A cooling drum for freezing granules has an inlet for receiving the granules and an outlet located opposite to the inlet for discharging the granules. The cooling drum for freezing granules includes: a first cylinder part having a first inner surface formed of a first material; and a second cylinder part located closer to the outlet than the first cylinder part and having a second inner surface formed of a second material. The first material has a lower thermal conductivity than that of the second material.

A food freezing apparatus according to the present invention comprises: a transport unit having multiple vertically spaced levels provided so as to continuously transport food; a cooling unit for cooling the food transported by the multiple levels of the transport unit; a pre-freezing unit for pre-freezing the food transported by the multiple levels of the transport unit after having been cooled; a freezing unit for freezing the food transported by the multiple levels of the transport unit after having been pre-frozen; and a defrosting unit connected to the freezing unit so as to remove frost that forms inside the freezing unit.

A cooler including a compartment, a conduit including a first end portion configured to be in communication with the compartment and a second end portion, food product at a first product temperature entering the first end portion, a fluid discharge positioned substantially within the conduit between the first end portion and the second end portion, and a pressurized fluid source in communication with and for supplying fluid through the fluid discharge, the fluid being at a first fluid temperature less than the first product temperature, the pressurized fluid source being operable to propel the fluid through the fluid discharge to move the food product from the first end portion of the conduit toward the second end portion and to cool the food product to a temperature below the first product temperature.

The present disclosure provides, inter alia, processes and apparatuses for rapid freezing of consumable and non-consumable products. In certain embodiments, the processes and apparatuses of the present disclosure yield the rapidly frozen consumable and non-consumable products using the expansion of dense gas. The present disclosure also provides consumable and non-consumable products produced by the processes and apparatuses disclosed herein.

In a freezer having an internal space therein in which a blower and an impingement plate are disposed and through which a conveyor for a food product passes, an impingement apparatus, includes a hood disposed at the internal space for coacting with the blower and the impingement plate, the hood including a sidewall defining a sub-chamber in which the blower is received; and a pipe having an end opening into the sub-chamber for introducing a pulse of cryogen to the sub-chamber for increasing a pressure in the sub-chamber and contacting the impingement plate. A related method is also provided.

A cooling system is provided. The cooling system comprises a first solution tank configured for receiving a cooling fluid. The cooling system may also include a second solution tank within the first solution tank and configured for receiving a food edible solution. The cooling system may also include a cooling fluid tube coiled around the second solution tank. The cooling system may further include a food edible solution tube coiled around the cooling fluid tube and/or the second solution tank.

A method and associated equipment for obtaining a product in the form of deep-frozen, dissolved-gas-rich granules, particles or beads from a liquid, semi-liquid or pasty matrix, comprises the following steps: gasification of the matrix by incorporating a gas; dispensing the matrix in the form of drops; and cryogenically freezing the matrix drops by immersion in a cryogenic fluid. The step of gasification of the matrix involves dissolving a large amount of the gas generated by the evaporation of the cryogenic fluid in the drops by increasing the number of gas molecules in a high gas density zone, called high molecular density zone, located above the surface of the cryogenic fluid and on the path of the matrix drops before they are immersed in the fluid.

The efficiency of a device for cooling or heating objects on a belt that moves through a path of a helix, in which gaseous cooling or heating medium is circulated within the device, is improved by positioning fans that circulate the cooling or heating medium so that the fans are distanced from the top of the helix.

A method for freezing a food product in a cryogenic freezer includes sensing at least one physical characteristic of the food product in real time, providing a cryogenic substance to the food product for heat transfer at said food product, automatically self-adjusting the heat transfer at the food product responsive to the sensing the at least one physical characteristic, and continuously self-adjusting the heat transfer for bringing the food product to a select temperature. A related freezer apparatus is also provided.

A cooler including a compartment, a conduit including a first end portion configured to be in communication with the compartment and a second end portion, food product at a first product temperature entering the first end portion, a fluid discharge positioned substantially within the conduit between the first end portion and the second end portion, and a pressurized fluid source in communication with and for supplying fluid through the fluid discharge, the fluid being at a first fluid temperature less than the first product temperature, the pressurized fluid source being operable to propel the fluid through the fluid discharge to move the food product from the first end portion of the conduit toward the second end portion and to cool the food product to a temperature below the first product temperature.