Provided is a supercooling refrigerator including, so as to supercool foods such as fish or meat and more uniformly and stably maintain a temperature in a storage chamber supercooling the foods, a body including a storage chamber storing goods such as the fish or meat in a supercooled state, a door installed in the body, a plurality of shelves installed in the storage chamber, on which the goods are stored, a cooling unit cooling internal air of the storage chamber, a cooling air supplying unit circulating the air cooled by the cooling unit into the storage chamber, and a cool air controlling unit controlling the temperature of the cool air supplied from the cool air supplying unit in a supercooling temperature range of the stored goods.

The invention provides a refrigerator, comprising a top air passage provided at a top wall of the storage compartment and connected with the refrigeration air passage to receive refrigeration air therefrom; an air guiding pipe comprising an air inlet end connected with the top air passage, an air outlet end for supplying air to the storage compartment, and an air outlet opening downwards; and a first air supply device configured to cause air flow to enter the air guiding pipe via the top air passage, such that the refrigeration air flowing into the top air passage from the refrigeration air passage is blown downwards in a concentrated manner via the air guiding pipe.

A refrigerator and a method of control thereof, whereby after driving of a compressor and a blower fan is stopped as temperatures of a refrigeration compartment and a freezer compartment are in a satisfactory state, opening/closing operations of a damper are repeatedly performed, so that cold air in the freezer compartment is supplied into the refrigeration compartment. Alternatively, if the temperature of the refrigeration compartment reaches an upper limit temperature, the repeated opening/closing operations of the damper are started. The repeated opening/closing operations of the damper are performed until the temperature of the refrigeration compartment reaches a lower limit temperature, so that a cooling operation of the refrigeration compartment is performed only once while the compressor is being driven.

Provided is a refrigerator. The refrigerator includes a cabinet defining a refrigerating compartment and a freezing compartment, a heat exchange chamber defined in a side of the cabinet to provide a space for receiving an evaporator, a storage compartment defined in the cabinet, the storage compartment being independent from the refrigerating compartment, the freezing compartment, and the heat exchange chamber, a supply duct assembly connecting the heat exchange chamber to the storage compartment to provide a cool air supply passage, and a guide duct communicating with the supply duct assembly, the guide duct extending from a rear surface of the storage compartment up to a front portion of the storage compartment to guide cool air into a front side of the storage compartment. The guide duct discharges the cool air from the front portion of the storage compartment toward the inside of the storage compartment.

An air-cooled refrigerator supplying air through a centrifugal fan, comprising a bottom liner, an air duct back plate, and the centrifugal fan. A cooling chamber and a storage space are defined in the bottom liner; the air duct back plate is provided in front of a back wall of the bottom liner, and defines an air supply duct with the back wall of the bottom liner; the centrifugal fan comprises a volute and an impeller; the volute is arranged obliquely upwards from front to back at the back of the cooling chamber, and a fan cavity and a gradually widened exhaust cavity are defined in the volute; the fan cavity is formed into a continuous spiral; the gradually widened exhaust cavity is gradually widen backwards from the fan cavity; the impeller is provided in the fan cavity; and the inner wall face of the fan cavity is continuous and smooth.

An air-cooled refrigerator comprises a bottom liner, a fan bottom shell, an air duct cover plate, and fan blades. A cooling chamber and a storage space are defined in the bottom liner. The fan bottom shell is arranged at a rear portion of the cooling chamber. The air duct cover plate comprises a back plate portion and a fan upper cover. The back plate portion is disposed in front of a rear wall of the bottom liner. The fan upper cover obliquely extends downward from a lower end of the back plate portion into the cooling chamber, covers the fan bottom shell and is fastened thereto. The back plate portion and the fan upper cover are integrally formed. The fan blades are arranged in a fan cavity, and enable formation of a refrigeration airflow discharged from the cooling chamber to an air supply duct.

An automated grid based storage and retrieval system includes a framework structure including upright members and a grid of horizontal rails provided at upper ends of the upright members. The framework structure defines a plurality of storage volumes arranged adjacent one another below the horizontal rails. The storage volumes are open against the horizontal rails such that storage container vehicles may lower and raise storage containers into and out of the storage volumes. The system includes a plurality of vertical walls surrounding each of the plurality of storage volumes, and a cooler system adapted to draw air from an input of the cooler system, cool the air drawn from the input, and blow cooled air through an output of the cooler system. For each of the plurality of storage volumes, the system further includes a first air damper connected between the output of the cooler system and an air release area above the storage volume, and a second air damper connected between a void beneath the storage volumes and the input of the cooler system. The system includes a controller. The controller is adapted, independently for each of the plurality of storage volumes, to adjust airflow through the first air damper associated with that storage volume to control an overpressure and air temperature in the air release area, and to adjust airflow through the second air damper associated with that storage volume to control an underpressure in the void, such that a storage volume temperature is controlled separately for each of the plurality of storage volumes. The storage volume temperature is regulated by the air temperature in the air release area and by controlling a pressure differential between the overpressure in the air release area and the underpressure in the void in each of the storage volumes.

The present invention may include a heat exchanger case that accommodates a first heat exchanger and constitutes at least a portion of a second wall of the second storage space. The heat exchanger case includes a hinge device, and the hinge device may rotate while supported by a hinge holder of the storehouse body so that the heat exchanger case may move in a direction in which the heat exchanger case is in close contact with the storehouse body.