An aircraft galley chiller is adapted to fit within a service column of the aircraft. The condenser is elongated, oriented vertically, and includes a bank of fans to increase airflow. The evaporator is also elongated and includes a bank of fans. The evaporator and condenser are oriented with the same plane to produce a footprint that fits within the service column. The evaporator includes a heater element to periodically heat and de-ice the evaporator.

A system for blast-freezing items includes a plurality of cells arranged side-by-side, each cell including a housing with a bay space, a plenum, a front air passage, a rear air passage, and a fan. The fan is positioned in the plenum and configured to circulate air through the bay space. Each cell also includes a plurality of channels to separate pathways of air to segments of the bay space. The system also includes a plurality of crane rails extending between rows of cells and at least one crane capable of traveling along the plurality of crane rails to load or unload each of the plurality of cells.

A blast cell system is provided with simple and scalable designs that prevent short cycling of air flow through any pallets in blast cells. The blast cell includes a plurality of suction channels that provide independent fluid pathways for directing the air drawn from different rows in the blast cell into the fan.

A controller, when a normal cooling operation is being performed, forward-drives a lower-side and an upper-side in-box blower fans, thereby causing internal air cooled by an evaporator to circulate within a commodity storage box in such a way that it enters a rear face duct through a lower-side opening and is discharged from an upper-side opening, and when a cold-maintaining operation is being performed, stops driving the lower-side and the upper-side in-box blower fans, and when a cooling recovery operation is being performed, forward-drives the lower-side in-box blower fan and reverse-drives the upper-side in-box blower fan, thereby causing internal air cooled by the evaporator to enter the rear face duct through the lower-side opening and causing internal air to enter the rear face duct through the upper-side opening, and also causing internal air entered the rear face duct to be discharged from the intermediate opening.

To provide a functional continuous rapid freezing apparatus with which cold air is made uniformly contact with the whole face of an article to be frozen, easily and rapidly passing the maximum ice crystal generating zone, and the central portion of the article to be frozen can reach for the predetermined temperature within a short period of time, a freezing chamber 2 in which an article Q to be frozen is stored, a heat exchanger 1 for cooling disposed on a central portion of the freezing chamber 2 as a partition to divide the freezing chamber 2 into a first freezing block 2a and a second freezing block 2b, a first blowing fan 5 disposed to face the heat exchanger 1 for cooling through the first freezing block 2a, and a second blowing fan 6 disposed to face the heat exchanger 1 for cooling through the second freezing block 2b, are provided.

Provided are a device (100) for self-adaptive regulation of air volume and a refrigerator (200) having the same. The regulating device (100) comprises: a drainage and air guide cavity (1), arranged on the back of a freezing chamber (201) of a refrigerator, the drainage and air guide cavity (1) comprising a funnel-shaped air collecting cavity (11) and a conical air outlet cavity (12) connected to the funnel-shaped air collecting cavity (11), an outlet of the conical air outlet cavity (12) facing a refrigerating chamber; a drainage tongue (2), provided in the conical air outlet cavity (12) so as to create a first outlet duct (122) and a second outlet duct (123) within the conical air outlet cavity (12), an inlet (20a) of the first outlet duct (122) being located on an extension line of a left side wall (113) of the funnel-shaped air collecting cavity (11) and an inlet (21a) of the second outlet duct (123) being located on an extension line of a right side wall (112) of the funnel-shaped air collecting cavity (11); and a fan (3) arranged inside of the funnel-shaped air collecting cavity (11). By rotating the fan (3), cold air is conveyed through the first outlet duct (122) and the second outlet duct (123) and into a refrigerating chamber (202) under the guide of the left side wall (113) or right side wall (112) of the funnel-shaped air collecting cavity (11).

A blast cell system is provided with simple and scalable designs that prevent short cycling of air flow through any pallets in blast cells. The blast cell includes a plurality of suction channels that provide independent fluid pathways for directing the air drawn from different rows in the blast cell into the fan.

A refrigerator damper system employs a fluidic valve providing switching of air between refrigerated compartments without the need for a movable valve plate such as can be obstructed by ice. In one embodiment, a bidirectional fan provides switching from a first compartment to a second compartment and then from a second compartment to a first compartment with change of fan direction.

A blast cell system is provided with simple and scalable designs that prevent short cycling of air flow through any pallets in blast cells. The blast cell includes a plurality of suction channels that provide independent fluid pathways for directing the air drawn from different rows in the blast cell into the fan.

A blast cell system is provided with simple and scalable designs that prevent short cycling of air flow through any pallets in blast cells. The blast cell includes a plurality of suction channels that provide independent fluid pathways for directing the air drawn from different rows in the blast cell into the fan.