A drying chamber assembly and a refrigerator are provided. The drying chamber assembly consists of a drawer-type sealing container which includes a drawer body, a drawer door and a drawer upper cover. The drawer body has an upward top opening. The drawer door is disposed at a front end of the drawer body and configured to push and pull the drawer body. The drawer upper cover is disposed above the drawer body to seal the top opening when the drawer body is completely pushed into the storage compartment and defines a drying space together with the drawer body and the drawer door. An airflow inlet is formed in the drawer body and configured to supply an airflow to the drying space. The drying chamber assembly directly covers and seals the top opening of the drawer body through the drawer upper cover.

A refrigerator includes a plurality of wall modules and a cooling module. At least one of a rear wall module, a left wall module, or a right wall module includes a supply duct provided to supply cold air produced by the cooling module to a storeroom, and a collecting duct to bring air having exchanged heat from the storeroom back to the cooling module.

According to the present disclosure, a method for controlling a refrigerator includes operating a cooling device at a previously-determined output for cooling a storage space; measuring, by a temperature sensor, a temperature of the storage space in unit times; determining a representative temperature of the storage space based on the temperature measured by the temperature sensor, and determining whether the determined representative temperature of the storage space falls within a convergence temperature range, when an output change time is reached after the output of the cooling device is previously determined; maintaining the output of the cooling device or determining the output of the cooling device according to one of a plurality of methods including a first method and a second method when the representative temperature of the storage space falls within the convergence temperature range, and determining the output of the cooling device according to the second method when the representative temperature of the storage space is out of the convergence temperature range; and operating the cooling device at the determined output.

The present invention discloses a method of controlling an air-cooling device and an air-cooling device. The air-cooling device enables two chambers to achieve simultaneous refrigeration, to achieve simultaneous heating, or to achieve refrigeration in one chamber and heating in the other chamber by employing a structural design with a single evaporator+a single evaporation blower+two dampers+three heating wires, in conjunction with the control of operational relationship of the compressor, the evaporation blower, the heating wires and the dampers; in conjunction with the control in the above three manners, the thermostatic control of the air-cooling device with a single refrigeration system and dual temperature zones is achieved with a simple structure and process.

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 ice maker assembly provided in the storage space. The ice maker assembly includes an ice maker provided forward of a cold air discharge port that is provided at a rear portion of the storage space, where the cold air discharge port is configured to deliver cold air, a front cover that covers a front side of the ice maker and that is configured to be exposed to an outside of the cabinet based on the door being opened, and a heat insulating material provided at a rear surface of the front cover and configured to at least partially block the cold air passing through the ice maker from being delivered past a front surface of the front cover.

A refrigerator includes evaporator cases arranged in a freezing chamber and located on a bottom surface of a partition wall, an evaporator installed inside the evaporator cases, and grill covers arranged on a rear side of the evaporator cases and having a blowing fan installed therein. The refrigerator includes a refrigerating chamber discharge passage which extends from the grill covers to a refrigerating chamber and through which at least a portion of cold air passing through the blowing fan flows, and a freezing chamber discharge passage which extends from the grill covers to the freezing chamber and through which the remaining cold air among the cold air passing through the blowing fan passes.

A refrigerator is provided. The refrigerator includes a camera, a thermal imaging camera, a display, and a processor configured to acquire an image that photographed the inside of the refrigerator through the camera, identify an object included in the acquired image, acquire information on the temperature of the identified object based on a thermal image that photographed the inside of the refrigerator through the thermal imaging camera, and control the display to display information on the identified object and information on the temperature of the identified object.

An ice maker for mounting into a household cooling appliance includes a storage container for ice that is formed with an opening which is accessible from the top. A fan generates an air stream in the ice maker. An air guiding duct above the storage container is bounded by a first lateral duct wall, which is oriented in the depth direction of the ice maker and extends in the height direction, and is bounded by a second duct wall, which is a roof wall. The air guiding duct has a first opening towards the bottom so that an air stream escapes towards the bottom. The first opening of the air guiding duct is arranged offset viewed in the width direction of the ice maker so that the air stream exiting from the first opening of the air guiding duct flows along an outer side of the storage container.

A refrigerating appliance is provided. The refrigerating appliance comprises: —a first storage compartment and a second storage compartment, the first and second storage compartments being separated from each other; —a refrigeration circuit comprising a first evaporator associated to the first storage compartment, a second evaporator associated to the second storage compartment, and a compressor for causing refrigerant to flow in the refrigeration circuit through the first evaporator and the second evaporator, the first evaporator, the second evaporator and the compressor being fluidly connected in series; —temperature sensors adapted to sense a first temperature indicative of the temperature inside the first storage compartment and a second temperature indicative of the temperature inside the second storage compartment; —a control unit configured to set a flow rate of the compressor according to both: —a first difference between the sensed first temperature and a first storage compartment target temperature, and —a second difference between the sensed second temperature and a second storage compartment target temperature.

A refrigerating apparatus applied to a refrigerator is disclosed. The refrigerating apparatus includes a refrigerant, a depressurization gas, an evaporator, a condenser, a first connecting pipe, a second connecting pipe, a third connecting pipe, a blower device and a refrigerator body. The evaporator is provided with an inlet and an outlet; the condenser is provided with a condensation cavity, a gas inlet, a gas outlet and a liquid outlet; a molecular sieve membrane is disposed in the condensation cavity; one end of the first connecting pipe is connected to the outlet and the other end to the gas inlet; one end of the second connecting pipe is connected to the liquid outlet and the other end to the inlet; one end of the third connecting pipe is connected to the gas outlet and the other end to the inlet.