A water purifier for home use, irrigation systems used for crop cultivation or the pharmaceutical industry includes a water inlet for a water to be purified and a water outlet for a purified water. A water treatment chamber is fluidly connected to the water inlet and the water outlet. The water treatment chamber is confined by a chamber wall. The water purifier includes a high-voltage plasma unit for generating a cold plasma within the water treatment chamber. The plasma unit has a first electrode and a second electrode. The first electrode is arranged inside the water treatment chamber such that, during use of the water purifier, it is contacted by the water. The second electrode is disposed spaced apart from the first electrode and electrically insulated therefrom by a dielectric. The water purifier further relates to a water purification system.

A fine particle manufacturing apparatus and a fine particle manufacturing method are provided. The apparatus includes a raw material supply part supplying a raw material; a plasma torch in which the thermal plasma flame is generated and the raw material supplied by the raw material supply part is vaporized by using the thermal plasma flame to form a mixture in a gas phase state; and a plasma generation part generating the thermal plasma flame inside the plasma torch. The plasma generation part includes a first coil encircling the plasma torch; a second coil encircling the plasma torch and disposed below the first coil; a first power supply part supplying a high-frequency electric current to the first coil; and a second power supply part supplying an amplitude-modulated high-frequency electric current to the second coil. The first coil and the second coil are arranged in the longitudinal direction of the plasma torch.

Provided is a spinning disc with plasma discharges for the treatment of liquid. In one configuration, plasma is introduced to the surface of a liquid by a point-plane discharge, dielectric barrier discharge or as a plasma jet. This liquid exists as a thin film on the surface of the spinning disc. The thin liquid layer, as well as the enhanced mixing provided by the spinning disc, allow the plasma generated radicals to more easily interact with the contaminant.

The disclosure refers to a method, reaction chamber and system for treatment of liquids in continuous flow including the steps of receiving a liquid for treatment in a reaction chamber; converting q flow of liquid for treatment in a biphasic liquid-gas flow; directing the biphasic flow to a central section of the reaction chamber, where an electric field is applied; ionizing the gaseous fraction of the biphasic flow that passes through said central section sustaining an ionization regime generating non-thermal plasma throughout the central section of the reaction chamber leading the biphasic flow under the ionization regime to a discharge section of the reaction chamber, where the electric field is applied, generating the deionization of the gaseous fraction and causing the biphasic flow to reduce its velocity, which results in the condensation of biphasic flow; and removing a flow of treated liquid from said discharge section.

A dielectric assembly for a plasma reactor includes a first dielectric layer having a first surface, and a second surface opposite the first surface, a second dielectric layer, thinner than the first dielectric layer, have a third surface, and a fourth surface opposite the third surface, and an electrode disposed between the second surface and the third surface. The electrode may be ring shaped and/or disposed on a spherical surface. A non-reactive coating may be disposed on a surface of the dielectric assembly exposed to a plasma chamber of the plasma reactor. The coating may be disposed in the form of rings with a gap between each ring.

Solutions having a solvent and a cold atmospheric plasma dissolved in the solvent are described. Methods and systems of forming cold atmospheric plasma (CAP)-containing solutions are also described. A system for producing (CAP)-containing solutions includes a gas source; a plasma generating device having a hollow body fluidically coupled with the gas source, a closed proximal end and an open distal end, the hollow body receiving gas from the gas source, and at least one electrode in or about the hollow body and ionizing the gas to discharge a cold atmospheric plasma (CAP) from the open distal end; and a container for housing a fluid, the open distal end of the plasma generating device in fluid communication with an inner portion of the container. CAP-containing solutions can be used in treatment of cancer cells, infected tissue sterilization, microorganism inactivation, promotion of wound healing, skin regeneration, and blood coagulation, and teeth bleaching/whitening.

An energy-efficient disinfection or sterilisation of contaminated liquid, such as water contaminated with viruses or microbes includes an asymmetric configuration of a cavitation nozzle made from dielectric material that enables the formation of a single, stable cavitation bubble of a large volume. A low-pressure gaseous plasma is continuously formed inside the cavitation bubble by electrodes to prevent contact of the metallic electrode with liquid water and Ohmic heating of the contaminated water. The electrodes are connected to a high voltage power supply. The power supply enables formation of a continuous stable gaseous discharge inside the cavitation bubble and radicals and radiation useful for destruction of viruses to the levels below the current US EPA standard in few minutes, while the temperature of liquid water remains practically unchanged. Use is not only for hospitals and pharmaceutical companies but the food industry and agriculture as well.

A plasma generator generates atmospheric pressure, low temperature plasma (cold plasma), and includes a first electrode, a second electrode arranged so as to define a predetermined gap between a planar bottom surface of the first electrode and a planar top surface of the second electrode; at least one supplemental electrode, a first dielectric layer, a second dielectric layer, at least one supplemental top dielectric layer having a relative permittivity between 2 and 500, and a thickness of 3 mm or less, at least one supplemental bottom dielectric layer having a relative permittivity between 2 and 500, and a thickness of 3 mm or less, and a power supply configured to supply electrical power to the first, second, and supplemental electrodes at a predetermined voltage and frequency, such that, based on the predetermined gaps between the first, second, and supplemental electrodes, atmospheric pressure, low temperature plasma is generated.

A plasma generator generates atmospheric pressure, low temperature plasma (cold plasma), and includes a first electrode; a second electrode opposing the first electrode so as to define a predetermined gap therebetween; at least one supplemental electrode opposing a planar top surface of the second electrode and a planar bottom surface of the first electrode; a first dielectric layer; at least one supplemental dielectric layer that is disposed on a additional planar bottom surface of the at least one supplemental electrode having a relative permittivity between 2 and 500, and a thickness of 3 mm or less; and a power supply configured to supply electrical power to the first and second electrodes at a predetermined voltage and frequency, such that, based on the predetermined gap between the first and second electrodes, atmospheric pressure, low-temperature plasma is generated.

An apparatus is provided for treating a liquid with a plasma. The apparatus includes one or two dielectric barriers, and the dielectric barrier(s) and high voltage electrode define a discharge zone therebetween. A high voltage electrode may be electrically insulated from the discharge zone by the inner dielectric barrier. In this apparatus, the outer dielectric barrier is gas and the discharge zone is configured to accept a gas flow therethrough.