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.

A refrigerator appliance having an ice making assembly is provided herein. The refrigerator appliance may include a cabinet, an icemaker attached to the cabinet, an ice bin, a support tray, a fluid filter, a liquid storage volume, and a fluid pump. The ice bin may define a bin outlet at a bottom end. The support tray may be positioned below the bin outlet to receive water therefrom. The support tray may define an inclined groove extending downward toward a tray outlet. The fluid filter may be positioned below the support tray. A filter inlet may be positioned downstream from the tray outlet. A filter outlet may be positioned below the filter inlet along the vertical direction. The liquid storage volume may be positioned below the filter outlet and downstream therefrom. The fluid pump may be positioned in fluid communication between the liquid storage volume and the icemaker.

Methods, systems, and device for solidification and/or solid production, such as ice production, are provided in accordance with various embodiments. For example, some embodiments include a method of solid production that may include contacting a first fluid with a second fluid to facilitate solidifying the second fluid; the first fluid and the second fluid may be immiscible with respect to each other. The method may include solidifying the second fluid. Some embodiments include a solid production system that may include a first fluid and a second fluid; the first fluid and the second fluid may be immiscible with respect to each other. The system may include one or more surfaces configured to contact the first fluid and the second fluid with each other and to form one or more solids from the second fluid.

Methods, systems, and device for solidification and/or solid production, such as ice production, are provided in accordance with various embodiments. For example, some embodiments include a method of solid production that may include contacting a first fluid with a second fluid to facilitate solidifying the second fluid; the first fluid and the second fluid may be immiscible with respect to each other. The method may include solidifying the second fluid. Some embodiments include a solid production system that may include a first fluid and a second fluid; the first fluid and the second fluid may be immiscible with respect to each other. The system may include one or more surfaces configured to contact the first fluid and the second fluid with each other and to form one or more solids from the second fluid.

A refrigerator appliance having an ice making assembly is provided herein. The refrigerator appliance may include a cabinet, an icemaker attached to the cabinet, an ice bin, a support tray, a fluid filter, a liquid storage volume, and a fluid pump. The ice bin may define a bin outlet at a bottom end. The support tray may be positioned below the bin outlet to receive water therefrom. The support tray may define an inclined groove extending downward toward a tray outlet. The fluid filter may be positioned below the support tray. A filter inlet may be positioned downstream from the tray outlet. A filter outlet may be positioned below the filter inlet along the vertical direction. The liquid storage volume may be positioned below the filter outlet and downstream therefrom. The fluid pump may be positioned in fluid communication between the liquid storage volume and the icemaker.

A spindle for an ice machine comprising an essentially cylindrical body, which on a first end has a hollow for the insertion thereof into the corresponding area of the ice machine, and on a second end it incorporates a shaft designed to be attached to a reducer motor or another element able to transmit a torque force thereto such that it provides the continuous movement thereof; and wherein the body has on the outer surface thereof, a double-pitch helix, wherein the pitch of the helix will be in proportion to the diameter thereof, and the height of the helix in proportion to the core thereof.

An appliance for producing frozen food products, such as ice cream or slush drinks, includes a cooling cylinder connected in a refrigeration circuit, the cooling cylinder including a thermally-conductive cylinder wall and end cap closing the distal end of the cylinder wall, the cylinder wall and end cap separating refrigerant on one side from product to be frozen on the other side. A divider member disposed adjacent the cylinder wall forms contiguous evaporator compartments spaced apart axially. Restrictor passages in the divider member permit communication between contiguous compartments and refrigerant first enters the first-cooled evaporator compartment at one of the axial ends and flows in series between the evaporator compartments. For fast, efficient freezing of small batches, the product to be frozen is either driven by the auger, or drains, toward the first-cooled evaporator compartment.

According to an embodiment of the present disclosure, a method for manufacturing an auger-type ice maker including an ice-making tube, an auger, a refrigerant pipe, and a metal core material, includes heating and feeding the metal core material to the ice-making tube; winding the metal core material together with the refrigerant pipe around the ice-making tube; and heating a welding agent through an internal space of the ice-making tube to perform adhesion between the metal core material and both of the refrigerant pipe and the ice-making tube, wherein, in the winding the metal core material together with the refrigerant pipe on the ice-making tube, the heated metal core material is pressurized by pressure of winding the refrigerant pipe around the ice-making tube, to completely fill the spiral space with the heated metal core material, or to form a uniform interval in the spiral space.

According to an embodiment of the present disclosure, a method for manufacturing an auger-type ice maker including an ice-making tube, an auger, a refrigerant pipe, and a metal core material, includes heating and feeding the metal core material to the ice-making tube; winding the metal core material together with the refrigerant pipe around the ice-making tube; and heating a welding agent through an internal space of the ice-making tube to perform adhesion between the metal core material and both of the refrigerant pipe and the ice-making tube, wherein, in the winding the metal core material together with the refrigerant pipe on the ice-making tube, the heated metal core material is pressurized by pressure of winding the refrigerant pipe around the ice-making tube, to completely fill the spiral space with the heated metal core material, or to form a uniform interval in the spiral space.

A method for continuously producing a flowable, pumpable, cooled mass or cooling mass, in particular for use as foodstuffs and food products and/or for foodstuffs and food products made of a flowable base mass, including the following steps: filling a housing with the flowable base mass; cooling the flowable base mass by bringing it in contact with a heat exchanger device disposed in the housing while stirring the base mass so as to generate the pumpable, cooled mass or cooling mass, wherein, when a layer, and in particular an ice layer, forms on the heat exchanger device, cooling is interrupted as soon as the layer, and in particular the ice layer, reaches a predetermined thickness, and cooling is continued as soon as the layer drops below the predetermined thickness, wherein the base mass and/or the mass is moved radially outwardly along the heat exchanger surfaces during stirring, and a force is transmitted for stirring from outside the housing to the inside, without contact and without apertures through the housing. The invention further relates to an air conditioning method, to a cooling mass production device, to an energy system, and to a use therefor.