A refrigerator including a water supplier; an ice-making housing in a storage compartment; a first tray in the ice-making housing and including a first ice-making cell, and a first sealing portion formed along an edge of the first ice-making cell; and a second tray including a second ice-making cell, and a second sealing portion formed along an edge of the second ice-making cell, wherein the second tray is movable horizontally to engage with the first tray and couple the first and second ice-making cell, and while the second tray is engaged with the first tray, the second sealing portion overlaps the first sealing portion to prevent leakage from the first and second ice-making cells, the first ice-making cell forms a first portion of ice with water from the water supplier, and the second ice-making cell forms a second portion of the ice with water from the water supplier.

An ice bin for a refrigerator appliance, the ice bin includes a storage body. An auger, rotatably driven by an auger motor, extends within the storage body and has first and second ends. The auger is rotatably driven about a first axis. A first crusher roller is disposed at the second end of the auger and is coupled thereto to rotate together with the auger about the first axis. A second crusher roller is disposed on an axle extending along a second axis, the second crusher roller is freely rotatable about the axle. The second crusher roller is movable between a first position and a second position. When the second crusher roller is in the first position, the first crusher roller and the second crusher roller are spatially arranged and configured to grind the produced ice pieces into crushed ice.

A food preservation system including a refrigerator and a freezer, wherein the refrigerator and freezer are independent from each other; the refrigerator comprising a fresh food compartment; the freezer including an icemaker and means for receiving filtered water; a water filter located in the fresh food compartment; a water supply line leading into an inflow side of the water filter; a refrigerator inlet valve connected to an inlet side of the water filter and a water distribution valve, wherein the water distribution valve comprises an auxiliary icemaker water valve, the distribution valve connected to an outflow side of the water filter; tubing connecting an outflow side of the auxiliary icemaker water valve to the icemaker; and a refrigerator main controller, wherein the refrigerator main controller is in operable communication with the refrigerator inlet valve and the auxiliary icemaker water valve is provided, Methods to make ice with filtered water are also provided.

A refrigeration appliance includes a fresh food compartment and a freezer compartment. An ice maker is disposed within the fresh food compartment for freezing water into ice pieces. The ice maker includes a removable ice bin for storing the ice pieces produced by the ice maker. A rotatable auger is positioned within the removable ice bin and configured to drive the ice pieces out of the removable ice bin via a driving force applied in a first direction. A motor is configured to rotate the auger. A drive bar is coupled to the motor and is configured to apply a resisting force to the removable ice bin along a second direction generally opposed to the first direction sufficient to counteract the driving force, wherein the resisting force is less than a removal force applied by a user to remove the removable ice bin from the ice maker.

A refrigerator includes a first air duct, a second air duct, a door, and a gasket. The door has an ice maker disposed therein. The door also has a third air duct disposed along an internal side panel. The third air duct defines inlet and outlet orifices configured to establish fluid communication between first and second air ducts and the ice maker, respectively. The gasket is overmolded onto the third air duct and is configured to from a seal along an interface between the third air duct and the first air duct, and along an interface between the third air duct and the second air duct.

An ice making assembly for a refrigerator appliance includes a resilient mold defining a mold cavity and a heat exchanger in thermal communication with the resilient mold to freeze water and form one or more ice cubes therein. The ice making assembly also includes a lifter mechanism positioned below the resilient mold for selectively deforming the mold and raising the ice cubes formed therein. A resilient seal is sealingly engaged with the lifter mechanism and the heat exchanger, whereby an air-tight seal is formed between the lifter mechanism and the resilient seal and between the heat exchanger and the resilient seal.

An ice maker includes an ice mold having an inner surface and an outer surface. The inner surface of the ice mold is configured to retain water for forming ice cubes in the ice mold. The ice mold includes a plurality of ice lobes each shaped to form a respective ice cube in the ice mold. A heater assembly is positioned on the outer surface of the ice mold. In some embodiments, each of a plurality of heating elements of the heater assembly is aligned with a corresponding lobe of the plurality of lobes for supplying heat to ice cubes formed in the lobes for releasing the ice cubes from the ice mold. In some embodiments, the heater assembly includes a heater having a ceramic substrate and one or more electrically resistive traces and electrically conductive traces thick film printed on the ceramic substrate.

A refrigerator appliance includes an ice packer assembly including an enclosure with a rotatable door, and an ice mold slidably supported by the enclosure. The ice mold is configured to translate between a first position and a second position. The door is configured to rotate from a first orientation to a second orientation as the ice mold is translated from the first position to the second position. The enclosure defines a pass-through opening therethrough. The door opens up the pass-through opening when rotated to the first orientation, and closes the pass-through opening and defines a platform for receiving crushed ice thereon when it is rotated to the second orientation.

A refrigerator includes: an ice maker for generating ice; an ice bin for storing the ice and including a rotational blade that is rotated in order to discharge the ice; a motor for generating power for rotating the rotational blade; a manipulation pad provided on the door of the refrigerator and manipulated to discharge the ice from the ice bin; a manipulation sensing part for detecting the manipulation of the manipulation pad; and a controller for operating the motor when the manipulation of the manipulation pad is detected by the manipulation sensing part, wherein the controller rotates the motor in one direction to discharge the ice from the ice bin and the controller rotates the motor in the other direction, which is the opposite direction of the one direction, for a set period of time when the manipulation of the manipulation pad is no longer detected.

The present invention relates to a refrigerator foaming jig, and particularly, to a refrigerator foaming jig and a foaming method using same, the refrigerator foaming jig including: a refrigerator outer case in which a space part, into which a heat insulating material is injected, and a refrigerating compartment, and a freezer compartment are formed; and an ice-making compartment case which is installed inside the outer case and inside which an insulating material accommodation space communicating with the space part is formed. The refrigerator foaming jig comprises: a front jig coupled to an inner case; and a variable jig inserted into the partition part, wherein the variable jig expands toward the space part and the insulating material accommodation space or contracts inward so that the distance to the partition part is adjusted. According to the above configuration, the refrigerating compartment, the freezing compartment, and the ice-making compartment are simultaneously formed as independent spaces.