The present invention relates to a continuous on-board drying method for Antarctic krill and a continuous on-board processing method of shelled Antarctic krill. The drying method includes the following steps: 1) subjecting fishing materials to cleaning, sorting, and dewatering with a vibrating screen; 2) rapidly heating the krill to the temperature of up to 70 C. using infra-red rays; 3) hot-air drying; 4) impurity removal by vacuum; 5) cooling to obtain dried krill. The processing method includes the following steps: a) subjecting fishing materials to cleaning, sorting, and dewatering with a vibrating screen; b) rapidly heating the krill to the temperature of up to 70 C. using infra-red rays; c) hot-air drying; d) subjecting the dried krill to shelling treatment to separate shell from meat, to obtain shelled krill; e) impurity removal by vacuum to obtain shelled krill product. The methods in the present invention are highly efficient, energy saving, green and environmental protection, and the krill products have high quality and safety.

A process for manufacturing dry sausage. The process includes preparing a dry sausage meat mixture, stuffing the mixture into a casing or mould, fermenting the mixture, heat treating the mixture, cooling the mixture to a temperature sufficiently low to permit slicing, slicing the sausage, placing the sausage onto a conveyor, and passing the conveyor and sausage through a chamber. The process also includes introducing a supply of conditioned air into the chamber, the air having a relative humidity below about 60% and a temperature in the range of at least about 40 F. to 130 F., and introducing a supply of microwaves into the chamber. The air supply and microwaves are selected to reduce the moisture content of the meat to a predetermined moisture to protein ratio.

A process for manufacturing dry sausage. The process includes preparing a dry sausage meat mixture, stuffing the mixture into a casing or mould, fermenting the mixture, heat treating the mixture, cooling the mixture to a temperature sufficiently low to permit slicing, slicing the sausage, placing the sausage onto a conveyor, and passing the conveyor and sausage through a chamber. The process also includes introducing a supply of conditioned air into the chamber, the air having a relative humidity below about 60% and a temperature in the range of at least about 40 F. to 130 F., and introducing a supply of microwaves into the chamber. The air supply and microwaves are selected to reduce the moisture content of the meat to a predetermined moisture to protein ratio.

A process for manufacturing dry sausage. The process includes preparing a dry sausage meat mixture, stuffing the mixture into a casing or mold, fermenting the mixture, heat treating the mixture, cooling the mixture to a temperature sufficiently low to permit slicing, slicing the sausage, placing the sausage onto a conveyor, and passing the conveyor and sausage through a chamber. The process also includes introducing a supply of conditioned air into the chamber, the air having a relative humidity below about 60% and a temperature in the range of at least about 40 F. to 130 F., and introducing a supply of microwaves into the chamber. The air supply and microwaves are selected to reduce the moisture content of the meat to a predetermined moisture to protein ratio.

A process for manufacturing dry sausage. The process includes preparing a dry sausage meat mixture, stuffing the mixture into a casing or mold, fermenting the mixture, heat treating the mixture, cooling the mixture to a temperature sufficiently low to permit slicing, slicing the sausage, placing the sausage onto a conveyor, and passing the conveyor and sausage through a chamber. The process also includes introducing a supply of conditioned air into the chamber, the air having a relative humidity below about 60% and a temperature in the range of at least about 40 F. to 130 F., and introducing a supply of microwaves into the chamber. The air supply and microwaves are selected to reduce the moisture content of the meat to a predetermined moisture to protein ratio.

The present disclosure provides systems and methods associated with non-thermal electroporation. One or more electromagnetic radiation sources may be used to generate an interference pattern having at least one antinode. The electric field associated with the antinode may be configured to cause irreversible electroporation. Thus, the antinode may be suitable for at least partial sterilization by rendering cells as non-viable through electroporation. An antinode may be formed by constructive interference of two or more lobes of two or more radiation sources. An antinode may be spatially varied with respect to an object, volume, and/or surface. A controller may spatially vary an antinode according to an electroporation pattern, such as a stochastic or rasterizing pattern, to achieve a desired sterilization level and/or maintain a temperature characteristic (e.g., absolute temperature, relative temperature, and/or rate of change) with a threshold range.

The present disclosure provides systems and methods associated with non-thermal electroporation. One or more electromagnetic radiation sources may be used to generate an interference pattern having at least one antinode. The electric field associated with the antinode may be configured to cause irreversible electroporation. Thus, the antinode may be suitable for at least partial sterilization by rendering cells as non-viable through electroporation. An antinode may be formed by constructive interference of two or more lobes of two or more radiation sources. An antinode may be spatially varied with respect to an object, volume, and/or surface. A controller may spatially vary an antinode according to an electroporation pattern, such as a stochastic or rasterizing pattern, to achieve a desired sterilization level and/or maintain a temperature characteristic (e.g., absolute temperature, relative temperature, and/or rate of change) with a threshold range.

The present disclosure provides systems and methods associated with non-thermal electroporation. One or more electromagnetic radiation sources may be used to generate an interference pattern having at least one antinode. The electric field associated with the antinode may be configured to cause irreversible electroporation. Thus, the antinode may be suitable for at least partial sterilization by rendering cells as non-viable through electroporation. An antinode may be formed by constructive interference of two or more lobes of two or more radiation sources. An antinode may be spatially varied with respect to an object, volume, and/or surface. A controller may spatially vary an antinode according to an electroporation pattern, such as a stochastic or rasterizing pattern, to achieve a desired sterilization level and/or maintain a temperature characteristic (e.g., absolute temperature, relative temperature, and/or rate of change) with a threshold range.

The present disclosure provides systems and methods associated with non-thermal electroporation. One or more electromagnetic radiation sources may be used to generate an interference pattern having at least one antinode. The electric field associated with the antinode may be configured to cause irreversible electroporation. Thus, the antinode may be suitable for at least partial sterilization by rendering cells as non-viable through electroporation. An antinode may be formed by constructive interference of two or more lobes of two or more radiation sources. An antinode may be spatially varied with respect to an object, volume, and/or surface. A controller may spatially vary an antinode according to an electroporation pattern, such as a stochastic or rasterizing pattern, to achieve a desired sterilization level and/or maintain a temperature characteristic (e.g., absolute temperature, relative temperature, and/or rate of change) with a threshold range.

An apparatus for extracting a vaporizable substance, from a material containing such substance, comprises an irradiation chamber for irradiating the material with electromagnetic radiation to vaporize the substance. The substance may comprise water and the material is dehydrated. The electromagnetic radiation comprises microwaves. The irradiation is conducted in the near-field range of the electromagnetic radiation. In one aspect, the electromagnetic radiation within the waveguide evanescently couples with the material.