A sterilization apparatus characterized in that the sterilization apparatus comprises a reactive oxygen species irradiation unit for irradiating a reactive oxygen species-containing gas which is a reaction product of plasma generated using an alternating current and a water-containing gas containing steam, the sterilization apparatus further containing an inlet unit for steam flow for supplying the water-containing gas heated to a temperature of from 50 to 300 C., wherein the reactive oxygen species-containing gas contains water in an amount equal to or greater than the amount of saturated steam. The sterilization apparatus of the present invention shows excellent sterilization activity, so that it can be suitably used in sterilization of containers for foodstuff, bottle caps sealing the openings of the containers, medical devices, foodstuff such as vegetables and meat, and the like.

A sterilization apparatus characterized in that the sterilization apparatus comprises a reactive oxygen species irradiation unit for irradiating a reactive oxygen species-containing gas which is a reaction product of plasma generated using an alternating current and a water-containing gas containing steam, the sterilization apparatus further containing an inlet unit for steam flow for supplying the water-containing gas heated to a temperature of from 50 to 300 C., wherein the reactive oxygen species-containing gas contains water in an amount equal to or greater than the amount of saturated steam. The sterilization apparatus of the present invention shows excellent sterilization activity, so that it can be suitably used in sterilization of containers for foodstuff, bottle caps sealing the openings of the containers, medical devices, foodstuff such as vegetables and meat, and the like.

A system for supercooling a product is provided, the system comprising: a chamber containing a supercooling medium; and disruptors that emit sound waves, ultrasound waves, and/or electromagnetic waves in the chamber; wherein during a cooling cycle the chamber reaches a cooling temperature below 0 C. and during a warming cycle the chamber reaches a warming temperature greater than the cooling temperature. The supercooling system may be used to supercool perishable products below freezing to extend shelf life and freshness of the products. Other embodiments of the supercooling system, and methods for its use, are described herein.

A system for supercooling a product is provided, the system comprising: a chamber containing a supercooling medium; and disruptors that emit sound waves, ultrasound waves, and/or electromagnetic waves in the chamber; wherein during a cooling cycle the chamber reaches a cooling temperature below 0 C. and during a warming cycle the chamber reaches a warming temperature greater than the cooling temperature. The supercooling system may be used to supercool perishable products below freezing to extend shelf life and freshness of the products. Other embodiments of the supercooling system, and methods for its use, are described herein.

A system for irradiation of grain foods using one or more ultraviolet emitting sources is provided. The system includes an irradiation region in which the grain foods are irradiated by ultraviolet light. The system can include means for moving the grain foods through irradiation region, means for detecting the flow rate of the grain foods moving through irradiation region, and a control system for adjusting power provided to the ultraviolet emitting sources based on the flow rate of the grain foods.

This invention relates to a method, process and apparatus for disinfecting and sterilizing all types of surfaces contaminated with microorganisms and toxic substances to render both inactive. Furthermore, this invention relates to both a method and apparatus for disinfecting and/or sterilizing breathable air and then using this air to protect a confined space from external contamination. The apparatus consists of a new ultra-violet (NUV) source that is more effective than mercury based 254 nm light for destroying DNA of virus, bacteria, spores and cists. It is most effective in breaking chemical bonds in toxic gases and Biotoxins that are useful to terrorists. It is combined with other apparatus that remove particulates and byproducts sometimes produced by the NUV source and maintains positive pressure of the confined space so as to prevent the influx of air from outside the protected zone.

This invention relates to a method, process and apparatus for disinfecting and sterilizing all types of surfaces contaminated with microorganisms and toxic substances to render both inactive. Furthermore, this invention relates to both a method and apparatus for disinfecting and/or sterilizing breathable air and then using this air to protect a confined space from external contamination. The apparatus consists of a new ultra-violet (NUV) source that is more effective than mercury based 254 nm light for destroying DNA of virus, bacteria, spores and cists. It is most effective in breaking chemical bonds in toxic gases and Biotoxins that are useful to terrorists. It is combined with other apparatus that remove particulates and byproducts sometimes produced by the NUV source and maintains positive pressure of the confined space so as to prevent the influx of air from outside the protected zone.

A food irradiation system including a plurality of compact linac systems is described herein. Each compact linac system, of the plurality of compact linac systems, includes: a high energy particle beam source providing a particle beam at up to 10 MeV; an emission target assembly configured to generate bremsstrahlung x-rays when impacted by particles of the particle beam; and a drift tube through which the particle beam passes on a path from the high energy particle beam source to the emission target assembly. The emission target assembly is positioned at a distal end of the drift tube for direct impingement of the particle beam to generate the bremsstrahlung x-rays in a directed radiation beam. Ones of the plurality of compact linac systems are individually positioned such that, as a group, the plurality of compact linac systems provide directed radiation beam coverage at prescribed radiation dose levels for an overall cumulative volume.

A device(s) and method for pasteurizing and/or sterilizing particulate material using an electron beam. The device (10) includes at least one electron source (20) for generating an electron beam, a treatment zone (19) in which the material, particularly a freely falling material, can be pasteurized and/or sterilized by the electron beam, and a material channel (21) arranged in the region of the treatment zone (19) in which the material can be pasteurized and/or sterilized by the electron beam. A planar protective element (23), which is at least partially permeable by the electron beam, is arranged between the electron source (20) and the material channel (21). The device (10) includes a holding frame (120) which holds the protective element (23) and which has a cavity (121) through which a cooling fluid can flow.

A device(s) and method for pasteurizing and/or sterilizing particulate material using an electron beam. The device (10) includes at least one electron source (20) for generating an electron beam, a treatment zone (19) in which the material, particularly a freely falling material, can be pasteurized and/or sterilized by the electron beam, and a material channel (21) arranged in the region of the treatment zone (19) in which the material can be pasteurized and/or sterilized by the electron beam. A planar protective element (23), which is at least partially permeable by the electron beam, is arranged between the electron source (20) and the material channel (21). The device (10) includes a holding frame (120) which holds the protective element (23) and which has a cavity (121) through which a cooling fluid can flow.