A control circuit for generating a primary alternating current (AC) voltage signal provided to a dielectric barrier discharge (DBD) disk of a three-dimensional printer includes a switching regulator receiving a direct current (DC) voltage signal. The switching regulator modulates the DC voltage signal based on a variable duty cycle to create a modulated DC signal. The control circuit also includes a modulation circuit in electrical communication with the switching regulator. The modulation circuit introduces a frequency component to the modulated DC signal, where the primary AC voltage signal includes a variable duty cycle and a set frequency, and the frequency component introduced into the modulated DC signal is representative of the set frequency of the primary AC voltage.

Some embodiments are directed to a generator and separator assembly for generating ions via atmospheric pressure, low temperature plasma and separating the generated ions. The generator and separator assembly include a plasma generator for generating the generating atmospheric pressure, low temperature plasma that is configured to eject positively and negatively ions. A separator is disposed to receive the positively and negatively ions ejected from the plasma generator, and includes a first separator electrode; a second separator electrode spaced from the first separator electrode; and a separator power supply that supplies electric power in the form of at least one of different voltages and different polarities to the first and second electrodes ranging from 0 kV and 10 kV, such that the received positively charged ions are redirected in one direction and the received negatively charged ions are redirected to another direction different from the one direction.

The disclosure relates to a flexible active species generator comprising: a first electrode of a conductive metal thin film; a second electrode of a ground electrode; a flexible dielectric layer of an insulator formed between the first electrode and the second electrode; and a plasma resistant functional layer formed between the dielectric layer and the second electrode, wherein the first electrode and the second electrode are electrically connected to an external power supply to generate an atmospheric pressure plasma to generate active species. The flexible active species generator has a plasma resistant function to prevent deformation and decomposition of an insulator caused by the plasma as well as an active species generating function from atmospheric pressure plasma, and has durability and safety, which is thus applicable to articles, foods, garments and human body in various forms.

A plasma generator includes an AC power supply, a power supply electrode and a ground electrode, one of which is disposed in a gas flow path and the other of which is a conductive wall constituting the gas flow path, an inflexible connection member configured to electrically connect the AC power supply and the power supply electrode, and an insulating material (power supply side insulating material, ground side insulating material) covering a side of one of the power supply electrode and the ground electrode, the side facing the other electrode.

A flexible elongate atmospheric plasma generator for generating a transverse atmospheric plasma within configured for insertion into an internal channel of an elongate endoscope tube, the plasma generator including an elongate body of dielectric material, an elongate first electrode centrally located within the body of dielectric material and an elongate second electrode around an elongate external surface of the body of dielectric material, the second electrode having a plurality of electrically conductive elements forming a mesh defining holes in the second electrode, wherein application of a potential difference across the first and second electrodes can generate a plasma within atmospheric air surrounding the atmospheric plasma generator.

A device with a pouch having a pouch wall with an inner side and an outer side, the pouch wall defining an interior of the pouch. A plurality of electrodes embedded in the pouch wall with at least one electrode partially exposed within the interior of the pouch. The plurality of electrodes generate plasma within the interior of the pouch in response to application of an voltage to the plurality of electrodes.

A treatment device for a body surface to be treated using a dielectric barrier plasma, including a high-voltage generator connected to a headpiece having a conductive element at least partially shielded by a dielectric wall that forms at least one part of an end wall facing the surface to be treated.

The present invention relates to a skin treatment apparatus using plasma. A plasma generator (400) comprises an electrode plate (420), an upper dielectric body (430), independent electrode portions (440) and a lower dielectric body (450). The independent electrode portion is an FPCB or a silver paste positioned a fixed distance away. According to the present invention, the electrode portions each independently work and thus prevent unevenness of plasma and enable the plasma to be generated evenly. According to the present invention, the plasma generator having such configuration is easily formed into a convex shape, and a convex plasma generator is suitable for a curved skin object such as the palm. The convex plasma generator can generate more even plasma and is particularly more effective for a long cylindrical object to be treated, such as the woman's vagina.

A polarization apparatus includes a conductive carrier, a dielectric barrier discharge (DBD) plasma source, an electric net, a DBD power supply, and a DC power supply. The conductive carrier has a carrying surface which is configured to carry a work piece. The work piece includes a piezoelectric material film, and the conductive carrier is grounded. The DBD plasma source is disposed over the carrying surface and is configured to apply plasma toward the piezoelectric material film. The electric net is disposed between the carrying surface and the DBD plasma source. The DBD power supply includes a first electrode and a second electrode, in which the first electrode is electrically connected to the DBD plasma source, and the second electrode is grounded. The DC power supply includes a third electrode and a fourth electrode. The third electrode is electrically connected to the electric net, and the fourth electrode is grounded.

In the present disclosure, in a high-voltage side electrode component, the electrode main dielectric film is provided on the lower surface of the electrode conductive film, and the electrode additional dielectric film is disposed below the electrode main dielectric film at an upper main/additional inter-dielectric distance. The electrode main dielectric film includes the whole electrode conductive film in a plan view, and has a formation area larger than the electrode conductive film. The electrode additional dielectric film includes the electrode conductive film in a plan view and has a formation area slightly larger than the electrode conductive film and smaller than the electrode main dielectric film. The ground side electrode component has the same features as the above-mentioned features of the high-voltage side electrode component.