An aspect of the present invention is a frozen strawberry having: a breaking load of not less than 10000 g and not more than 30000 g; and a breaking strain factor of not less than 15%.

An aspect of the present invention is a frozen strawberry having: a breaking load of not less than 10000 g and not more than 30000 g; and a breaking strain factor of not less than 15%.

A food processing system is provided with: a heating unit equipped with a heating mechanism for indirectly heating food; a cooling unit equipped with an air blowing cooler for cooling the food heated by the heating unit; and a conveyor for transferring the food through the heating unit and the cooling unit. The integrated food processing system allows a large amount of sterilized food having a good texture, good taste and long shelf life to be provided.

Dehydration and drying are some of the oldest methods of preserving food and other biological materials such as proteins and both live and dead live microorganisms or their metabolites. The invention disclosed herein seeks a method of further improving the process of preserving biological material by combining the freezing or freeze-drying process with a partial infrared dehydration step. By using infrared radiation energy to perform simultaneous blanching and dehydration, the drying speed is greatly increased and better cellular and molecular integrity is maintained. The invention herein is also particularly useful in connection with cannabis and hemp.

An air composition adjusting device includes: a carbon dioxide separator that separates carbon dioxide from air-to-be-treated to be supplied to a target space; a gas supply path including a high concentration gas supply path through which the carbon dioxide separator communicates with the target space; and a controller that performs a carbon dioxide concentration raising operation of supplying a high carbon dioxide concentration gas, which has a higher carbon dioxide concentration than air-to-be-treated before being treated, to the target space through the high concentration gas supply path.

An air composition adjusting device includes: a carbon dioxide separator that separates carbon dioxide from air-to-be-treated to be supplied to a target space; a gas supply path including a high concentration gas supply path through which the carbon dioxide separator communicates with the target space; and a controller that performs a carbon dioxide concentration raising operation of supplying a high carbon dioxide concentration gas, which has a higher carbon dioxide concentration than air-to-be-treated before being treated, to the target space through the high concentration gas supply path.

An improved system and method for treating, precooling, and handling perishable products uses a mobile container enhanced with increased capacity refrigeration and air flow to recirculate functional substances including sanitizers, and ripening management and conditioning agents across the surface of palletized perishable products during the precooling step. As the perishable is precooled, the system integrates humidity control to reduce dehydration. Sanitizing substances are dispensed into the recirculating air to significantly reduce micro-organisms on the surface coming from the field and avoid recontamination from the cooling warehouse. Conditioning and ripening management substances are recirculated to enable managing the ripeness of a perishable to a target. The mobile container is modified from a standard intermodal container or over-the-road semi-trailer. The enhanced forced air and/or refrigeration equipment is contained within the container and/or mounted on the top and/or side exterior of the container and can accomplish rapid cooling. The system and method has thus combined rapid cooling, reduced dehydration, reduced surface micro-organism contamination, and conditioning or ripeness control for enhanced quality and shelf life. The mobile container is able to operate independently outside of a refrigerated warehouse used for storage and distribution of the cooled perishable product. The materials of construction used and operational independence enable safely using highly active sanitizing, ripening management, and other functional substances. The mobile container can be located near harvest or facilities with no colling assets. A combined system using conveyors and operational controls provides automated handling of the perishables from receiving, through precooling and treatment, preferably to a MAP process, and then distribution.

An improved system and method for treating, precooling, and handling perishable products uses a mobile container enhanced with increased capacity refrigeration and air flow to recirculate functional substances including sanitizers, and ripening management and conditioning agents across the surface of palletized perishable products during the precooling step. As the perishable is precooled, the system integrates humidity control to reduce dehydration. Sanitizing substances are dispensed into the recirculating air to significantly reduce micro-organisms on the surface coming from the field and avoid recontamination from the cooling warehouse. Conditioning and ripening management substances are recirculated to enable managing the ripeness of a perishable to a target. The mobile container is modified from a standard intermodal container or over-the-road semi-trailer. The enhanced forced air and/or refrigeration equipment is contained within the container and/or mounted on the top and/or side exterior of the container and can accomplish rapid cooling. The system and method has thus combined rapid cooling, reduced dehydration, reduced surface micro-organism contamination, and conditioning or ripeness control for enhanced quality and shelf life. The mobile container is able to operate independently outside of a refrigerated warehouse used for storage and distribution of the cooled perishable product. The materials of construction used and operational independence enable safely using highly active sanitizing, ripening management, and other functional substances. The mobile container can be located near harvest or facilities with no colling assets. A combined system using conveyors and operational controls provides automated handling of the perishables from receiving, through precooling and treatment, preferably to a MAP process, and then distribution.

Provided is a wasabi rhizome with suppressed quality deterioration, a method of preserving the same, and a method of producing the same. Disclosed herein are: a wasabi rhizome having a phenylalanine ammonia-lyase activity of less than 0.04 U per mg of protein, after preserving the wasabi rhizome at 0° C. for 5 days following trimming of the surface thereof; and a method of preserving the wasabi rhizome at a temperature of −5° C. or more and 10° C. or less. Also disclosed herein is a method of producing a wasabi rhizome with suppressed quality deterioration, including: (1-1) immersing a wasabi rhizome in water having a temperature of more than 40° C. and less than 60° C.; and/or (1-2) immersing the wasabi rhizome in an ethanol solution.

Provided is a wasabi rhizome with suppressed quality deterioration, a method of preserving the same, and a method of producing the same. Disclosed herein are: a wasabi rhizome having a phenylalanine ammonia-lyase activity of less than 0.04 U per mg of protein, after preserving the wasabi rhizome at 0° C. for 5 days following trimming of the surface thereof; and a method of preserving the wasabi rhizome at a temperature of −5° C. or more and 10° C. or less. Also disclosed herein is a method of producing a wasabi rhizome with suppressed quality deterioration, including: (1-1) immersing a wasabi rhizome in water having a temperature of more than 40° C. and less than 60° C.; and/or (1-2) immersing the wasabi rhizome in an ethanol solution.