There is provided an in-liquid plasma device including a tubular flow channel in which a liquid flow, and a cavitation generator and a voltage application unit which are disposed in the tubular flow channel. The cavitation generator generates cavitation in the liquid inside the tubular flow channel. The voltage application unit is located in the tubular flow channel so as to generate plasma by applying a voltage to the liquid in which the cavitation is generated. The cavitation generator has a throttle portion whose inner diameter is smaller than other sites in the tubular flow channel. The throttle portion has an upstream side inclined surface located on an upstream side of a narrowest site of the throttle portion, and a downstream side inclined surface located on a downstream side of the narrowest site of the throttle portion.

An ionization chamber is disclosed that can free ions in water creating polarized atoms of hydrogen and oxygen derived from water in the process. The water can be comprised of non-potable waste water. Once the hydrogen and oxygen ions are released, and polarized in the process, the electrons can be aligned such that the end product is the release of hydrogen and the bonding of the oxygen with the free electrons of the other element(s) such as Titanium or Tungsten for example, without high heat or pressure as is normally required. The chamber is comprised of a series of metallic rods, a series of solid nickel mesh plates, a vacuum pump, a dual pulsed D.C. Power supply (from 200-800 VDC pulsed and a low power, 24 VDC pulsed at 400-600 Hz.), a water bath chamber, a ceramic or Teflon encapsulated feeder assembly, and an R.F. Pulse generator.

The invention relates to a method (S) for generating a plurality of cold-plasma jets at atmospheric pressure in order to treat a target (2), wherein said method includes the following steps: producing (S1) a primary cold-plasma jet (3) at atmospheric pressure using a plasma source (10); placing (S2) a substrate (20, 21, 30, 32, 34) near the target (2) to be treated, said substrate (20, 21, 30, 32, 34) including at least two through-holes; and passing (S3) the plasma through the through-holes (22) of the substrate (20) such as to generate at least two secondary cold-plasma jets (4) at atmospheric pressure.

Exemplary magnetic induction plasma systems for generating plasma products are provided. The magnetic induction plasma system may include a first plasma source including a plurality of first sections and a plurality of second sections arranged in an alternating manner and fluidly coupled with each other such that at least a portion of plasma products generated inside the first plasma source may circulate through at least one of the plurality of first sections and at least one of the plurality of second sections inside the first plasma source. Each of the plurality of second sections may include a dielectric material. The system may further include a plurality of first magnetic elements each of which may define a closed loop. Each of the plurality of second sections may define a plurality of recesses for receiving one of the plurality of first magnetic elements therein.

In order to ensure quality even when a sheet-like base material is thin while improving efficiency of production, a plasma treatment apparatus disclosed herein includes a plasma treatment chamber X for treating a sheet-like base material Z with plasma, a high-frequency antenna 3 for generating plasma in the plasma treatment chamber X, and a feeding mechanism 10 for feeding the sheet-like base material Z into the plasma treatment chamber X in a vertical direction.

Disclosed is a device for generating compressed fluids, including: a process chamber for containing and further treating a first reaction material; a process chamber for containing and further treating a second reaction material; a process chamber for containing and further treating a fluid intended for compression; a unit for determining the nebulization and the consequent inlet of the first reaction material into process chamber; a unit intended for determining the emission of radio waves with variable frequencies in the direction of the process chamber, wherein the radio waves emitted by the unit interact with the first and second reaction material contained and treated in process chamber, for producing a high-energy plasma that determines the warming and the consequent compression of the fluid contained in process chamber.

A plasma power generator wherein a plasma is generated by subjecting oxygen (O2) to a strong electromagnetic field. The oxygen plasma enters a chamber and is combined with free electrons from an electron-donation element thereby producing heat.

A system includes an afterburner including an afterburner duct that defines an afterburner channel. The afterburner is configured to receive input gas from a jet engine turbine into the channel and to output an exhaust gas resulting from combustion of fuel. The system includes a plurality of resonators electromagnetically coupled to at least one radio-frequency power source. Each resonator has a resonant wavelength, first and second conductors, and a dielectric between those conductors. Each resonator is configured such that, when that resonator is excited by the power source with a signal having a wavelength proximate to an odd-integer multiple of one-quarter of the resonant wavelength of that resonator, that resonator provides within the afterburner at least one of electromagnetic waves or a plasma corona proximate to that resonator. A first resonator further includes a fuel conduit having a fuel outlet configured to output fuel for mixing with the input gas.

A system includes a radio-frequency power source, a resonator, and an afterburner including a duct that defines a channel. The afterburner receives input gas from a turbine of a jet engine into the channel and outputs an exhaust gas resulting from combustion of fuel within the channel. The resonator, having a resonant wavelength, is electromagnetically coupled to the power source. The resonator includes first and second conductors, a dielectric between the conductors, an electrode coupled to the first conductor and disposed within the afterburner, and a fuel conduit having a fuel outlet that is configured to output fuel for mixing with the input gas from the turbine of the jet engine. The resonator, when excited by the power source with a signal having a wavelength proximate to an odd-integer multiple of one-quarter of the resonant wavelength, provides electromagnetic waves and/or a plasma corona proximate to a concentrator of the electrode.

A system includes an afterburner including an afterburner duct that defines an afterburner channel. The afterburner receives input gas from a jet engine into the channel and outputs an exhaust gas resulting from combustion of fuel. The system includes multiple resonators electromagnetically coupled to at least one radio-frequency power source. Each resonator has a resonant wavelength, first and second conductors, and a dielectric between those conductors. Each resonator is configured such that, when that resonator is excited by the power source with a signal having a wavelength proximate to an odd-integer multiple of one-quarter of that resonator's resonant wavelength, that resonator provides within the afterburner electromagnetic waves and/or a plasma corona proximate to that resonator. A resonator also includes a fuel conduit having a fuel outlet configured to output fuel for mixing with the input gas, and at least a portion of that resonator is arranged proximate to the dielectric.