and the first plate.

Abstract: A caloric heat pump system includes a motor and a pair of non-circular gears meshed with each other. A first one of the pair of non-circular gears is coupled to a regenerator housing, and a second one of the pair of non-circular gears is coupled to the motor. The regenerator housing is rotatable with the motor through the pair of non-circular gears.