Directly heating a protein-enriched milk product occurs by introducing steam, the direct heating taking the form of an infusion or injection method. The described technique significantly extends service time, ensuring a content of non-denatured whey proteins in the treated protein-enriched milk product greater than that obtained in the prior art. The milk product, which is preheated and kept at temperature is indirectly cooled before direct heating by a recuperative cooling step from the preheating temperature to a cool-down temperature with a temperature difference ranging from 5 K to 10 K. The direct heating from the cool-down temperature to the high pasteurization temperature is controlled by direct heating setting parameters which are known per se. Finally, the milk product is cooled by flash cooling from the high pasteurization temperature to a necessarily required exit temperature.

A food processing vat is provided with a zoned heat transfer system that provides zoned temperature control to the vat. The zoned heat transfer system selectively transmits heat to or removes heat from different portions of a bottom wall and/or side walks) of the vat. A heat transfer fluid may be directed through the zoned heat transfer system along a flow path that is selected based on a target size and/or a target temperature of a batch of food product being processed in the vat.

The invention relates to a continuous process for freezing a flow of aqueous material in liquid form and moving the aqueous material through at least one tube from an inlet of the tube to an outlet of the tube so as to form a breakable or cuttable frozen extrusion without bursting the tube. The process creates an extruded material that comprises liquid aqueous material entrapped between frozen aqueous material to self-lubricate the extrusion as it moves through the tube. An apparatus for carrying out the process of the invention is also provided.

A pasteurization system is configured for incorporating a food treatment system which includes a mix hopper, a freezing cylinder, and a cooling condenser. The pasteurization system includes a pasteurizing pipeline and a cooling module. The pasteurizing pipeline includes a forwarding passage guiding a heat exchanging medium from the compressor to the mix hopper and the freezing cylinder, and a returning passage guiding the heat exchanging medium from the mix hopper and the freezing cylinder back to the compressor through the cooling condenser. The cooling module is operatively coupled at the returning passage for not only reducing the temperature and pressure of the heat exchanging medium at the returning passage but also releasing an excessive energy of the heat exchanging medium before returning back to the compressor.

Directly heating a protein-enriched milk product occurs by introducing steam, the direct heating taking the form of an infusion or injection method. The described technique significantly extends service time, ensuring a content of non-denatured whey proteins in the treated protein-enriched milk product greater than that obtained in the prior art. The milk product, which is preheated and kept at temperature is indirectly cooled before direct heating by a recuperative cooling step from the preheating temperature to a cool-down temperature with a temperature difference ranging from 5 K to 10 K. The direct heating from the cool-down temperature to the high pasteurization temperature is controlled by direct heating setting parameters which are known per se. Finally, the milk product is cooled by flash cooling from the high pasteurization temperature to a necessarily required exit temperature.

Heat exchange devices, including aseptic cooler devices, and systems including same are provided. Methods of using heat exchange device are also provided. In a general embodiment, the present disclosure provides heat exchangers having an open chamber configuration and including a first section containing a cooling or heating media and a second section containing a food product. The first section includes a level detecting device that is configured to maintain a level of cooling or heating media in the first section, while preventing the cooling or heating media from pressurizing the first section. The open chamber configuration provides an air break at a top portion of the first section that ensures that the cooling or heating media entering the first section is at, or close to, atmospheric pressure.

In a device for freezing milk, in particular colostrum (3), in a container (5) comprising a temperature control element (10), the temperature control element remains in the frozen milk.

Methods, compositions, and articles of manufacture for preparing frozen beverages are described. The methods and articles generally include first and/or second frozen pellets. Upon mixing the frozen pellets with an appropriate liquid for a sufficient time, a frozen beverage is obtained. Articles of manufacture including frozen pellets, as well as optional objects such as straws, spoons, and mixing containers are disclosed. Methods, compositions, and articles of manufacture for preparing frozen pellets are also described.