Predictive cooking systems and methods. A representative system can include a cooking device submergible in a container of fluid and a memory device storing instructions for causing a processor to receive information and determine heater set point temperature and on time. The processor can receive information indicative of one or more characteristics of a food item to be cooked in the fluid and a desired food temperature. The processor can perform a control process that can include sending instructions for controlling a heater, obtaining a temperature measurement of the fluid from a temperature sensor, determining a measurement of power delivered to the heater, determining constants related to corresponding physical characteristics of the fluid and/or the container based on at least one of the temperature measurement and the measurement of power, and determining a food temperature of the food item.

A food safety related management method includes: allowing a terminal to access an authenticated account; receiving reported data in relation to a defective food product from the terminal; searching a database for piece(s) of highly related data each related to a defective food product and each with a purchase time within a time interval that is defined based on the reported data; searching the piece(s) of highly related data for one(s) with overlapping issues of concern and identical merchant information with the reported data; creating a communication group for communication among accounts used to upload the reported data and said one(s) of the piece(s) of highly related data; and inserting the reported data into the database.

A method of and a system for surface pasteurizing or sterilizing low-moisture particulate foods, such as nuts, oats, and spices, is disclosed wherein the foods are pre-heated, pasteurized or sterilized in a gas, optionally dried, and cooled. The gas pasteurizing or sterilizing the foods contains water vapor and one or more further gasses, preferably air.

An in-line shell egg pasteurizer has a clean-in-place system. Empty shell egg carriers are placed in the water bath for multiple cleaning cycles. The cleaning solution level is lowered to expose the shell egg carriers and the top parts of the water bath walls. An air perturbation is used to agitate cleaning solution held in the bottom of the water bath and clean heating coils and other components located in the bottom of the water bath. Sprayers (e.g., nozzles, cleaning spray balls, etc. . . . ) mounted on a hood over the water bath clean the top parts of the water bath walls and the empty shell egg carriers placed in the water bath.

The invention relates to a system (1) and a method for pasteurizing foods packed in closed containers (2). The containers (2) are supplied with a processing liquid (11) in at least one heating zone (5,6), at least one pasteurization zone (7, 8), and at least one cooling zone (9, 10). In order to cool and heat the processing liquid (11) as needed, a coolant (23) is cooled by means of a heat pump (22) in a cooling circuit (20), and a heating medium (33) is heated by means of the heat pump (22) in a heating circuit via a respective heat exchanger (19, 30) in each case. In order to provide cooling energy, the cooled coolant (23) is introduced into a lower end region of a cold buffer store (24), and in order to provide heating energy the heated heating medium (33) is introduced into an upper end region of a heat buffer store (35).

Device and method suitable for disinfecting herbs using plasma are disclosed. The device comprises a chamber and two sets of electrodes in an opposed position one relative to the other, inside the chamber. Each electrode in one set has a counterpart electrode in the other set, the two electrodes positioned facing each other and being configured to connect to a RF HV power supply, to produce a plasma-generating EM field in the space between the electrodes. The device further comprises a dielectric carrier positioned inside the chamber in the space between the two sets of electrodes, the carrier being dimensioned and configured to carry herbs in granular form such as powder or particles thereon. A portable sealable container comprising a unidirectional valve is also disclosed, configured to store herbs thereinside during plasma treatment in the device, and to store the disinfected herbs after treatment under vacuum. A device for disinfecting herbs by evaporating a disinfection agent in an evacuated chamber is also disclosed where plasma is used in any of several methods to enhance, improve and expedite the disinfection process.

A device for indicating exposure to a pressure. The device may include a base layer, a plurality of microcapsules, and a coating, with the microcapsules being disposed between the base layer and the coating. The microcapsules contain a indicator material that can be released once the microcapsules burst. The microcapsules then have a compressive bursting strength that is chosen or designed to be less than a selected pressure (e.g., the pressure being that to which a particular article may be exposed during high pressure processing). Thus, when the device is subjected to a pressure greater than the compressive bursting strength, at least some microcapsules burst, the indicator material is released from the microcapsules, and the release of the indicator material can be detected by observation of the device. The device may be a label that is associated (such as by being affixed) to the article being subjected to pressure (or multiple labels being associated (such as by being affixed) to multiple articles. Alternatively, the device may be associated with an article or articles without being affixed thereto.

A sterile carbonated beverage filling system includes a beverage sterilizing section which sterilizes a raw material liquid to prepare a sterilized beverage, a beverage cooling section which cools the sterilized beverage, a carbonated beverage producing section which injects carbonic acid gas into the sterilized beverage to prepare a sterile carbonated beverage, and a carbonated beverage filling section which fills the sterile carbonated beverage into a bottle. The beverage sterilizing section, the beverage cooling section, the carbonated beverage producing section, and the carbonated beverage filling section are connected by a beverage supply pipeline. The carbonated beverage filling section and the beverage supply pipeline each include a rotary machine, and a boundary surface between a rotating body and a non-rotating body of the rotary machine is sealed with sterile water or sterile air.

Apparatus and method for pasteurizing food products and ready meals in hermetically sealed packages (22) by means of microwaves, comprising a microwave chamber (14); a lower conveyor belt (20) for the packages (22); an upper conveyor belt (18), extending substantially horizontally and vertically movable, and a microwave source (16) located below the lower conveyor belt (20), the microwave chamber (14) being under atmospheric ambient pressure. The apparatus comprises a cooling plate (10) in close contact with the upper conveyor belt (18) so that during microwave heating the top of the package (22) is cooled to below the condensation point of water vapor and overpressure in the package is avoided.

Disclosed is a heating device (100), including: a metal cylinder body (110) provided with a pick-and-place opening, a door body (120) configured to open and close the pick-and-place opening, an electromagnetic generating module (161) configured to generate an electromagnetic wave signal, and a radiating antenna (150). The radiating antenna (150) is configured to be electrically connected with the electromagnetic generating module (161) to generate electromagnetic waves of a corresponding frequency according to the electromagnetic wave signal. The heating device (100) further includes an antenna housing (130) made of an insulating material. The antenna housing (130) is configured to separate an inner space of the cylinder body (110) into a heating chamber (111) and an electrical appliance chamber (112), wherein an object to be processed and the radiating antenna (150) are respectively disposed in the heating chamber (111) and the electrical appliance chamber (112), and the radiating antenna (150) is configured to be fixedly connected with the antenna housing (130). The heating device (100) covers and fixes the radiating antenna (150) through the antenna housing (130), which not only can separate the object to be processed from the radiating antenna (150) to prevent the radiating antenna (150) from being dirty or damaged by accidental touch, but also can simplify the assembly process of the heating device (100) to facilitate the positioning and installation of the radiating antenna (150).