A micro-vibration wave generating device includes: a power indicator circuit, a first transformer micro-vibration wave generating circuit, and a receptor. An input end of the power indicator circuit is connected to the power source; an input end of the first transformer micro-vibration wave generating circuit is connected with an output end of the power indicator circuit; the receptor is connected with an output end of the first transformer micro-vibration wave generating circuit. Micro-vibration waves generated by the transformer micro-vibration wave generating circuit can resonate with the water molecules in the food, and thereby the water molecules form soft and non-spiky crystals of water molecules when they are frozen, which greatly reduces the damage to the food cells. Accordingly, the quality of the food is intact without mixing odors. The present invention can also be used in cooking deep fried food with almost no oil smoke produced.

A micro-vibration wave generating device includes: a power indicator circuit, a first transformer micro-vibration wave generating circuit, and a receptor. An input end of the power indicator circuit is connected to the power source; an input end of the first transformer micro-vibration wave generating circuit is connected with an output end of the power indicator circuit; the receptor is connected with an output end of the first transformer micro-vibration wave generating circuit. Micro-vibration waves generated by the transformer micro-vibration wave generating circuit can resonate with the water molecules in the food, and thereby the water molecules form soft and non-spiky crystals of water molecules when they are frozen, which greatly reduces the damage to the food cells. Accordingly, the quality of the food is intact without mixing odors. The present invention can also be used in cooking deep fried food with almost no oil smoke produced.

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.

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.

Provided is a production method for a soluble material, including: causing a solid raw material containing at least one component of a hydrolyzable material selected from the group consisting of a protein, a carbohydrate and a lipid, and a fibrous material, and water in an amount corresponding to 0.04 to 2.4 parts by weight with respect to 1 part by weight of a dry amount of the raw material to coexist; applying a shearing force in a state where heating and pressurization are performed at 200 to 374 C. and in a pressure range equal to or higher than a vapor-liquid coexistence curve of water to hydrolyze at least a part of the hydrolyzable material and/or to amorphize at least a part of the fibrous material; and halting the pressurization to cause adiabatic expansion.

Disclosed are methods and devices for reducing the number of pathogens in a liquid. The methods or devices uses one or more of pressure, pressure drop, increased temperature, rate of temperature increase, and inert gas to kill pathogens. In one embodiment, inert gas is dissolved into a liquid at a pressure greater than ambient pressure. The pressure is later rapidly reduced, which causes inert gas to be released from the liquid. This reduces the number of pathogens in the liquid. Other method steps or processes that do not utilize inert gas are also disclosed.

A freshness container, in particular in the form of a vacuum drawer device, for food, includes at least one container base body and a container lid to be placed on the at least one container base body, and the container lid includes a control and/or regulating device and a sensor system. The sensor system is designed to determine a CO2 content, a temperature, and/or a proportion of, in particular volatile, organic compounds in an atmosphere arranged within the at least one container base body, and the control and/or regulating device is configured to adjust the CO2 content, the temperature, and/or the proportion of organic compounds in the atmosphere.

A method and apparatus for evaporative cooling of materials within a vacuum chamber by maintaining a controlled partial pressure environment. The method involves sealing material inside a chamber, reducing the internal pressure using a vacuum pump, and simultaneously introducing external gassuch as ambient air, nitrogen, or inert gasesinto the chamber. A constant partial pressure is maintained by balancing the gas input and vacuum pump operation, allowing for efficient evacuation of vaporized liquid without recondensation. The system can operate with either constant or variable flow rates for both gas input and vacuum pumping, depending on desired cooling conditions, chamber size, and material characteristics. The apparatus includes a sealable vacuum chamber, at least one external gas inlet, and a vacuum pump configured to sustain the target partial pressure.

Methods and apparatus for sterilizing plant material include disposing plant material in a sub-atmospheric pressure environment, dispersing a non-toxic, non-polymerizable gas into the sub-atmospheric pressure environment, applying an electric field to change the gas into cold plasma, and maintaining exposure of the plant material to the cold plasma until substantially sterilized plant material is obtained, wherein an amount of at least one active constituent in the plant material is substantially unchanged by the sterilizing. The plant material may be cannabis.