A method for building an ice structure includes making a plurality of ice logs or ice beams and attaching the ice logs together to form a support structure. The support structure may be two or more stories high and may be constructed by freezing the ice logs or ice beams together.

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.

A household cooling appliance has a housing with a receiving space for food, a door for closing the receiving space, wherein the door is movably arranged at the housing, an ice maker with an ice tray, wherein the ice maker with the ice tray is arranged in the door, a first cooling device, which is arranged at the door and by which the ice tray is cooled, wherein the first cooling device comprises a waste heat unit by which the waste heat resulting from the cooling of the ice tray can be dissipated, and a second cooling device, which is arranged at the housing and by which the receiving space is cooled. The waste heat unit of the first cooling device is thermally coupled with the second cooling device such that the waste heat of the waste heat unit can be transferred to the second cooling device.

There is provided a method that includes (a) controlling a vibrator to produce an acoustic wave in accordance with a signal that includes (i) an on-time during which a packet of pulses is generated, followed by (ii) an off-time during which no pulses are generated, and thus includes (iii) a frequency component, (b) receiving an electrical representation of the acoustic wave that has been detected from a body of water that is being frozen on a structure, (c) extracting, from the electrical representation, (i) the frequency component, and (ii) a magnitude of the frequency component, (d) recognizing that the magnitude of the frequency component exceeds a threshold value, thus yielding a recognition, and (e) issuing a command to remove the body of water from the structure, in response to the recognition. There is also provided a system that employs the method, and a storage device containing instructions for the method.

A domestic refrigeration appliance having a housing in which a cooling compartment is provided, and is closable by a first door which is movably arranged on the housing. The appliance further having a dispensing unit having an output unit and an ice maker. The dispensing unit is configured for the output of liquid and/or molded ice elements and is arranged on the first door. A rear side of the first door facing toward the cooling compartment has a receptacle protruding toward the cooling compartment, in which receptacle the dispensing unit is arranged. The first door is pivotably arranged with at least one multiple-joint hinge on the housing. The multiple-joint hinge has a mechanism with which, during the pivoting movement of the first door, the first door is also displaced in the width direction.

There is provided a method that includes (a) controlling a vibrator to produce an acoustic wave in accordance with a signal that includes (i) an on-time during which a packet of pulses is generated, followed by (ii) an off-time during which no pulses are generated, and thus includes (iii) a frequency component, (b) receiving an electrical representation of the acoustic wave that has been detected from a body of water that is being frozen on a structure, (c) extracting, from the electrical representation, (i) the frequency component, and (ii) a magnitude of the frequency component, (d) recognizing that the magnitude of the frequency component exceeds a threshold value, thus yielding a recognition, and (e) issuing a command to remove the body of water from the structure, in response to the recognition. There is also provided a system that employs the method, and a storage device containing instructions for the method.

An ice maker includes an ice making unit comprising an evaporator connected to a refrigeration system, an ice holding bin, a sump, a pump, a drain valve, an ozonated water source, and a controller. The controller activates the ozonated water source supplying a first volume of ozonated water to the sump, thereafter activates the pump to circulate the first volume of ozonated water from the sump to the ice making unit, once a predetermined sterilization time has been reached, the controller turns off the pump and drains the first volume of ozonated water from the sump. The controller initiates an ice making mode, and activates the ozonated water source to supply a second volume of ozonated water to the sump, thereafter activates the pump to circulate the second volume of ozonated water from the sump to the ice making unit forming ozonated ice on the evaporator, and initiates an ice harvest mode to remove the ozonated ice from the evaporator and delivers it to the ice holding bin.

An ice dispenser for storing and dispensing ice. The ice dispenser includes a holding bin that extends longitudinally between a first side and a second side, transversely between a third side and a fourth side, and vertically between a top to a bottom. A chute is configured to guide the ice from outside the holding bin into the holding bin. The chute has an upper end and an opposite lower end. The upper end of the chute extends longitudinally farther than the first side of the holding bin from the second side of the holding bin. A spout is operatively coupled to the holding bin for dispensing ice from the holding bin.

A system for cutting artisanal ice including a first sliding table having defining a first direction, a first saw guide disposed above the first sliding table and perpendicular to the first direction, a first saw coupled to the first saw guide, a first pushing arm extending laterally across the first sliding table, the first pushing arm configured to translate along the first, a pivot table pivotably coupled to the first sliding table, the pivot table configured to pivot between a first coplanar position to a second downward position, a second sliding table defining a second direction, wherein the second direction is perpendicular to the first direction, a second pushing arm configured to translate along the second direction, a second saw guide disposed above the second sliding table and perpendicular to the second direction and a second saw coupled to the second saw guide.

An ice maker includes an ice making unit comprising an evaporator connected to a refrigeration system, an ice holding bin, a sump, a pump, a drain valve, an ozonated water source, and a controller. The controller activates the ozonated water source supplying a first volume of ozonated water to the sump, thereafter activates the pump to circulate the first volume of ozonated water from the sump to the ice making unit, once a predetermined sterilization time has been reached, the controller turns off the pump and drains the first volume of ozonated water from the sump. The controller initiates an ice making mode, and activates the ozonated water source to supply a second volume of ozonated water to the sump, thereafter activates the pump to circulate the second volume of ozonated water from the sump to the ice making unit forming ozonated ice on the evaporator, and initiates an ice harvest mode to remove the ozonated ice from the evaporator and delivers it to the ice holding bin.