The present disclosure relates to a refrigerator. The refrigerator includes first storage for defining a first storage space therein, a door for opening and closing the first storage space, and a plurality of shelves installed in the first storage space for placing food thereon. The door includes a door frame having an opening defined therein, and mounted pivotable to the first storage, a panel assembly inserted into the opening, and disposed to allow the first storage space to be seen through, and a flow path blocking portion mounted on the door frame, wherein the flow path blocking portion shields a gap defined between the panel assembly and the shelf as the door closes the first storage space.

A storage container having a basin defining an interior space, and comprising two or more partition walls; a freezer partition wall defining a freezer compartment, a chill partition wall defining a chilled compartment, a cooling chamber being defined between said partition walls, wherein each of said partition walls are configured, when a cooling medium is received within said cooling chamber, for allowing airflow therethrough to its respective compartment, thereby maintaining a temperature difference between said freezer compartment and chilled compartment.

A storage container having a basin defining an interior space, and comprising two or more partition walls; a freezer partition wall defining a freezer compartment, a chill partition wall defining a chilled compartment, a cooling chamber being defined between said partition walls, wherein each of said partition walls are configured, when a cooling medium is received within said cooling chamber, for allowing airflow therethrough to its respective compartment, thereby maintaining a temperature difference between said freezer compartment and chilled compartment.

A refrigerator comprises: a refrigerator body having an open front side to define a first chamber; and a door body used to open or close the first chamber and defining a second chamber. The door body further defines a square annular air duct surrounding an outer side of the second chamber. The air duct comprises an air inlet section, two air supply sections and an air outlet section which are respectively located at an upper side, two transverse sides and a lower side of the second chamber. The air inlet section has an air inlet for intake of cold air. Each air supply section has an air supply portion for supplying the cold air to the second chamber. The air outlet section has an air outlet for discharging the remaining cold air in the air duct. The temperature in the chamber defined by the door body can be independently controlled.

Provided is a refrigerator, including a freezer compartment, a refrigeration compartment, a drying compartment, an air intake channel, a first sealing apparatus, and a second sealing apparatus. The drying compartment is independently provided within the refrigeration compartment in a sealed manner. The drying compartment is provided with an air inlet and an air outlet. The first sealing apparatus is provided in the drying compartment and can switch between sealing an air outlet of the air intake channel and leaving the air outlet of the air intake channel open. The second sealing apparatus is provided at the air outlet and can switch between sealing the air outlet and leaving the air outlet open. Cooled air in the freezer compartment is introduced into the drying compartment and then mixed with air in the drying compartment, a rise in the temperature of the cooled air allows the relative humidity in the drying compartment to be reduced.

A method and a device for controlling a low-temperature refrigeration air valve, the method includes: acquiring a current environment temperature; according to the current environment temperature, determining an initial target pressure of the current system and an initial opening degree of an air valve; acquiring an actual pressure of the current system and a target pressure of the current system; and adjusting an opening degree of the air valve according to a difference value between the target pressure of the current system and the actual pressure of the current system, wherein the air valve is disposed at a low-temperature cover. An opening degree of the air valve is adjusted according to the difference value between the target pressure of the current system and the actual pressure of the current system, to meet the refrigeration demand of the user in an ultra-low temperature environment, expanding the operation scope of refrigeration.

A refrigerator comprises: a storage compartment, at least divided into a refrigerating compartment and a freezing compartment a first evaporator, arranged at a cooling compartment connected to the storage compartments through supply air ducts; a second evaporator, arranged inside the freezing compartment a switching valve, used to switch the flow of a refrigerant to a refrigerant channel connected to the second evaporator; a fan, used to enable cooled air in the first evaporator to flow from the cooling compartment to the storage compartments; a first air duct damper, inserted in the supply air duct connected to the refrigerating compartment and a second air duct damper, inserted in the supply air duct connected to the freezing compartment.

A method of controlling a refrigerator includes: controlling a cooling unit such that an output of the cooling unit becomes a first reference output for a first reference time previously determined; controlling the cooling unit such that the output of the cooling unit becomes a second reference output for a second reference time previously determined; calculating a representative value of a temperature of a storage compartment for an operating period, which is made by a sum of the first reference time and the second reference time, and comparing the calculated representative value with a specific temperature in a temperature satisfying range of the storage compartment; and varying, by a control unit, at least one of the first reference time and the second reference time depending on a comparison result between the specific temperature and the representative value and controlling operating of the cooling unit based on a varied reference time.

A refrigerator includes a storage compartment, a door, an air outlet, an imaging unit, and a determination unit. The storage compartment has a storage region that stores a stored object. The door opens and closes the storage compartment. The air outlet is provided in a rear wall of the storage region and blows cold air into the storage region. The imaging unit is provided at an inner side of the door at a position higher than or equal to a height of the air outlet and acquires an image of the storage region from the door. The determination unit determines an arrangement state of the stored object stored in the storage region based on the image acquired by the imaging unit.

A refrigerator includes a cabinet including a refrigerating compartment and an evaporation chamber, a first door, a housing in the first door, an ice making room defining a cool air inflow hole and a cool air discharge hole, a chiller room defining a cool air discharge hole, a second door connected to the first door, a partition wall defining the ice making room, the chiller room, and a communication hole, a damper opening and closing the communication hole, a cool air supply duct connecting an outlet of the evaporation chamber and the cool air inflow hole to supply cool air of the evaporation chamber to the ice making room, and a cool air return duct having a first inlet connected to the cool air discharge hole of the ice making chamber and a second inlet connected to the cool air discharge hole of the chiller room.