An on-demand and efficient ice delivery unit is described. In an aspect, the unit is comprises a cabinet that further comprises an ice storage bin and an icemaker. The ice delivery unit provides a user with compressed chewable nuggets of ice. In an aspect, the unit comprises an icemaker that is ideally located below the ice storage bin. The location of the icemaker, which may also be remote, is designed to enable the ice storage bin to be of a larger capacity than ice delivery units currently known in the art. Additionally, the location of the icemaker reduces the overall size, particularly the height, of the unit in comparison to other ice distribution units known in the art.

An on-demand and efficient ice delivery unit is described. In an aspect, the unit is comprises a cabinet that further comprises an ice storage bin and an icemaker. The ice delivery unit provides a user with compressed chewable nuggets of ice. In an aspect, the unit comprises an icemaker that is ideally located below the ice storage bin. The location of the icemaker, which may also be remote, is designed to enable the ice storage bin to be of a larger capacity than ice delivery units currently known in the art. Additionally, the location of the icemaker reduces the overall size, particularly the height, of the unit in comparison to other ice distribution units known in the art.

A control method for a nugget ice maker includes setting the nugget ice maker to an ice formation operating state, monitoring a speed of a motor in the ice formation operating state, and switching the nugget ice maker from the ice formation operating state to an ice production operating state in response to the monitored speed of the motor in the ice formation operating state dropping below an ice formation speed threshold.

A control method for a nugget ice maker includes setting the nugget ice maker to an ice formation operating state, monitoring a speed of a motor in the ice formation operating state, and switching the nugget ice maker from the ice formation operating state to an ice production operating state in response to the monitored speed of the motor in the ice formation operating state dropping below an ice formation speed threshold.

An icemaker according to present invention may comprise: a device body having an inflow penetration portion and a discharge penetration portion formed therein; a flow portion having an inflow opening and a discharge opening provided to penetrate the inflow penetration portion and the discharge penetration directly or indirectly, respectively, and having a flow space formed therein so as to connect with the inflow opening and the discharge opening; a cooling portion configured such that a refrigerant flows to at least a part of the periphery of the flow portion, thereby cooling water, which is introduced into the flow space through the inflow opening and flows therein, and turning the same into ice or cold water; and a separating/transferring portion for separating the ice, which has been generated in the flow space, from the flow space and transferring the same to the discharge opening.

An icemaker according to present invention may comprise: a device body having an inflow penetration portion and a discharge penetration portion formed therein; a flow portion having an inflow opening and a discharge opening provided to penetrate the inflow penetration portion and the discharge penetration directly or indirectly, respectively, and having a flow space formed therein so as to connect with the inflow opening and the discharge opening; a cooling portion configured such that a refrigerant flows to at least a part of the periphery of the flow portion, thereby cooling water, which is introduced into the flow space through the inflow opening and flows therein, and turning the same into ice or cold water; and a separating/transferring portion for separating the ice, which has been generated in the flow space, from the flow space and transferring the same to the discharge opening.

An icemaking system includes: a refrigerant circuit that executes a vapor compression refrigeration cycle; a circulation circuit that circulates solution as a cooling target of the refrigerant circuit; and a control device that controls refrigerant evaporation temperature at the refrigerant circuit. The circulation circuit includes a solution flow path of: an ice generator; a solution tank that stores the solution; and a pump that pressure feeds the solution to the solution flow path. The refrigerant circuit includes: an evaporator of the ice generator; a compressor; a condenser; and an expansion valve. The control device includes a central processing unit (CPU) that adjusts to lower evaporation temperature at the evaporator as the solution has higher solute concentration.

An icemaking system includes: a refrigerant circuit that executes a vapor compression refrigeration cycle; a circulation circuit that circulates solution as a cooling target of the refrigerant circuit; and a control device that controls refrigerant evaporation temperature at the refrigerant circuit. The circulation circuit includes a solution flow path of: an ice generator; a solution tank that stores the solution; and a pump that pressure feeds the solution to the solution flow path. The refrigerant circuit includes: an evaporator of the ice generator; a compressor; a condenser; and an expansion valve. The control device includes a central processing unit (CPU) that adjusts to lower evaporation temperature at the evaporator as the solution has higher solute concentration.

Systems and devices are provided for generating gel-ice. For example, a gel-ice generator is provided including a rotor apparatus to assist in moving flowable material through a gel-ice formation chamber. The rotor apparatus may include a rotor shaft positioned in the gel-ice formation chamber which is configured to rotate about a longitudinal axis during operation and to maintain flowable material within an annular column around the rotor shaft as the flowable material moves from an inlet end of the gel-ice formation chamber toward an outlet end of the gel-ice formation chamber. The gel-ice formation chamber may be surrounded by a coolant passage that spirals circumferentially along an exterior of the chamber. The rotor apparatus may further include a plurality of scraper elements supported on the rotor shaft to rotate in unison therewith to assist in the production of gel-ice as the rotor shaft rotates during operation by, among other things, scraping ice particles of a wall of a surrounding enclosure. The resultant gel-ice has a variety of uses, including for food processing and preservation.

An ice making assembly includes an ice bucket with an agitator rotatably mounted within the ice bucket. The agitator may be rotated by a dispenser motor. The agitator may be coupled to the dispenser motor via a fork connected to the motor and a socket connected to the agitator. The fork is selectively engagable with the socket, and the fork transfers torque from the dispenser motor to the agitator via the socket when the fork engages the socket. The ice making assembly may be provided in a refrigerator appliance.