Provided herein is a plasma generating device for medical treatment and sanitizing purposes which comprises a control unit and a plasma generator connecting to the control unit. The plasma generator comprises a plasma tube having a first end and a second end; a first dielectric layer disposed on the inner surface of the plasma tube; a first electrode disposed on the first dielectric layer; a second dielectric layer disposed on the first electrode; a second electrode disposed on the second dielectric layer; and a plasma nozzle disposed on the bottom cover on the second end of the plasma tube.

Apparatus for reducing the translucence or opacity caused by smoke within a closed environment includes a fibrous substrate comprising non-conductive fibers. The apparatus further includes elongated, substantially parallel electrodes disposed on the substrate arranged as one or more pairs of adjacent electrodes, wherein a discharge gap is defined between each pair. The apparatus additionally includes a component configured for applying a voltage between each pair to generate a non-thermal microplasma in a corresponding discharge gap to collect or bind one or more airborne particulate combustion byproducts.

A radar-absorbing fiber-reinforced structure includes a fiber composite discharging part. The fiber composite discharging part includes a first electrode part and a second electrode part, which are spaced apart from each other by a dielectric layer and receive different voltages. The fiber composite discharging part is configured to discharge plasma in response to a voltage difference thereby changing a reflected wave or transmitted wave of a radar incident on the radar-absorbing fiber-reinforced structure to reduce reflectivity of the radar. At least one of the first electrode part and the second electrode part include a conductive fiber having a tensile strength equal to or more than 0.5 GPa.

A device for inhibiting condensation distortion on an optical element of a medical instrument configured for insertion into a body cavity is provided. The device may include a housing; a cavity within the housing, the cavity being sized to removably retain at least a portion of the medical instrument therein, wherein the portion includes the optical element; a plasma activation zone within the cavity and arranged such that when the at least a portion of the medical instrument is retained within the cavity, the optical element is located within the plasma activation zone; a plasma generator configured to be activated to cause formation of a plasma cloud in the plasma activation zone in a vicinity of the optical element; and a controller configured to activate the plasma generator for a time period sufficient to cause the optical element to become hydrophilic prior to insertion into the body cavity.

A device for inhibiting condensation distortion on an optical element is provided. The device may include a housing; a chamber within the housing; electrical circuitry in the housing; a plasma activation region configured to retain the optical element in a manner exposing an optical surface to the plasma activation region, wherein the electrical circuitry is configured to form an electrical connection with a first electrode located on the first side of the dielectric barrier; a second electrode located on a second side of the dielectric barrier, opposite the plasma activation region; and at least one processor configured to: control electricity flow through the circuitry to cause an electric field associated with a voltage drop between the first electrode and a second electrode to generate plasma within the plasma-activation region; and maintain the generated plasma for a time period sufficient to cause the optical surface to become hydrophilic.

Ion mobility spectrometers and methods for determining the ion mobility of a sample gas in dry air as drift gas are disclosed. The ion mobility spectrometers comprise a drift chamber, a reaction chamber, a dielectric barrier discharge ionisation source, a control unit, and a DBDI source, a pressure sensor, and a temperature sensor arranged in the chamber. A light source irradiates the DBDI source with light in a wavelength range from about 240 nm to about 480 nm. The control unit is designed to set an ignition voltage of the DBDI source and to control the light source depending on a determined pressure value and a determined temperature value. The methods control and utilize the control unit for operating the ion mobility spectrometer.

A kit of parts for use in treatment of tissue by a contained plasma and/or plasma products is disclosed. The kit of parts includes a plasma generating device for use with a membrane dressing attached to tissue requiring treatment. The plasma generating device comprises a first cavity with an opening at one end formed between a grounded electrode and a cathode such that, in use, an arc discharge between the cathode and the grounded electrode ionizes a feed gas to produce at the open end a thermal plasma. Furthermore, the plasma generating device also comprises a second cavity with an opening at one end formed between a high voltage electrode and a grounded electrode such that, in use, a dielectric barrier discharge between the high voltage electrode and grounded electrode ionizes a feed gas to produce at the open end a non-thermal plasma. The membrane dressing is suitable for covering tissue in use, such as a diabetic ulcer, and comprises a sheet of impermeable material configured for forming a plasma containment compartment adjacent to the tissue. The membrane dressing also comprises one or more input connectors configured to admit plasma and/or plasma products through the membrane dressing. The plasma generating device and the one or more input convectors of the membrane dressing are configured to allow the plasma generating device and the input connector to be directly coupled or indirectly coupled through a connector tube to allow fluid communication of the plasma and/or plasma products produced at the openings of the cavities of the plasma generating device through the membrane dressing to, in use, allow conduction of the produced plasma into the membrane dressing. Advantages of such a kit of parts may be that the membrane dressing does not need to be removed to inspect the progress of the wound, nor does it need to be removed and replaced to manage the exudate. Such advantages helps to mitigate the problems of wound aggravation and maceration typically associated with well-known wound dressings, and also helps to encourage and facilitate wound healing.

The invention relates to an electrode arrangement for generating a non-thermal plasma, with: a first electrode and a second electrode, wherein the first electrode and the second electrode are electrically insulated from each other and spaced from each other by a dielectric element, characterized in that the second electrode has an Electroless Nickel Immersion Gold (ENIG) coating, or an Electroless Nickel Electroless Palladium Immersion Gold (ENEPIG) coating, or an Electroless Nickel Immersion Palladium Immersion Gold (ENIPIG) coating, or an Electroless Palladium (EP) coating, or an Electroless Palladium Immersion Gold (EPIG) coating, and/or the dielectric element is made of a woven glass reinforced hydrocarbon ceramic.

A plasma treatment device (1), designed for treating a surface with a dielectrically impeded plasma, comprising an electrode arrangement (5) which has at least one electrode (3), and comprising dielectric (7) which completely covers the electrode (3) in relation to the surface to be treated, and comprising a housing (9) which contains a line arrangement (11) which comprises at least one high-voltage supply line (10, 10a, 10b), wherein the electrode (3) is connected to the line arrangement (11) and can be acted on by a high-voltage signal (13a, 13b), which can be applied to the high-voltage supply line (10, 10a, 10b), via the high-voltage supply line (10, 10a, 10b), allows, in a simple manner, the combination of an effective plasma treatment with an effective mechanical treatment of the surface to be treated by way of the plasma treatment device (1) having a brush head (15) which has a bristle area (17) and a bristle support (19) with a base surface (21), wherein the bristle area (17) has a large number of flexible bristles (23) and interspaces between the bristles (23), and the bristles (23) protrude from the base surface (21) of the bristle support (19) in a direction of an abutment surface (27) which is defined by those ends of the longest bristles (23) of the bristle area (17) that are averted from the base surface (21), wherein the bristle area (17) has a first length which is defined by the distance between the base surface (21) and the abutment surface (27), and wherein the at least one electrode (3) of the electrode arrangement (5), starting from the base surface (21), extends with a second length, which is smaller than the first length or equal to the first length and is at least 30% of the first length, into the bristle area (17) in the direction of the abutment surface (27).

A vehicle suspension can include an adapter mounting face, a spindle rigidly mounted relative to the adapter mounting face, a wheel mounting hub including a hub body rotatably mounted on the spindle by bearings, and an adapter that spaces a brake component away from the adapter mounting face. Another vehicle suspension can include a spindle, bearings, and a wheel mounting hub rotatably mounted on the spindle by the bearings, the wheel mounting hub can include a hub body and a wheel mounting flange, the hub body and the wheel mounting flange being separate components of the wheel mounting hub. A system for adapting a vehicle suspension to different suspension capacities can include multiple wheel mounting hubs including a same hub body internal configuration configured to be rotatably mounted on the spindle by the bearings, but the wheel mounting hubs including respective different wheel mounting flanges.