The object of the present disclosure is to efficiently generate plasma. In the plasma device of the present disclosure, a dielectric barrier discharger and an arc discharger are included, but the arc discharger is provided downstream from the dielectric barrier discharger in a discharge space where a gas for generating plasma is supplied. Dielectric barrier discharge occurs at the dielectric barrier discharger, and arch discharge occurs at the arc discharger. As a result of the gas for generating plasma being activated in the dielectric barrier discharge, the aforementioned gas can be adequately converted to plasma in the arc discharger.

Plasma applications are disclosed that operate with argon or helium at atmospheric pressure, and at low temperatures, and with high concentrations of reactive species in the effluent stream. Laminar gas flow is developed prior to forming the plasma and at least one of the electrodes can be heated which enables operation at conditions where the argon or helium plasma would otherwise be unstable and either extinguish, or transition into an arc. The techniques can be employed to clean and activate a metal substrate, including removal of oxidation, thereby enhancing the bonding of at least one other material to the metal.

A system for reducing plasma instability is disclosed. The system includes: an outer electrode having a first end and a second end spaced from the first end; and an inner electrode disposed inside of a void defined within the outer electrode and arranged coaxial with the outer electrode. The inner electrode includes: a base end defined by the first end of the outer electrode; and an apical end spaced from the base end. The system includes a fiber injector configured to inject a frozen fiber into the void from the apical end of the inner electrode; an electrode power source configured to energize the outer electrode and the inner electrode, and thereby, cause a plasma contained within the outer electrode to flow axially along the frozen fiber; and a frozen fiber power source configured to drive an electrical pulse to the frozen fiber.

A low temperature micro plasma ozone generating device for generating ozone by inhaling external air and reacting the sucked air with plasma. The low temperature micro plasma ozone generating device includes a main body having an accommodating space therein; an ozone generating module installed in an internal accommodation space of the main body to generate ozone; an external air supply line installed to be connected to the ozone generating module from an outside of the main body and configured to supply external air of the main body to an inside of the ozone generating module; an ozone discharge line installed to extend from the inside of the ozone generating module to the outside of the main body to discharge the ozone generated by the ozone generating module to the outside of the main body; and a cooling fan installed on one side of the main body.

The present disclosure relates to a portable plasma device which is convenient to carry and has excellent performance and is capable of simply, uniformly, and locally treating an inner surface of a microstructure such as a microwell plate by easily adjusting a plasma flame.

The invention relates to a flat flexible coating arrangement comprising a coating surface (9) for placing on a body region of a living being and at least one electrode (3, 3′) arranged above the coating surface (9), and a dielectric (1) containing the at least one electrode (3, 3′), the at least one electrode (3, 3′) comprising a supply line for an AC high voltage in order to form a dielectrically impeded plasma. Said arrangement enables fusion processes over the course of the plasma treatment and optionally wound healing without removing the coating arrangement from the body region by means of at least one built-in sensor (14) for determining at least one parameter of the body region.

A plasma engine includes a plasma source that generates ions from molecular gas species received at a gas input where at least some of the ions generated are atomic species ions. An ion extractor is configured to extract ions from the plasma source with an electric field. A housing comprising a recombination region receives ions extracted from the ion extractor. At least some of the atomic species ions recombine into molecular species in the housing, thereby releasing energy for thrust.

The present invention relates to a skin treatment apparatus using fractional plasma, in which a plasma generator includes an electrode plate, a dielectric body, a pin holder, a plurality of pins, and a gap maintaining part and further includes a lower support which includes a pin cover, vents, and an auxiliary gap maintaining part. According to the present invention, the plurality of pins are configured as independent electrodes to prevent concentration of plasma, ends of the plurality of pins are pointed to more smoothly generate plasma, the distances between the plurality of pins may be more reliably maintained using the pin cover, plasma generated by the plurality of pins may be evenly emitted onto the skin via the pin cover and vents without being concentrated on a curved region of the skin, and the auxiliary gap maintaining part moves in a vertical direction of the gap maintaining part to adjust a distance between the plurality of pins and the skin.

A dielectric barrier plasma generator includes: a dielectric substrate, a high-voltage electrode provided on a first surface of the dielectric substrate, a low-voltage electrode provided to face a second surface of the dielectric substrate, a power introduction section provided at a first end of the high-voltage electrode, a gas channel formed from a first end to a second end thereof between the dielectric substrate and the low-voltage electrode to allow gas to flow from the first end of the gas channel to the second end thereof, and a blowout outlet formed at the second end of the gas channel to blow out the gas that has flown through the gas channel and plasma that has been generated in the gas channel. The dielectric substrate includes a portion having a thickness being thinner when being closer to the blowout outlet.

An active gas generation apparatus according to the present disclosure includes: a base flange having a central bottom surface region and a peripheral protruding part; a cooling plate provided on the peripheral protruding part of the base flange; an insulating plate provided between the cooling plate and the high voltage apply electrode part; and an electrode holding member provided on a lower surface of the cooling plate to support the high voltage apply electrode part from a lower side. Provided is a gas separation structure of separating a gas flow between an in-housing space and a discharge space by the cooling plate, the electrode holding member, and the high voltage apply electrode part.