In an ice maker according to the present disclosure, transporter configured to supply ice to a dispenser, at least a part of which is located above an ice bucket located in the middle of the main body, may transport the ice upward to help the user take the ice conveniently even with the ice bucket located in the middle of the main body. So a refrigerator including the ice maker, according to the present disclosure, includes a storeroom to store groceries with increased utilization of the storeroom.

An ice-making device in a refrigerator including water blocking walls configured to prevent water supplied to an ice tray from straying outside the ice tray. The ice-making device includes an upper frame and a lower frame. A water supply port is disposed in a rear wall of the upper frame and configured to supply water to an ice tray between the upper frame and the lower frame. An upper sidewall protrudes downward from the upper frame. A main water-blocking rib protrudes from the rear wall and configured to prevent water supplied from the water supply port from straying along the upper sidewall. An auxiliary water-blocking rib protrudes from the upper sidewall and can further prevent the water supplied from the water supply port from straying along the upper sidewall.

A refrigerator includes an ice-making unit disposed in the door and can make ice through direct cooling by a refrigerant without using cold air flow. A cold air generation system operates to circulate the refrigerant for supplying a cold air flow for the refrigerator. A refrigerant pipe is installed in the refrigerator main body to branch off some refrigerant from the cold air generation system. An ice-making pipe is installed within the ice-making unit and receives the refrigerant from the refrigerant pipe. Water freezes into ice through heat transfer between the ice-making unit and the ice-making pipe containing refrigerant. A soft pipe is disposed around a hinge shaft of the refrigerator main body and the door and configured to interconnect the ice-making pipe and the refrigerant pipe in a twistable manner.

A refrigerator has an ice bin that can break ice piece agglomerates therein. The ice bin includes a breaking unit rotatably installed in a discharge port of the ice bin, the breaking unit including a stationary blade and rotatable blade. The ice bin also includes a separation blade rotatably installed parallel the breaking unit and configured to strike and separate ice pieces agglomerates into smaller pieces for discharging.

An ice-making device for a refrigerator including a duct providing a cold air flow path under an ice tray in which water turns into ice pieces. Uneven portions extending in a direction differing from a flow direction of cold air are formed at a lower surface of the ice tray. The duct may have a wavy surface. The surface features of the ice tray and the duct can advantageously increase contact area and contact time between cold air and the ice tray, thereby increasing the heat exchange efficiency between cold air and water contained in the ice tray.

A refrigerator includes a refrigerator main body configured to define an outer shell of the refrigerator and a door configured to open and close an internal space of the refrigerator main body. The refrigerator further includes an ice-making unit provided in the door and a cold air generation unit configured to circulate a refrigerant so that a cold air is supplied to the internal space. The refrigerator further includes an ice-making pipe installed within the ice-making unit so that the ice-making unit makes heat exchange with the refrigerant, a refrigerant pipe installed in the refrigerator main body so as to receive the refrigerant from the cold air generation unit, and a soft pipe disposed around a folding portion of the refrigerator main body and the door and configured to interconnect the ice-making pipe and the refrigerant pipe in a stretchable manner.

An ice-making device for a refrigerator. The ice-making device includes an ice tray, an ice-storing unit, and a slide. The slide is configured to guide ice pieces discharged from the ice tray toward the ice-storing unit.

The ice-storing unit includes an ice storage part configured to accommodate the ice pieces released from the ice-making unit and a drive device configured to drive a delivery member for discharging the ice pieces from the ice storage part. The ice tray extends to a location above the drive device.

A refrigerator including an ice maker and cutters for crushing ice produced from the ice maker. The cutters include fixed cutters and rotational cutters. Through holes are formed on the cutters to facilitate cold air flow to pass through the cutters and into the ice crushing space. The rotational cutters can rotate in one direction to crush the ice, and can rotate in another direction to leave the ice uncrushed.

An ice making assembly includes an ice mold defining a mold cavity and a refrigeration loop having an evaporator in thermal communication with the ice mold. A compressor is operably coupled to the refrigeration loop for circulating a flow of refrigerant through the refrigerant loop to cool the evaporator and the ice mold. After ice is formed, a flow regulating device may divert a portion of the flow of refrigerant around the condenser through a bypass conduit to slowly increase a temperature of the refrigerant within the evaporator.

A configurable container includes a first divider and a container body. The divider has a divider body and a first projection extending from the divider body, wherein the first projection has a length having a first dimension and a width having a second dimension different than the first dimension. The container body includes a first wall that includes a first groove facing inward toward the internal cavity, wherein the first groove has a width configured to receive the width of the first projection of the first divider in a first orientation. At least one of the first wall and a second wall includes a second groove also facing inward toward the internal cavity, wherein the second groove has a width configured to receive the length of the first projection in a second orientation, wherein the width of the second groove is different than the width of the first groove.