Disclosed are an ice storage container (100) and a refrigerator (1000) having same. The ice storage container (100) includes: an ice delivering part (10) and an ice crushing part (20). The ice delivering part (10) includes: a container body (11), an ice pushing component (12), and a driving member. The container body (11) defines a first accommodating cavity (a) for accommodating ice cubes. The first accommodating cavity (a) is provided with an ice outlet (b). The ice pushing component (10) is arranged in the first accommodating cavity (a). The ice pushing component (12) includes a plurality of blades (1212). The driving member is connected to the ice pushing component (12). The blades (1212) of the ice pushing component (12) are configured to crush the ice cubes selectively based on a preset condition that is forward rotation or reverse rotation. The plurality of blades (1212) push the ice towards the ice outlet (b).

Disclosed are an ice storage container (100) and a refrigerator (1000) having same. The ice storage container (100) includes: an ice delivering part (10) and an ice crushing part (20). The ice delivering part (10) includes: a container body (11), an ice pushing component (12), and a driving member. The container body (11) defines a first accommodating cavity (a) for accommodating ice cubes. The first accommodating cavity (a) is provided with an ice outlet (b). The ice pushing component (10) is arranged in the first accommodating cavity (a). The ice pushing component (12) includes a plurality of blades (1212). The driving member is connected to the ice pushing component (12). The blades (1212) of the ice pushing component (12) are configured to crush the ice cubes selectively based on a preset condition that is forward rotation or reverse rotation. The plurality of blades (1212) push the ice towards the ice outlet (b).

A refrigeration appliance has an enclosure that defines an electronics module recess and a detachable electronics module that can be releasably retained in the recess. Tabs and tab receivers can be integrated with the electronics module and enclosure to releasably retain the electronics module in the recess. A trim piece can releasably attach to a display bezel of the electronics module by a snap-fit connection to retain the electronics module in the electronics module recess. In use, the electronics module can be selectively removed and a data acquisition device can be connected to the appliance using a data connector that is exposed by removing the electronics module.

An ice maker for freezing water into ice pieces, the ice maker including an elongated cage having a central revolving axis about which the elongated cage revolves. The elongated cage having a first end, a second end and at least one elongated slot extending between the first end and the second end. An ice tray is configured to be received in the at least one elongated slot. The ice tray includes a plurality of cavities for receiving water to be frozen into ice pieces. A motor is coupled to the elongated cage for revolving the elongated cage about the central revolving axis. A controller is connected to the motor for controlling the revolving of the elongated cage about the central revolving axis.

An ice maker for freezing water into ice pieces, the ice maker including an elongated cage having a central revolving axis about which the elongated cage revolves. The elongated cage having a first end, a second end and at least one elongated slot extending between the first end and the second end. An ice tray is configured to be received in the at least one elongated slot. The ice tray includes a plurality of cavities for receiving water to be frozen into ice pieces. A motor is coupled to the elongated cage for revolving the elongated cage about the central revolving axis. A controller is connected to the motor for controlling the revolving of the elongated cage about the central revolving axis.

Ice making appliances and methods for making ice using a machine-readable ice cube mold are provided herein. The ice making appliances and methods of making ice may include obtaining ice mold identifier data from the ice mold. Ice mold identifier may be used to acquire operating parameters of the ice making appliance specific to that ice mold from an external communication network. The operating parameters may be used to adjust operation of the appliance, such as the volume of water to dispense for that particular mold.

Ice making appliances and methods for making ice using a machine-readable ice cube mold are provided herein. The ice making appliances and methods of making ice may include obtaining ice mold identifier data from the ice mold. Ice mold identifier may be used to acquire operating parameters of the ice making appliance specific to that ice mold from an external communication network. The operating parameters may be used to adjust operation of the appliance, such as the volume of water to dispense for that particular mold.

The present application relates to the field of ice making, and provides an ice making system and a refrigeration apparatus. The ice making system includes an ice making assembly, a water collecting tank located below the ice making assembly, and a water diversion ice rake structure. The water diversion ice rake structure includes: a pair of water receiving lateral wings, each of which is constructed with a rotary end and a free end; the pair of water receiving lateral wings are rotatably disposed on opposite sides of the ice making assembly through the respective rotary ends to rotate between an ice making position and an ice falling position. At the ice making position, the free ends of the pair of water receiving lateral wings are butted in a space between the ice making assembly and the water collecting tank to form a closure space with an opening facing the ice making assembly, and a water outlet communicating with the water collecting tank is constructed on one side of the closure space. The present application may solve the problems of condensed water dripping out and water splashing outward during ice making.

The present application relates to the field of ice making, and provides an ice making system and a refrigeration apparatus. The ice making system includes an ice making assembly, a water collecting tank located below the ice making assembly, and a water diversion ice rake structure. The water diversion ice rake structure includes: a pair of water receiving lateral wings, each of which is constructed with a rotary end and a free end; the pair of water receiving lateral wings are rotatably disposed on opposite sides of the ice making assembly through the respective rotary ends to rotate between an ice making position and an ice falling position. At the ice making position, the free ends of the pair of water receiving lateral wings are butted in a space between the ice making assembly and the water collecting tank to form a closure space with an opening facing the ice making assembly, and a water outlet communicating with the water collecting tank is constructed on one side of the closure space. The present application may solve the problems of condensed water dripping out and water splashing outward during ice making.

A refrigerator includes a water system and a valve. The water system is configured to direct water to a dispenser or an ice maker. The valve includes a valve body, an inlet port, and a clutch. The valve is configured to connect the water system to a water source. The inlet port is configured to receive a tube to establish fluid communication with the water source and to engage a nut to secure the tube to the inlet port. The clutch is disposed between the inlet port and the valve body and is configured to slip in response to an applied torque to the inlet port exceeding a threshold.