A handheld cold plasma device in which the device includes power source, control electronic circuit boards connected to high-frequency high-voltage transformers, user control panels, insulating case covering control electronic circuits, high-frequency high-voltage transformer and user control panel to form a monoblock, the plasma generating unit contains the active electrode and the passive electrode outside the housing to allow the user to be connected to the neutral wires of the device. The device according to the present disclosure uses the principle of direct discharge (or dielectric barrier discharge with floating electrodes) with small size, inexpensive and does not use consumable materials.

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.

An electrotechnical core for generating a cold atmospheric pressure or low-pressure plasma for the treatment of human, animal, or technical surfaces. The core has a side facing the surface and a side facing away from the surface and comprises the following layers, starting from the side facing the surface: a first insulation layer, a first electrode structure with a first contact between the first electrode structure and a power supply unit, a second insulation layer to galvanically isolate the first electrode structure and a second electrode structure from one another, wherein the second electrode structure is driven during operation by a voltage signal sufficient to ignite a plasma, a third insulation layer to galvanically isolate the second electrode structure from a third electrode structure, wherein the third electrode structure grounds the third electrode structure during operation.

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.

A BID includes: a discharger (2) including a dielectric pipe (8) and a pair of electrodes (14, 16) attached on an outer wall of the dielectric pipe, the pair of electrodes (14, 16) being arranged at a distance from each other in a direction along a central axis of the dielectric pipe (8), the discharger (2) being arranged so that plasma generating gas is introduced from a first end of the dielectric pipe (8) and configured to generates dielectric barrier discharge inside the dielectric pipe (8) to generate plasma; a detection section (4) including a sample gas introduction section (31) and a collection electrode (26) for collecting ions, the detection section (4) being configured to ionize components in the sample gas using light emitted from the plasma generated in the discharger (2) and to detect the generated ions by collecting them using the collection electrode (26); and a voltage supply (6; 6′) for generating a potential difference between the pair of electrodes (14, 16).

Disclosed is a method for treating actinic keratosis of tissue of a patient, the method including contacting non-thermal, atmospheric pressure plasma over areas of the tissue having actinic keratosis for a time and at treatment conditions effective to give rise to an at least partial amelioration of the keratosis.

Various embodiments relate to plasma actuators that generate fluidic flow. In one or more embodiments, a plasma actuator includes a first electrode and a second electrode. A dielectric film physically separates the first electrode and the second electrode of the plasma actuator. The dielectric film is configured to be attached to a surface to facilitate the plasma actuator providing fluidic flow for an environment. A method of using the dielectric film can include attaching the dielectric film to a surface of a machine, applying a voltage across electrodes of the dielectric film, and moving the machine based on an electrohydrodynamic (EHD) body force produced by the dielectric film.

A pulsed voltage is repeatedly applied between a first electrode and a second electrode to which a gas is supplied, a plasma is generated between the first electrode and the second electrode, and an active species is produced in the plasma. The energy necessary for plasma generation is set to a value greater than or equal to 1.8 W/cm.sup.3 and less than or equal to 8.5 W/cm.sup.3.

A first electrode and a second electrode, and a ceramic structural body into which a gas is introduced, and which is configured to introduce into water an active species produced by a plasma which is generated between the first electrode and the second electrode are provided. The ceramic structural body and at least one electrode from among the first electrode and the second electrode are formed together in an integrated manner.

A detection device for detecting and characterizing biological energy fields emitted by biological specimens is configured to collect and analyze an electromagnetic signal that includes millimeter-length waves generated by the interaction of atmospheric plasma with torsion waves of the biological energy field. The device performs spectral analysis on the millimeter waves to determine characteristics of the corresponding torsion waves that generated them. An array of several hundred non-thermal plasma plumes are placed directly in front of a circular horn. A switchable circular polarizer is used to select left hand circular, linear or right hand circular polarization. A low noise frequency converter allows a noise temperature of less than 1150 K. A frequency scan and averaging algorithm is developed to characterize noise temperature versus frequency, comparing signal and noise levels between plasma on and plasma off, and switching polarization sense.