A food sterilization tube includes a layer including a fluoropolymer, wherein the fluoropolymer includes a copolymer of tetrafluoroethylene and perfluoropropyl vinyl ether (PFA), a fluorinated ethylene propylene copolymer (FEP), polytetrafluoroethylene (PTFE), or combination thereof, wherein the fluoropolymer has a dielectric constant of less than 3 as measured by ASTM D150.

A food sterilization tube includes a layer including a fluoropolymer, wherein the fluoropolymer includes a copolymer of tetrafluoroethylene and perfluoropropyl vinyl ether (PFA), a fluorinated ethylene propylene copolymer (FEP), polytetrafluoroethylene (PTFE), or combination thereof, wherein the fluoropolymer has a dielectric constant of less than 3 as measured by ASTM D150.

Provided herein are a microwave retort system and a process for heating food products using a microwave retort system, such as to pasteurization and/or sterilization temperatures. Food product formulated for treatment in microwave retort processes are also provided. In one aspect, the microwave retort system includes a microwave zone having one or more microwave temperature sections in which a liquid medium is maintained at a temperature below sterilization temperatures during the microwaving process. The processes and systems described herein heat the products to pasteurization or sterilization temperatures while preventing the products, including outer surfaces, reaching a temperature greater than 135 F. The microwave retort processes and systems advantageously provide products with the taste and organoleptic properties equivalent to or nearly equivalent to an otherwise identical freshly prepared product and significantly better than otherwise identical food products that have undergone a conventional immersion or saturated steam retort process.

Provided herein are a microwave retort system and a process for heating food products using a microwave retort system, such as to pasteurization and/or sterilization temperatures. Food product formulated for treatment in microwave retort processes are also provided. In one aspect, the microwave retort system includes a microwave zone having one or more microwave temperature sections in which a liquid medium is maintained at a temperature below sterilization temperatures during the microwaving process. The processes and systems described herein heat the products to pasteurization or sterilization temperatures while preventing the products, including outer surfaces, reaching a temperature greater than 135 F. The microwave retort processes and systems advantageously provide products with the taste and organoleptic properties equivalent to or nearly equivalent to an otherwise identical freshly prepared product and significantly better than otherwise identical food products that have undergone a conventional immersion or saturated steam retort process.

A refrigerator includes a cooling/heating chamber capable of cooling and heating foods. The cooling/heating chamber is divided into a heating zone that is a space where foods to be heated are placed, and a non-heating zone that is a space continuous with the heating zone where foods not to be heated are placed. The refrigerator further includes an oscillation electrode and a counter electrode that are arranged so as to face each other with the heating zone in between, and an oscillating unit that applies an AC voltage to between the oscillation electrode and the counter electrode.

Systems and processes for use in heating articles include passing a carrier loaded with an article through a vessel inlet and into a first vessel portion and moving the loaded carrier in a first direction through the first vessel portion away from the inlet. During at least a portion of the movement through the first vessel portion, the article is contacted with a first fluid medium. The loaded carrier is moved carrier in a second direction opposite the first direction through a second vessel portion toward a vessel outlet. During at least a portion of the movement through the second vessel portion, the articles is contacted with a second fluid medium. In certain implementations, each of the first direction and the second direction are vertical.

Systems and processes for use in heating articles include passing a carrier loaded with an article through a vessel inlet and into a first vessel portion and moving the loaded carrier in a first direction through the first vessel portion away from the inlet. During at least a portion of the movement through the first vessel portion, the article is contacted with a first fluid medium. The loaded carrier is moved carrier in a second direction opposite the first direction through a second vessel portion toward a vessel outlet. During at least a portion of the movement through the second vessel portion, the articles is contacted with a second fluid medium. In certain implementations, each of the first direction and the second direction are vertical.

The present invention provides a highly reliable and safe heating device that can uniformly heat an object to be heated and provides a refrigerator having a storage space in which frozen products as storage products can be easily thawed to a high-quality state. A heating device of the present invention includes an oscillation electrode disposed on one hand of the heating space and having an electrode surface on which an electric field concentration region is formed, a counter electrode disposed on the other hand of the heating space and having an electrode surface that faces the electrode surface of the oscillation electrode, and a high-frequency electric field forming unit for forming a high-frequency electric field applied to between the oscillation electrode and the counter electrode.

A thawing method for a thawing device includes: generating a radio frequency signal; acquiring the radio frequency signal; an upper electrode plate and a lower electrode plate of the thawing chamber generating, according to the radio frequency signal, radio frequency waves having a corresponding frequency in a thawing chamber and thawing an object to be processed, obtaining voltages and currents of the incident wave signal and reflected wave signal, and determining a thawing progress of the object to be processed.

A thawing method for a thawing device includes: generating a radio frequency signal; acquiring the radio frequency signal; an upper electrode plate and a lower electrode plate of the thawing chamber generating, according to the radio frequency signal, radio frequency waves having a corresponding frequency in a thawing chamber and thawing an object to be processed, obtaining voltages and currents of the incident wave signal and reflected wave signal, and determining a thawing progress of the object to be processed.