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 icemaker appliance includes a cabinet forming an ice storage compartment; an ice maker provided within the cabinet; a first reservoir provided below the ice maker; a second reservoir provided below the ice storage compartment; and a circulation system in fluid communication with the first reservoir and the second reservoir. The circulation system includes a return line conduit; a first pump connected to the return line conduit to pump the liquid from the second reservoir to the first reservoir; and a cleanout line conduit in fluid communication with the first pump, wherein the first pump selectively pumps the liquid from the second reservoir through the cleanout line conduit.

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.

An ice machine includes: an ice maker including: an ultrasonic bin sensor mounted to a body; and a controller in electrical communication with the ultrasonic bin sensor and configured to control the ultrasonic bin sensor; and a storage bin coupled to the ice maker and sized to receive a mound of ice, a lens of the ultrasonic bin sensor facing a bottom of an interior cavity of the storage bin, the controller configured to process a return signal of the ultrasonic bin sensor to control a level of ice stored inside the storage bin, the controller further configured to apply a predetermined time delay to filter out a portion of the return signal that exceeds a threshold voltage but does not exceed the time delay.

Non-plumbed appliances and filters are provided. A filter includes a body which includes a sidewall extending along a longitudinal axis between a first end wall and a second end wall, the body defining a body interior. The filter further includes an inlet defined in the body, and a nozzle protruding from the second end wall along the longitudinal axis and defining an outlet, the nozzle offset along an outer surface of the second end wall from a centroid of the outer surface. The filter further includes a tab configured on the body, and a filter medium disposed within the body interior, the filter medium operable to remove contaminants from water flowing through the filter medium.

Stand-alone ice making appliances are provided. An appliance includes a container defining a first storage volume for receipt of ice, a water tank defining a second storage volume for receipt of water, and a pump in fluid communication with the second storage volume. The appliance further includes an ice maker which is in fluid communication with the pump for receiving water from the pump. The appliance further includes a filter, the filter including a filter medium operable to remove contaminants from water flowing through the filter medium, the filter positioned upstream of the ice maker in a flow direction of water from the second storage volume to the ice maker.

A stand-alone ice making appliance includes a container defining a first storage volume for receipt of ice, a water tank defining a second storage volume for receipt of water, and a pump in fluid communication with the second storage volume. The appliance includes a reservoir defining a third storage volume, the third storage volume in fluid communication with the pump for receiving water that is actively flowed from the water tank. The appliance includes an ice maker which is in fluid communication with the third storage volume for receiving water from the reservoir, the ice maker including a sealed refrigeration system in thermal communication with the casing. The appliance includes a chute extending between the ice maker and the container for directing ice produced by the ice maker towards the first storage volume. The appliance includes a heating element, the heating element activatable to heat the casing.

Systems and methods for creating an oxidation reduction potential (ORP) in water for pathogenic control are described. The systems and methods generate an oxidation reduction potential that provides pathogenic control of the solution as well as pathogenic control of the surfaces with which the solution comes in immediate contact. The system also provides purified drinking water to a tap or an ice making machine.

An aseptic ice making system includes an ice making system to receive water from a water supply. The ice making system includes an ice producing subsystem to produce ice and a positive air pressure subsystem to maintain a positive air pressure environment within the ice making system.

An ice dispensing system is provided. The system includes multiple sidewalls forming an ice bin cavity configured to store ice. The system further includes an auger drive assembly. The auger drive assembly includes a drive assembly that is coupled to one of the multiple sidewalls and has a motor configured to rotate a drive gear. The auger drive assembly further includes an auger assembly positioned within the ice bin cavity. The auger assembly includes a helical auger coupled to an auger gear. The drive gear is configured to mate with the auger gear to drive rotation of the helical auger and cause ice to be dispensed through an ice chute. The drive assembly is additionally configured to move relative to the auger assembly between a closed position and an opened position. The opened position permits removal of the auger assembly from the ice bin cavity.