A glow discharge cell includes an electrically conductive cylindrical vessel, a hollow electrode, a cylindrical screen, a first insulator, a second insulator and a non-conductive granular material. The hollow electrode is aligned with a longitudinal axis of the cylindrical vessel and extends at least from the first end to the second end of the cylindrical vessel. The hollow electrode has an inlet, an outlet, and a plurality of slots or holes. The cylindrical screen is aligned with the longitudinal axis of the cylindrical vessel and disposed between the hollow electrode and the cylindrical vessel to form a substantially equidistant gap between the cylindrical screen and the hollow electrode. The first insulator seals the first end of the cylindrical vessel around the hollow electrode. The second insulator seals the second end of the cylindrical vessel around the hollow electrode. The non-conductive granular material is disposed within the substantially equidistant gap.

A plasma irradiation apparatus has a gas guide channel and a creeping discharge section. The creeping discharge section is disposed such that one of a discharge electrode and a ground electrode faces a flow path directly or via another member, and is configured to generate creeping discharge in the flow path by the application of a periodically changing voltage to the discharge electrode. At least a part of the ground electrode is arranged closer to an outlet port than the discharge electrode.

A high-frequency discharge ignition device includes a current supply device which supplies an AC current to a spark discharge path formed in a gap of an ignition plug, a control device which controls the operation of the current supply device, and a voltage detection device which outputs a signal of a section where a magnetic induction voltage of a primary coil generated after a switch element of an ignition coil device is placed in a shutoff state exceeds a predetermined voltage, and the control device determines the timing when the spark discharge path has been formed in the gap of the ignition plug according to an output signal of the voltage detection device and operates the current supply device based on the timing when the spark discharge path has been formed in the gap of the ignition plug to supply the AC current to the spark discharge path.

The plasma is formed between electrodes to be energized from an electric power source, containing a partially ionized mass having a luminescence region including neutral atoms (NA), primary electrons (PE), secondary electrons (SE), and ions.

The method comprises the interspersed steps of: accelerating the primary electrons (PE) toward one of said electrodes (10) polarized by a short, positive, high voltage pulse, impacting primary electrons (PE) against said electrode (10) and ejecting secondary electrons (SE) from it; subsequently, accelerating the secondary electrons (SE) toward the luminescence region by polarization of said electrode (10) by a negative voltage with a lower voltage pulse colliding the secondary electrons with neutral atoms (NA) and producing positive ions (PI) and derived electrons (DE); the negative pulse must have a period of time sufficient to accelerate the positive ions (PI) of the luminescent region towards the electrodes 10, striking the surface of said electrodes; repeating the previous steps in order to obtain a steady state plasma with a desired degree of ionization. The control of the intensity and the period of the positive and negative pulses allow the control of the degree of ionization and the volume of the luminescent region of the plasma.

A treatment device for treating a lens included in an operational device, is disclosed. The Device may include a first segmented electrode, comprising at least two segments electrically isolated from one another, located in proximity to a first surface of the lens, wherein the first surface is to be treated by the treatment device; at least one second electrode; a distributor electrically associated with the first segmented electrode and with the at least one second electrode, and configured to distribute RF energy from a single RF generator to each of the segments of the segmented electrode separately; an RF generator for separately providing RF energy to the segments of the at least one first electrode and the at least one second electrode in an amount sufficient to generate plasma on at least a portion of the first surface of the lens, and a controller functionally associated with the distributor.

The invention relates to a device for producing a cold atmospheric pressure plasma for the treatment of human and/or animal surfaces, comprising a flexible, planar multilayer system with a side facing the surface to be treated and a side facing away from the surface to be treated, wherein the multilayer system comprises the following layers, namely a first electrode layer on the facing away side of the multilayer system, second electrode layer on the facing side of the multilayer system, wherein the electrode layer has a plurality of recesses or is formed in a grid-like or meander-shaped fashion, a dielectric layer arranged between the first electrode layer and the second electrode layer, and a spacer layer arranged adjacent the second electrode layer on the facing side of the multilayer system. In addition, the invention relates to a cable, a generator unit for providing a high voltage, and a system.

A system for evaluating a bond includes a first electrode and a second electrode that are spaced apart from one another. The system also includes a sacrificial material layer positioned proximate to a surface of a bonded structure that includes the bond. The system also includes a power source configured to cause the first and second electrodes to generate an electrical arc that at least partially ablates the sacrificial material layer as part of a non-destructive inspection of the bond.

An airflow adjusting apparatus to be provided in a vehicle includes a flap and an airflow generator. The vehicle includes a wheel disposed to be partly protruded downward from a vehicle body of the vehicle. The flap is protruded, in front of the wheel, downward from the vehicle body. The airflow generator is configured to generate an airflow, and provided in an underneath of the vehicle body. The airflow generator is configured to generate an airflow. The airflow moves backward and downward of the vehicle and the airflow moves obliquely relative to a horizontal plane.

The present disclosure describes material surface treatment systems and methods that employ a byproduct treatment system to receive a byproduct generated by application of a plasma, the byproduct treatment system configured to degrade the byproduct and exhaust the degraded byproduct from the material surface treatment. The disclosed byproduct treatment system modifies the byproduct prior to evacuation from the material treatment system in order to reduce or eliminate byproduct contamination into the surrounding atmosphere.

An airflow adjusting apparatus to be provided in a vehicle includes airflow generators. The vehicle includes a front wheel and a rear wheel that are disposed in a vehicle longitudinal direction to be partly protruded from a bottom surface of a vehicle body of the vehicle downward in a vertical direction of the vehicle body. The airflow generators are provided on the bottom surface of the vehicle body and behind the front wheel. Each of the airflow generators is configured to generate an airflow along an underside of the vehicle body. The airflow has a speed component moving vehicle-widthwise inward. The airflow generators are disposed in a distributed arrangement in the vehicle longitudinal direction.