A method for controlling a refrigerator includes: a step for determining whether or not a defrosting initiation condition is satisfied with respect to an evaporator; a step for, if the defrosting initiation condition is satisfied, detecting a pressure differential by means of one differential pressure sensor for measuring the pressure differential between a first through hole, which is positioned between the evaporator and an inlet port having air flowing in from a storage chamber, and a second through hole which is positioned between the evaporator and a discharge port having air discharged to the storage chamber; and a defrosting step for variably defrosting in accordance with the measured pressure differential.

A control method and device for a refrigerator, and the refrigerator. The refrigerator comprises at least two compartments. The control method comprises: acquiring a compartment currently requesting cooling; after detecting and confirming a first set time, the compartment currently requesting cooling not being cooled, determining a currently cooled compartment, and interchanging currently set valve body rotation angles corresponding to the compartment currently requesting cooling and the currently cooled compartment requesting cooling. The present disclosure may solve the problem in which a refrigerator cannot be cooled normally due to a connection error between the capillary tube and a solenoid valve during the production of a multi-system refrigerator, and reduces the refrigerator repair rate, improves the refrigerator production efficiency, and reduces fabrication costs.

In one implementation, a system for controlling defrost of a chilled environment includes a camera configured to capture images of one or more objects located in the chilled environment and a defrost control unit. The defrost control unit is configured to: receive an image of the one or more objects from the camera, analyze the image of the one or more objects to quantify an amount of frost formation on the one or more objects, determine when to initiate a defrost cycle in the chilled environment based on the amount of frost formation on the one or more objects, and in response to determining to initiate the defrost cycle, initiating the defrost cycle by sending a defrost control signal to a defroster. The defroster is configured to perform the defrost cycle within the chilled environment in response to receiving the defrost control signal.

A freezer case includes a refrigeration system and a controller. The controller is configured to store a plurality of setpoint instruction sets associated with a plurality of possible operating modes, select a current operating mode from the plurality of possible operating modes, assign a value for the superheat setpoint by executing the setpoint instruction set associated with the current operating mode, control the refrigeration system in accordance with the superheat setpoint.

A refrigerator including a compressor, a condenser, a freezing chamber evaporator, a freezing chamber fan, a defrosting heater, a wine chamber evaporator, a wine chamber fan, a path switching device configured to guide the refrigerant condensed in the condenser to the freezing chamber evaporator in a freezing chamber mode and to guide the refrigerant condensed in the condenser to the wine chamber evaporator in a wine chamber mode, and a controller configured to turn on the defrosting heater to perform a freezing chamber defrosting mode for defrosting the freezing chamber evaporator, to control the path switching device to the wine chamber mode while the temperature of the wine chamber is dissatisfied when the temperature of the wine chamber is dissatisfied in the freezing chamber defrosting mode, and to drive the wine chamber fan.

A refrigerator is designed considering pressure distribution around a cooling fan with respect to a fluid outlet of a frost detecting device provided for frosting detection, so that the design may be efficiently perform with respect to the frost detecting device and precise frosting detection may be performed.

A method for determining a time frame for when a freezer having a compressor should be defrosted include the steps of measuring compressor cycling over time, determining a change in compressor cycling over time, and determining from the change in in compressor cycling over time determined a time frame for when the freezer should be defrosted.

A refrigerator in which a performance cycle for a next frost detection operation according to a logic temperature (ΔHt) checked through a frost detection operation may be changed. Thus, unnecessary power consumption may be reduced and power consumption efficiency may be improved.

A side-by-side refrigerator system includes a first refrigerated cabinet and a second refrigerated cabinet alongside the first refrigerated cabinet. A heater is positioned within a wall of one of the first refrigerated cabinet and the second refrigerated cabinet. A controller is configured to constantly operate the heater during a side-by-side operating mode. The controller is disposed within the one of the first refrigerated cabinet and the second refrigerated cabinet.

Disclosed is a carbon dioxide heat pump evaporator, comprising side evaporators having defrosting water flow channels formed thereon, an evaporator tray which is arranged at the bottoms of the side evaporators and is used for supporting the side evaporators, and a defrosting drainage system, wherein the defrosting drainage system comprises a plurality of defrosting electric heating tubes inserted into the side evaporators, water receiving gutters which are connected to the defrosting water flow channels, gutter electric heating mechanisms for heating the water receiving gutters, and drainage pipes which are connected to the water receiving gutters and are provided with conduit electric heating tracing bands; and the evaporator tray, the water receiving gutters and the drainage pipes are sequentially arranged from top to bottom. The carbon dioxide heat pump evaporator is suitable for low-temperature areas, especially for areas of extreme cold, and has the characteristics of a short defrosting time, smooth drainage, etc.