Disclosed is an evaporator assembly for a horizontal type ice making machine. The evaporator assembly includes a plurality of tubes for circulating a refrigerant; a plurality of conductive protrusions, which are thermally coupled to and extending from each of the plurality of tubes; and a non-conductive plate, which is arranged adjacent to the plurality of tubes. The non-conductive plate is defined with a plurality of moulds, wherein each of the plurality of moulds is defined with a provision to receive one of the plurality of conductive protrusions. Each of the plurality of tubes includes a hemispherical structure, configured to enclose a top portion of the mould. The configuration of the evaporator assembly facilitates fast and efficient formation of ice, and there improves the efficiency of the ice making machine.

An ice maker capable of sterilizing bacteria contains: a body, a compressor, a condenser, a cooling fan, and a control box. The condenser is connected with a capillarity tube on which a filtration program is installed, and the capillarity tube is connected with an expansion valve which communicates with an evaporator, and an ice cavity that has a heater. A tilted channel is located below the ice cavity, and a storage tank is fixed on the tilted channel. The body includes an ice water tank and a water pump communicating with multiple spray nozzles. The ice water tank includes a control valve connected with an intake, an overflow outlet is defined on the ice water tank, and a generator for ozonated and hypochlorous acid water is mounted in the ice water tank. The ozonated and hypochlorous acid water generator includes a casing, two inflow holes, two outflow holes, multiple cathode plates, and multiple anode plates.

An ice making assembly, a provided herein, may include a conductive ice mold, a sealed refrigeration system, and a water dispenser. The conductive ice mold may define a mold cavity. The sealed refrigeration system may include an evaporator in thermal communication with the ice mold. The water dispenser may be positioned below the ice mold to direct an ice-building spray of water to the mold cavity. The water dispenser may include a dispenser base and a spray cap selectively secured to the dispenser base. The spray cap may include a nozzle head defining an outlet aperture and an attachment wing extending radially from the nozzle head into the dispenser base.

An ice making assembly includes an ice mold defining a mold cavity and a refrigeration loop having an evaporator assembly in thermal communication with the ice mold. A compressor is operably coupled to the refrigeration loop for circulating a flow of refrigerant through the refrigerant loop to cool the evaporator assembly and the ice mold. The evaporator assembly includes a primary evaporator tube and a thermal enhancement structure, such as internal tubes and/or copper foam, placed therein to increase the refrigerant side surface area. The primary evaporator tube is deformed into a non-circular cross sectional shape and soldered or brazed onto a top wall of the ice mold.

An icemaker appliance includes a cabinet. A refrigeration system includes a compressor, a condenser, an expansion device, and an evaporator. The refrigeration system is charged with a refrigerant. The refrigeration system further includes a modulator having a reservoir and a supply conduit. The reservoir of the modulator is positioned on an outlet conduit of the evaporator. A first end portion of the supply conduit is coupled to an inlet conduit of the evaporator, and a second end portion of the supply conduit is coupled to the reservoir of the modulator. The refrigerant is flowable into and out of the reservoir of the modulator through the supply conduit of the modulator. An ice maker is positioned within the cabinet. The evaporator of the refrigeration system is coupled to the icemaker such that the refrigeration system is operable to chill the icemaker.

An icemaker appliance includes a cabinet. A refrigeration system includes a compressor, a condenser, an expansion device, and an evaporator. The refrigeration system is charged with a refrigerant. The refrigeration system further includes a modulator having a reservoir and a supply conduit. The reservoir of the modulator is positioned on an outlet conduit of the evaporator. A first end portion of the supply conduit is coupled to an inlet conduit of the evaporator, and a second end portion of the supply conduit is coupled to the reservoir of the modulator. The refrigerant is flowable into and out of the reservoir of the modulator through the supply conduit of the modulator. An ice maker is positioned within the cabinet. The evaporator of the refrigeration system is coupled to the icemaker such that the refrigeration system is operable to chill the icemaker.

The icemaker comprises an evaporator equipped with a plurality of open cells for the formation of ice elements, a sprayer for spraying water into the cells, a tank for collecting the water not transformed into ice in the cells, the sprayer having an element for occluding the cells equipped with a plurality of calibrated holes, each for access to a corresponding cell and a plurality of nozzles, each engaged in a corresponding access hole for the injection of water into a corresponding cell, the sprayer being supported by a support in a movable manner between an opening position and a closing position of the cells by means of the occlusion element, a kinematic mechanism for moving said support also being provided externally to said collection tank.

An ice making assembly includes an ice mold defining a mold cavity and a refrigeration loop having an evaporator in thermal communication with the ice mold. A compressor is operably coupled to the refrigeration loop for circulating a flow of refrigerant through the refrigerant loop to cool the evaporator and the ice mold. After ice is formed, a flow regulating device may divert a portion of the flow of refrigerant around the condenser through a bypass conduit to slowly increase a temperature of the refrigerant within the evaporator to release formed ice from the ice mold while preventing thermal shock and cracking.

In one exemplary aspect of the present disclosure, an ice making assembly is provided for making clear ice. The ice making assembly may include a conductive ice mold, an insulation jacket, and a water dispenser. The conductive ice mold may define an upper portion of a mold cavity extending from a top end to a bottom end. The insulation jacket may extend downward from the conductive ice mold. The insulation jacket may define a lower portion of the mold cavity. The lower portion of the mold cavity may be a vertically open passage aligned with the upper portion of the mold cavity. The water dispenser may be positioned below the insulation jacket to direct an ice-building spray of water to the mold cavity through the vertically open passage of the insulation jacket.

In one exemplary aspect of the present disclosure, an ice making assembly is provided for making clear ice. The ice making assembly may include a conductive ice mold, an insulation jacket, and a water dispenser. The conductive ice mold may define an upper portion of a mold cavity extending from a top end to a bottom end. The insulation jacket may extend downward from the conductive ice mold. The insulation jacket may define a lower portion of the mold cavity. The lower portion of the mold cavity may be a vertically open passage aligned with the upper portion of the mold cavity. The water dispenser may be positioned below the insulation jacket to direct an ice-building spray of water to the mold cavity through the vertically open passage of the insulation jacket.