An aseptic ice making system includes an ice making system to receive water from a water supply. The ice making system includes an ice producing subsystem to produce ice and a positive air pressure subsystem to maintain a positive air pressure environment within the ice making system.

An ice making assembly and method utilizes a housing having an upper fluid chamber, a plurality of distinct, substantially vertical fluid channels, and at least one drain aperture in fluid communication with a fluid reservoir. Ice forming members extend from an ice forming evaporator into respective fluid channels. During an ice making event, fluid continuously supplied to the upper fluid chamber flows into each of the fluid channels and out through at least one drain aperture into a fluid reservoir below. The ice forming members are cooled such that fluid flowing across the fluid channels freezes on the ice forming members over time, forming clear ice pieces. The ice pieces are subsequently released from the ice forming members and transferred for storage and/or dispensing.

A refrigerator in which an ice making chamber case including a horizontal wall, a vertical wall, a front opening and a front edge is coupled to an inside of an inner case, to form an ice making chamber. A case insulator is disposed in a wall space of the ice making chamber case. The case insulator is foamed separately from a body insulator which is foamed between inner and outer cases of a refrigerator body. Since the case insulator is foamed separately from the body insulator, it is possible to easily achieve foaming of the case insulator. It is also possible to prepare the ice making chamber case separately from molding of the inner case.

A refrigerator in which an ice making chamber case including a horizontal wall, a vertical wall, a front opening and a front edge is coupled to an inside of an inner case, to form an ice making chamber. A case insulator is disposed in a wall space of the ice making chamber case. The case insulator is foamed separately from a body insulator which is foamed between inner and outer cases of a refrigerator body. Since the case insulator is foamed separately from the body insulator, it is possible to easily achieve foaming of the case insulator. It is also possible to prepare the ice making chamber case separately from molding of the inner case.

There is provided a refrigerator having a locking device for an ice bucket and a method for installing a locking device for an ice bucket. A refrigerator having a locking device for an ice bucket, comprising: a main body; a storage space within the main body; an ice space configured to be disposed inside the main body, and partitioned from the storage space, and having a front opening; an ice bucket comprising an ice storage part which stores ice generated within the ice space; and a cover member which is disposed in front of the ice storage part to cover a front of the ice space and configured to be slidably installed in the ice space; and a locking device configured to lock the ice bucket within the ice space to prevent the ice bucket from being drawn out of the ice space by itself.

An ice-making device for a refrigerator capable of detecting ice fullness in the ice storing unit and suspending ice production accordingly. The ice-making device includes a sensing unit configured to measure the amount of ice in the ice-storing unit based on detected positional information of the ice-storing unit. An accommodation unit is configured to accommodate the ice-making unit and the ice-storing unit. The sensing unit can sense relative movement of the ice storage unit with respect to the accommodation unit.

The present application provides an ice dispenser for dispensing a volume of ice. The ice dispenser may include an ice bin and an ice deflector positioned about a top of the ice bin. The ice deflector may include a reverse funnel configuration such that an entrance to the ice deflector is narrower that an exit to the ice deflector so as to prevent the volume of ice from bridging therein in whole or in part.

Disclosed herein is a refrigerator having an ice bucket with a simple structure. The refrigerator may include a main body and an ice bucket provided to supply ice, wherein the ice bucket includes an ice bank provided with an ice storage space therein and an opening, an auger rotatably disposed in the ice bank to rotate about a rotating shaft to transfer ice, and a guide lever rotatably installed in the ice bank to open or close the opening and configured to open the opening by being pushed by ice being transferred in a direction of the rotating shaft.

An ice collection area is disposed inside the cabinet proximate an ice maker. An ice storage area is disposed inside the cabinet. A first relocatable ice bin is disposed inside the cabinet. The first relocatable ice bin is disposed in one of the ice collection area and the ice storage area. A second relocatable ice bin is disposed inside the cabinet. The second relocatable ice bin is disposed in the other of the ice collection area and the ice storage area.

An outdoor unit includes a compressor compressing a sucked refrigerant and discharging compress, an outdoor heat exchanger exchanging heat between outdoor air and the refrigerant, an accumulator storing a liquefied refrigerant at a suction side of the compressor, a solenoid valve for storing the refrigerant in the outdoor heat exchanger, and a controller performing control so as to feed the refrigerant stored within the outdoor heat exchanger during a defrosting operation, to the accumulator on the basis of an amount of refrigerant within the accumulator when operation is switched to a heating operation from the defrosting operation.