A beverage container includes a base, a stem, and a bowl. The base has a base lateral dimension parallel to the horizontal supporting plane. The stem extends upwardly from a stem lower end coupled to the base to a stem upper end. The stem has a heat pipe extending between the stem lower end and the stem upper end. The stem has a stem lateral dimension smaller than the base lateral dimension. The bowl is coupled to the stem upper end and extends upwardly of the stem. The bowl defines a liquid chamber having an upper opening. Other beverage containers, systems, methods, and heat transfer pads are also disclosed.

A refrigerator having an ice-making device evaporator in addition to a refrigerator storage room evaporator. The ice-making device includes an ice tray and a cooling pipe contacting an outer surface of the ice tray. A refrigerant flows in the cooling pipe and directly cools the ice tray. The ice-making device evaporator receives the refrigerant from a condenser and supplies it to the cooling pipe. A heat insulation member wraps around the cooling pipe and can prevent the cooling pipe from exchanging heat with ambient air.

A supplemental refrigeration heat sink includes a plurality of sealed tubes filled with a compound and arranged so as to extend across the top inside a refrigerated box. The compound is preferably a phase change compound with a melting point proximate to and higher than the average return air temperature. During the cooling phase of the box, the supplemental heat sink tubes are cooled, with the phase change material freezing or nearly freezing. During the heating phase, cooling fans can be secured and the phase change material readily absorbs heat from the box, slowing the temperature rise in the box.

In a refrigerator control method according to an embodiment of the present invention, a control unit intermittently turns on a temperature sensor on a predetermined cycle when a deep-freezing chamber mode is turned off, so that the temperature sensor senses the internal temperature of a deep-freezing chamber for a first set time, and the sensed internal temperature of the deep-freezing chamber is transmitted to the control unit so as to minimize power consumption.

A method for controlling a refrigerator including: determining whether a defrosting period for a freezing chamber and a deep freezing chamber has elapsed; when it is determined that the defrosting period has elapsed, performing a deep cooling operation for bringing at least one among the temperature of the deep freezing chamber and temperature of the freezing chamber down to a temperature lower than a control temperature; and defrosting the deep freezing chamber when the deep cooling operation is terminated. When the defrosting of the deep freezing chamber is started, a freezing chamber valve is closed to block cold air flow. The defrosting of the deep freezing chamber includes cold sink defrosting and heat sink defrosting performed after the cold sink defrosting is completed, and while the heat sink defrosting is being performed, a deep freezing chamber fan is driven to remove vapor generated during the cold sink defrosting.

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.

A heat pump includes a magnet assembly which creates a magnetic field, and a regenerator housing which includes a body defining a plurality of chambers, each of the plurality of chambers extending along a transverse direction orthogonal to the vertical direction. The heat pump further includes a plurality of stages, each of the plurality of stages including a magnetocaloric material disposed within one of the plurality of chambers and extending along the transverse direction between a first end and a second end.

A refrigerator cooling system and method provides cooling to one or more features of a refrigerator by employing a secondary cooling loop that utilizes the excess cooling capacity of an evaporator to selectively provide supplemental cooling to the features when a thermal demand arises.

The present invention relates to a refrigerator having a separate deep-freezing space which is partitioned inside a storage space of the refrigerator. Provided is a refrigerator having a flow path which allows cold air to circulate inside a deep-freezing chamber. According to an embodiment disclosed in the present document, a flow path portion is formed on one part of the inner surface of the housing which forms the inner space of the deep-freezing chamber. The flow path portion is formed in a stepped shape on the inner surface of the housing.

Provided is a refrigerator. The refrigerator includes a main body defining a storage space, a cryogenic freezing compartment provided in the storage space, and a thermoelectric module assembly disposed at one side of the cryogenic freezing compartment so that the cryogenic freezing compartment is cooled to a temperature less than that of the storage space. The cryogenic freezing compartment includes a cryogenic case into which an insulation material is filled to be thermally insulated from the storage space and in which a cryogenic freezing space is defined, a case door opening and closing the cryogenic case, and a rail assembly connecting the cryogenic case to the case door and extending and contracted in multi-stages to allow the case door to be slid to be inserted and withdrawn. The rail assembly is mounted on the cryogenic case outside the cryogenic freezing space.