A refrigerator appliance includes a rear wall, side walls, a bottom wall, and partitions. The side walls are secured to and extend from the rear wall toward a front side of the refrigerator. The bottom wall is secured to the side walls along a bottom end of the rear wall. The side walls and the bottom wall define a cavity below the bottom wall and define an opening to the cavity along the front side of the refrigerator. The rear wall and the bottom wall define a machine compartment. An exterior surface of the rear wall defines an inlet to and an outlet from the machine compartment. A first partition extends outward from the exterior surface and is disposed between the inlet and the outlet. A second partition extends from a bottom of the first partition. The partitions are configured to segregate airflows between the inlet and outlet.

A refrigeration module, comprising: a module body, in which an installation space is defined; and a refrigeration system disposed in the installation space for use in generating cold, wherein a cold supply port is provided on the module body, the cold supply port is configured to be detachably connected to an external pipeline, and the cold generated by the refrigeration system is supplied to the external pipeline by the cold supply port. Further provided by the present invention is a refrigerator that has the refrigeration module. By means of separating the refrigeration module and a storage portion, the storage portion does not need to give way to the refrigeration system, and the internal volume of the refrigerator may be greatly increased; and the refrigeration module may be freely matched with one or more of the same or different storage portions as needed.

A refrigerator 10 comprises at least one box-shaped storage compartment 14 and a heat radiating member 23. The storage compartment 14 is formed in such a way that one side of a frame formed by a wall member is closed and the other thereof is provided with an opening surface configured to be opened or closed by a door. The wall member includes a hollow structure composed of a plurality of plate members 21 and 22 and a foam insulation 25 filled in the hollow structure. The heat radiating member 23 is arranged in the wall member. In the wall member, a pressure member 24 configured to press the heat radiating member against the plate member is provided. The pressure member 24 is a material configured to press the heat radiating member 23 under predetermined conditions.

A foot is connected to the bottom wall of a refrigeration cabinet. The foot is selectively movable relative to the bottom wall to adjust a vertical position of the foot with respect to the bottom wall. The bottom wall provides access to the foot from within the interior of the cabinet to allow a user to selectively move the foot to adjust the vertical position of the foot with respect to the bottom wall. The foot includes a stop configured to engage the bottom wall and thereby limit downward adjustment of the foot with respect to the bottom wall. A floor glide is connected to the bottom wall and initially protrudes downward from the bottom wall beyond the foot. The floor glide enables the cabinet to slide along a support surface to a deployment position so then the foot can be lowered to support the cabinet at the deployment position on the foot.

A refrigerator includes a cabinet, in which a cooling chamber and at least one storage space are defined, the cooling chamber being arranged at the bottom of the cabinet and directly below the storage space; a door body, which is arranged on a front surface of the cabinet so as to operably open and close the storage space; an evaporator, which is wholly horizontally placed in the cooling chamber in the shape of a flat cube, and is configured to provide cooling capacity to the storage space; and a liquid storage bag, which is arranged in the cooling chamber and connected to the evaporator. An included angle between a center line of the liquid storage bag and a horizontal line is 1° to 89°. A foam layer and a housing of the refrigerator may block the sound transmission of flow of a liquid refrigerant, to achieve a good sound insulation effect.

A refrigerator, comprising: a refrigerator body, comprising a storage liner at a bottommost position; a top cover, arranged to divide the storage liner into a storage space at the upper part and a cooling space at the lower part; and an evaporator, arranged in the cooling space and configured to cool airflow entering the cooling space to form cooling airflow; wherein the evaporator is placed on a bottom wall of the storage liner, and the bottom wall is provided with a limit structure at the front part and rear part of the evaporator respectively, to realize front and rear limits of the evaporator. The height of the storage space above the cooling space is increased and the user experience is improved. The evaporator is placed on the bottom wall of the storage liner to realize the front and rear limits of the evaporator.

A refrigerator comprises: a refrigerator body (10), at the interior of which a cooling chamber (11) and at least one storage space are confined, wherein the cooling chamber (11) is arranged at the bottom of the refrigerator body (10) and below the storage space; door bodies (20) arranged on a front surface of the refrigerator body (10) to operably open and close the storage space; and an evaporator (21), which is wholly horizontally placed in the shape of a flat cube in the cooling chamber (11) and configured to provide cold energy to the storage space, wherein a bottom wall of the cooling chamber (11) below the evaporator (21) is provided with a water pan (40) to receive condensate water generated by the evaporator (21), and the bottom of the water pan (40) is provided with compensation heating wires (80).

A method of making a vacuum insulated refrigerator structure includes positioning a core of overlapping stacked sheets of fiberglass mat in an envelope of impermeable barrier material. The core is pressed into a predefined three dimensional shape by pressing first and second mold parts together. The core is evacuated, and the envelope is sealed to form a three dimensional core having an airtight envelope around the core. The three dimensional vacuum core is positioned between a wrapper and a liner, and the wrapper and the liner are interconnected to form a vacuum insulated refrigerator structure.

A transport refrigeration unit is configured to provide conditioned air to a refrigerated cargo space and includes: an AC battery pack configured to store and convert DC electricity to AC electricity and provide the AC electricity to power the transport refrigeration unit as three phase electrical power, the AC battery pack includes: a first phase group including a first plurality of battery modules, the first phase group being configured to provide the AC electricity in a first phase; a second phase group including a second plurality of battery modules, the second phase group being configured to provide the AC electricity in a second phase; and a third phase group including a third plurality of battery modules, the third phase group being configured to provide the AC electricity in a third phase. The first phase, the second phase, and the third phase are each shaped as a stair step sine wave.

A transport refrigeration unit is configured to provide conditioned air to a refrigerated cargo space and includes: an AC battery pack configured to store and convert DC electricity to AC electricity and provide the AC electricity to power the transport refrigeration unit as three phase electrical power, the AC battery pack includes: a first phase group including a first plurality of battery modules, the first phase group being configured to provide the AC electricity in a first phase; a second phase group including a second plurality of battery modules, the second phase group being configured to provide the AC electricity in a second phase; and a third phase group including a third plurality of battery modules, the third phase group being configured to provide the AC electricity in a third phase. The first phase, the second phase, and the third phase are each shaped as a stair step sine wave.