A refrigerator according to the present disclosure includes at least one storage chamber and uses an electromagnetic wave to heat a stored object inside the storage chamber. A first electromagnetic wave shield is provided on a door of the storage chamber, and a second electromagnetic wave shield is provided on a housing part of the refrigerator that is in contact with the door while the door is closed. This makes it possible to provide a structure capable of exhibiting a function as an electromagnetic wave shield even for a refrigerator door in which wiring to a grounding part is difficult.

A cooling device including a liner defining a freezer compartment, a shelf positioned within the freezer compartment, and an ice maker assembly secured to the shelf. The ice maker assembly including an ice maker configured to produce ice pieces, and an ice maker support frame that supports the ice maker. The ice maker support frame includes a fill cup and an air plenum, the air plenum defining a channel therein and extends between first and second walls of the ice maker support frame. A fan is disposed adjacent the ice maker frame at a location corresponding to the air plenum. The fill cup is configured to receive water from a water fill tube and direct the water to an ice tray of the ice maker.

A refrigerator according to an embodiment includes: a duct dividing the inside of a storage compartment body into a storage compartment and an air channel and having a main discharge port and a sub-discharge port; an air guide dividing the air channel into a first channel communicating with the main discharge port and a second channel guiding air in the first channel to the sub-discharge port; a heat exchanger provided in the first channel; and a fan suctioning air in the storage compartment and sending the air to the first channel. According to the refrigerator, it is possible to maximize the volume of the storage compartment and separately discharge air to the main discharge port and the sub-discharge port, using a simple structure.

An artificial intelligent refrigerator is disclosed. The artificial intelligent refrigerator includes: one or more first temperature sensor that senses refrigerating compartment-internal temperature in a refrigerating compartment of the refrigerator; one or more second temperature sensor that senses freezing compartment-internal temperature in a freezing compartment of the refrigerator; and a refrigerator processor that calculates a load accumulation amount for food put in the refrigerator on the basis of the refrigerating compartment-internal temperature or the freezing compartment-internal temperature, and performs a load correspondence operation using the calculated load accumulation amount. According to the artificial intelligent refrigerator of the present disclosure, one or more of a user terminal, and a server of the present disclosure may be associated with an artificial intelligence module, a drone ((Unmanned Aerial Vehicle, UAV), a robot, an AR (Augmented Reality) device, a VR (Virtual Reality) device, a device associated with 5G services, etc.

A refrigerator appliance includes a cabinet forming a refrigerating compartment defining a plurality of cooling zones, an air circulation duct in fluid communication with the refrigerating compartment, an evaporator provided in the air circulation duct, and a damper assembly in fluid communication with the air circulation duct and the refrigerating compartment. The damper assembly includes a plurality of doors to selectively allow air to enter into selected cooling zones within the refrigerating compartment.

A refrigerator includes an ice tray, a motor, an ejector including a rotary shaft and a protrusion pin, and a heater for selectively supplying heat to the ice tray. A control method of the refrigerator includes a first step of sensing whether the ejector is rotated to reach a first setup position; a second step of driving the heater and stopping driving of an ice making compartment fan if the first step is satisfied; a third step of determining whether the ejector is rotated to reach a second setup position; and a fourth step of stopping driving of the heater if the third step is satisfied, and wherein the ejector continues to be rotated while the second to fourth steps are implemented.

A refrigerator includes a main body defining a storage space, a cryogenic freezing compartment having an insulation space that is independent with respect to the storage space, an evaporator disposed inside the storage space to cool 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 thermoelectric module assembly includes a thermoelectric module, a cold sink coming into contact with a heat absorption surface of the thermoelectric module and disposed in the cryogenic freezing compartment, and a heat sink coming into contact with a heat generation surface of the thermoelectric module. The heat sink is cooled by introducing a refrigerant supplied to the evaporator.

A refrigerator includes a cabinet defining a storage space, a door configured to open and close at least a portion of the storage space, and an evaporator configured to generate cold air. The refrigerator also includes a first ice maker provided in the door, a second ice maker provided in the storage space and configured to be covered by the door when the door is closed, a first cold air guide configured to guide the cold air to the first ice maker, and a second cold air guide configured to guide the cold air to the second ice maker.

An ice maker for mounting into a household cooling appliance, the ice maker includes an ice producer for producing ice; a storage container for storing ice; a driving unit for driving the storage container, the driving unit having a drive housing; and an air duct formed in the drive housing. The air duct has an air duct outlet configured in a front wall of the drive housing which faces towards the storage container and an air duct inlet provided in a side wall of the drive housing which faces towards the ice producer. A fan is arranged in the air duct. The fan generates an air stream from the ice producer to the storage container through the air duct.

A fresh-keeping device for a refrigerator, and a refrigerator. The fresh-keeping device includes a fresh-keeping box body having a lower frame and an upper frame, the lower frame being provided with an accommodating space as well as an opening and a gas inlet communicated with the accommodating space, the upper frame being provided with a refrigerating air channel, and the refrigerating air channel being used for refrigerating the accommodating space; a drawer is configured to enter from the opening and accommodated in the accommodating space to fit the fresh-keeping box body to form the sealed accommodating space; and a nitrogen generating means connected to the side of the fresh-keeping box body on which the gas inlet is formed and is configured to charge generated nitrogen into the accommodating space from the gas inlet.