In a method for the inactivation of microorganisms in liquid foods, a liquid food is mixed with a pressurized, liquefied gas at a pressure which is sufficient to maintain the liquefied gas in the liquid state. The mixture of food and gas is then depressurized to a pressure at which the liquefied gas is vaporized. According to the invention, before or during the depressurization to the second pressure, the mixture is guided through a pipeline and brought up to a flow speed in the pipeline which is sufficient to form cavitations in the liquid food.

In a method for the inactivation of microorganisms in liquid foods, a liquid food is mixed with a pressurized, liquefied gas at a pressure which is sufficient to maintain the liquefied gas in the liquid state. The mixture of food and gas is then depressurized to a pressure at which the liquefied gas is vaporized. According to the invention, before or during the depressurization to the second pressure, the mixture is guided through a pipeline and brought up to a flow speed in the pipeline which is sufficient to form cavitations in the liquid food.

A system and method for storing, preserving and cooking meals using the sous-vide technique. The system and method of the present invention is designed to automatically cook, upon request a meal having various ingredients by immersing bagged food in temperature-controlled liquid. The cooking time may be manually or automatically programmed from downloaded cooking direction associated with the food. The cooking request may be given by a user from the physical apparatus or using a mobile device application.

A high pressure process for decontamination comprises subjecting a hermetically-sealed package containing a product and a gas to an operating pressure by a pressurizing media containing water, wherein the product has a water activity less than or equal to 0.9; increasing the operating pressure to change the gas into a different phase; and maintaining the operating pressure for a sufficient length of time to achieve some decontamination inside the package.

Provided herein are techniques, devices, and systems for determining the safety of an ingestible product with respect to a contaminant as the ingestible product is being processed. A computing system may receive data associated with processing of an ingestible product. Based on the data, and using a model, the computing system may determine a value associated with the ingestible product with respect to a target contaminant. Based on the value, the ingestible product can be classified as a class label indicative of a safety of the ingestible product with respect to the contaminant, such as a classification of “safe” or “unsafe.” In some examples, a reduction of a contaminant in an ingestible product is dynamically monitored, in real-time, as the ingestible product is being processed.

Provided herein are techniques, devices, and systems for determining the safety of an ingestible product with respect to a contaminant as the ingestible product is being processed. A computing system may receive data associated with processing of an ingestible product. Based on the data, and using a model, the computing system may determine a value associated with the ingestible product with respect to a target contaminant. Based on the value, the ingestible product can be classified as a class label indicative of a safety of the ingestible product with respect to the contaminant, such as a classification of “safe” or “unsafe.” In some examples, a reduction of a contaminant in an ingestible product is dynamically monitored, in real-time, as the ingestible product is being processed.

The disclosure relates to preparation, processing, and packaging of fresh foods, particularly proteins. In various implementations, the methods include steps for ozone exposure, reduction of surface moisture, introduction of a modified atmosphere, and high pressure pasteurization. Prior to packaging the protein may be exposed to ozone and undergo dehydration to reduce the amount of moisture on the surface of the protein. The protein may then be packaged in a modified atmosphere, lacking oxygen, and then undergo high-pressure pasteurization.

A disinfectant device provides a solution to disinfect bulk quantities of small items such as food items. The disinfectant device has a housing, an inlet, an outlet, a shaker tray positioned to descend from a first height on the inlet side to a second height on the outlet side, the second height lower than the first height, wherein the shaker tray is configured to shake or vibrate via a motor, and at least one disinfecting light is positioned within the housing and above the shaker tray, the light configured to disinfect items passing on the shaker tray. The disinfectant device may have a hopper having a gate to the shaker tray. The gate may be manually operated or actuated by a motor to control the number of items on the shaker tray at any given time, thereby ensuring adequate exposure to the disinfecting light.

A disinfectant device provides a solution to disinfect bulk quantities of small items such as food items. The disinfectant device has a housing, an inlet, an outlet, a shaker tray positioned to descend from a first height on the inlet side to a second height on the outlet side, the second height lower than the first height, wherein the shaker tray is configured to shake or vibrate via a motor, and at least one disinfecting light is positioned within the housing and above the shaker tray, the light configured to disinfect items passing on the shaker tray. The disinfectant device may have a hopper having a gate to the shaker tray. The gate may be manually operated or actuated by a motor to control the number of items on the shaker tray at any given time, thereby ensuring adequate exposure to the disinfecting light.

A recirculation circuit for a processing vessel is configured to process a load with a process fluid. The recirculation circuit includes a first circuit portion configured to recirculate a first portion of the process fluid through the vessel. The first circuit portion includes a first pump having a first flow rate and a first output pressure and a heat exchanger in fluid communication with the first pump. A second circuit portion is configured to recirculate a second portion of the process fluid through the vessel. The second circuit portion includes a second pump having a second flow rate higher than the first flow rate and a second output pressure lower than the first output pressure.