Methods and apparatuses for transferring heat to and from multiple objects. Such a method entails placing objects in a vessel that contains a heat transfer fluid so that the objects contact the heat transfer fluid. The heat transfer fluid is at a temperature that is different from the temperature of the object, and is induced to circulate along a continuous flowpath. Each object is at least partially disposed in the flowpath of the heat transfer fluid, and each object is individually rotated about an axis of rotation thereof. The heat transfer fluid continues to circulate and the objects continue to rotate for a time sufficient to cause the temperatures of the objects to become closer to the heat transfer fluid temperature.

A suspension device enables a freely projecting suspension of a food-accommodating container. The suspension device has a central rail for the direct suspension of the food-accommodating container. The central rail is a profiled rail made of metal. There is also described an arrangement of a suspension device with a food-accommodating container suspended in a freely projecting manner on the profiled rail, and a household refrigerator component.

A freezing device comprising a refrigeration base housing having a refrigeration system therein and a bottle receiver above the refrigeration base housing. The bottle receiver has a top opening for accepting a portion of a bottle of consumable beverage therein such that a top portion of the bottle is not encompassed by the bottle receiver. The bottle receiver has an air space between at least one sidewall of the bottle receiver and the bottle. The refrigeration system cools the space within the bottle receiver for freezing a bottom portion of the consumable beverage encompassed by the bottle receiver.

A device (100; 200; 300; 400) comprising: a first arm (1051; 2051; 3051; 4051) adapted to accommodate and retain a bottle neck of a beverage bottle; a second arm (1052; 2052; 3052; 4052), extending from the first arm (1051; 2051; 3051; 4051), configured to extend towards a bottle body of the beverage bottle when the device (100; 200; 300; 400) is mounted on the beverage bottle; a temperature measuring unit (120), housed in the second arm (1052; 2052; 3052; 4052), facing the bottle body when the device (100; 200; 300; 400) is mounted on the beverage bottle, and a wireless communication unit (125) coupled to the temperature measuring unit (120) and adapted to wirelessly communicate with a display unit arranged to provide an indication associated with the temperature of the beverage bottle as measured by the temperature measuring unit (120).

A float with a beverage holder cooler has two (2) interior voids configured for ice storage within the cooler separated by a central wall. The voids are accessed by a common side wall which is securable in a closed position by a strap and a fastener. A beverage container holding aperture is disposed within the top center face of the cooler and extends into the common side wall.

Disclosed is a container assembly for containing freezable liquid. The container assembly comprises a V-shaped container having a V-shaped cross-section and being formed from freezer-safe material, and a support base having a V-shaped groove sized to receive and cooperate with the container thereby to support the container during filling with freezable liquid. Also disclosed is a freezer container support structure comprising two or more plates and at least two spaced support members. The support members are adapted to engage the plates in spaced locations along the support members, to maintain one or more freezer containers between the plates during freezing of a freezable liquid contained in each said freezer container.

A portable fluid transportation enclosure can include a specimen carrier within a portable container that can be transported portably by a user. The carrier can define one or more specimen bores therein, where each specimen bore can be configured to receive a specimen therein. Such a gyroid shaped carrier within a container can improve heat transfer between specimen supported by the carrier and can help to limit shock transferred to the specimen within the carrier, such as from an impact to the container in which the gyroid carrier is located.

A freezing system includes a freezing device and an acquisition unit. The freezing device includes: a holding room for holding a plurality of containers, the plurality of containers each having an RF tag attached thereto, containing a material to be cooled, and being held at corresponding one of predetermined positions; and a plurality of antennas provided inside the holding room each corresponding to one of the predetermined positions, the plurality of antennas each being configured to receive information stored in the RF tag. The acquisition unit acquires information received by the plurality of antennas, with the plurality of containers being held in the holding room.

A refrigerator has a cabinet with a storage compartment. A door is provided for opening and closing the storage compartment. A receiving box has a box body provided with a receiving space and a cover for selectively opening and closing the receiving space. A tray is removably placed in the receiving space. The tray may be formed with a plurality of receiving cells.

In accordance with the principals of the present invention, a frozen tube is adapted to securely surround the can, the frozen tube utilizing high heat capacity/thermal mass to wick heat from the beverage in the can. Contained within the frozen tube, a plurality of fins are provided thus acting as a heatsink. The presence of the fins act as a heatsink by increasing convective, conductive, and radiative heat dissipation if used in the absence of the frozen tube and conductive heat dissipation if used with the frozen tube.