A system for making a three dimensional ice sculpture has a movable print head and fan mounted in a refrigerated enclosure. The print head has an inlet connected to a source of chilled water and can spray dyed or undyed water at a platform. A controller can move the print head and regulate its water outflow. A fluid can be discharged into the sprayed water at a temperature that accommodates ice formation. The sprayed water forms successive layers that freeze.

A system for making a three dimensional ice sculpture has a movable print head and fan mounted in a refrigerated enclosure. The print head has an inlet connected to a source of chilled water and can spray dyed or undyed water at a platform. A controller can move the print head and regulate its water outflow. A fluid can be discharged into the sprayed water at a temperature that accommodates ice formation. The sprayed water forms successive layers that freeze.

An ice maker includes a dry compartment and a wet compartment adjacent to the dry compartment and including: an evaporator case sized to receive an evaporator, the evaporator case including: a plurality of interior panels joined to each other with snap-fit joints, each of the snap-fit joints including a tab and defining a slot, each of a plurality of seams formed between the interior panels defining a foam-tight seal and a water-tight seal; and a plurality of exterior panels, each of the plurality of exterior panels joined to a mating interior panel of the plurality of interior panels with slide joints, wherein the evaporator case is integrally insulated with blown foam insulation positioned between each of the plurality of exterior panels and a corresponding interior panel.

An ice maker includes a dry compartment and a wet compartment adjacent to the dry compartment and including: an evaporator case sized to receive an evaporator, the evaporator case including: a plurality of interior panels joined to each other with snap-fit joints, each of the snap-fit joints including a tab and defining a slot, each of a plurality of seams formed between the interior panels defining a foam-tight seal and a water-tight seal; and a plurality of exterior panels, each of the plurality of exterior panels joined to a mating interior panel of the plurality of interior panels with slide joints, wherein the evaporator case is integrally insulated with blown foam insulation positioned between each of the plurality of exterior panels and a corresponding interior panel.

An ice making machine having a refrigeration system designed for hydrocarbon (HC) refrigerants, and particularly propane (R-290), that includes dual independent refrigeration systems and a unique evaporator assembly comprising of a single freeze plate attached to two cooling circuits. The serpentines are designed in an advantageous pattern that promotes efficiency by ensuring the even bridging of ice during freezing and minimizing unwanted melting during harvest by providing an even distribution of the heat load. The charge limitations imposed with flammable refrigerants would otherwise prevent large capacity ice maker from being properly charged with a single circuit. The ice making machine includes a single water circuit and control system to ensure the proper and efficient production of ice. Material cost is conserved as compared to a traditional dual system icemaker.

An ice making machine having a refrigeration system designed for hydrocarbon (HC) refrigerants, and particularly propane (R-290), that includes dual independent refrigeration systems and a unique evaporator assembly comprising of a single freeze plate attached to two cooling circuits. The serpentines are designed in an advantageous pattern that promotes efficiency by ensuring the even bridging of ice during freezing and minimizing unwanted melting during harvest by providing an even distribution of the heat load. The charge limitations imposed with flammable refrigerants would otherwise prevent large capacity ice maker from being properly charged with a single circuit. The ice making machine includes a single water circuit and control system to ensure the proper and efficient production of ice. Material cost is conserved as compared to a traditional dual system icemaker.

The use of the following techniques to clean air: (1) inlet air filtration, (2) continuous recirculation air filtration, (3) water filtration and disinfection, (4) use of an air curtain in the ice bin opening, and (5) provision of clean air to the air assist pump during the harvest cycle.

The use of the following techniques to clean air: (1) inlet air filtration, (2) continuous recirculation air filtration, (3) water filtration and disinfection, (4) use of an air curtain in the ice bin opening, and (5) provision of clean air to the air assist pump during the harvest cycle.

The present disclosure relates to a method of controlling an ice-detaching temperature of an icemaker, including a first step of performing an ice-making operation in an ice-making unit, and counting a required ice-making time period from a starting point in time of the ice-making operation to an end point in time of the ice-making operation; a second step of acquiring the counted required ice-making time period, and acquiring an ambient temperature from an external temperature sensor; a third step of determining a variable ice-detaching time period, depending on the acquired ambient temperature and the acquired required ice-making time period; and a fourth step of using the determined ice-detaching time period to perform an ice-detaching operation. Ice of a cold plate is completely separated from the cold plate during an ice-detaching operation under conventional temperature conditions and even under harsh environments, preventing icemaker failure and increasing ice-making capacity.

The present disclosure relates to a method of controlling an ice-detaching temperature of an icemaker, including a first step of performing an ice-making operation in an ice-making unit, and counting a required ice-making time period from a starting point in time of the ice-making operation to an end point in time of the ice-making operation; a second step of acquiring the counted required ice-making time period, and acquiring an ambient temperature from an external temperature sensor; a third step of determining a variable ice-detaching time period, depending on the acquired ambient temperature and the acquired required ice-making time period; and a fourth step of using the determined ice-detaching time period to perform an ice-detaching operation. Ice of a cold plate is completely separated from the cold plate during an ice-detaching operation under conventional temperature conditions and even under harsh environments, preventing icemaker failure and increasing ice-making capacity.