A refrigerator includes a refrigerator case, a freezer case disposed below the refrigerator case, a door disposed at a front of the refrigerator case, an ice maker disposed at the door, an evaporator disposed at a rear of the freezer case, an ice maker supply duct supplying the cold air to the ice maker, and an ice maker return duct supplying the cold air from the ice maker to the freezer compartment. An upper portion of the ice maker return duct extends from a rear of one side surface of the freezer case to a front of one side surface of the refrigerator case, a lower portion of the ice maker return duct extends in a vertical direction from the rear of one side surface of the freezer case, and the lower portion bends from the upper portion toward the other side surface of the freezer case.

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 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.

The application pertains to, for example, novel processes and systems for heat transfer, refrigeration, energy storage, and various cooling and heating processes. Such processes may include cooling or mixing various liquid-liquid phase transition liquids to release and/or energy. Additionally or alternatively, such processes may include charging and/or discharging thermal storage reservoirs with layered liquids of various temperatures.

The disclosure features various embodiments and aspects of a chest for quenching beverages. The chest can include a tank for holding a chilled mixture of ice and water, an ice maker adapted for making ice having an output for ejecting ice into a conduit in fluid communication with the tank, and a plurality of quench trays disposed above the tank for holding containers of beverages located in first and second positions. The trays can be filled with cold water by way of a conduit in fluid communication with the tank. The quench trays can include a compartment defined by a bottom and a plurality of walls, and defining therein a plurality of rows for aligning and containing a plurality of beverage containers. The drawers can further include at least one drain orifice configured to guide water out of the quench tray.

The disclosure features various embodiments and aspects of a chest for quenching beverages. The chest can include a tank for holding a chilled mixture of ice and water, an ice maker adapted for making ice having an output for ejecting ice into a conduit in fluid communication with the tank, and a plurality of quench trays disposed above the tank for holding containers of beverages located in first and second positions. The trays can be filled with cold water by way of a conduit in fluid communication with the tank. The quench trays can include a compartment defined by a bottom and a plurality of walls, and defining therein a plurality of rows for aligning and containing a plurality of beverage containers. The drawers can further include at least one drain orifice configured to guide water out of the quench tray.

The present embodiments relate to an improved mobile cooling box with an ice maker that is capable of freezing water and making ice, for example, ice cubes.

The present embodiments relate to an improved mobile cooling box with an ice maker that is capable of freezing water and making ice, for example, ice cubes.

A method of detecting ice within an automatic ice maker includes capturing an image of an ice mold within the ice maker, analyzing the image using a machine learning image recognition process, determining one or more characteristics of the ice maker, and implementing a responsive action to control the ice maker accordingly.

An ozone generator for producing ozone water for the sanitation and disinfection of an ice maker includes cathode plates and anode plates that are arranged alternatively in an electrolysis chamber. The cathode plates and the anode plates are connected to a cathode wire and an anode wire of a cable. A wiring chamber is provided with a temperature sensor extending into the electrolysis chamber and connected with a temperature sensor wire of the cable. The cable is connected to a control circuit. The ozone generator is submerged in the ice-making water of the ice-making water tank. The temperature sensor of the ozone generator submerged in the ice-making water is configured to sense temperature changes. When the ice maker is activated, the temperature of the ice-making water in the ice-making water tank will drop. When the temperature drops to the set temperature, the ozone generator is activated once to produce ozone gas. The ozone gas is dissolved in the ice-making water to generate ozone water. The ozone water is used to sanitize the ice-making loop process of the ice maker. The ozone generator has simple structure, low cost and good effect.