Abstract: Systems and methods for a nitric oxide (NO) generation system are provided. In particular, the present disclosure provide an NO generation system that is configured to be cooled to maintain an NO generator of the system at or below temperatures safe for patient use and contact. In some non-limiting examples, the NO generation system may include a pump configured to furnish a fluid (e.g., a gas) toward and/or through the NO generator to provide cooling thereto.

Abstract: An apparatus for the treatment of a liquid that includes a chamber having at least one inner surface, the chamber adapted for passage of a fluid therethrough. The chamber is at least 80 percent enclosed. The apparatus also includes an optional ultraviolet-transmissive tube disposed within the chamber and also adapted for the passage of the liquid therethrough. The apparatus further includes an ultraviolet lamp disposed within the chamber and, optionally, within the ultraviolet-transmissive tube. A reflective material is interposed between the chamber and the transmissive tube. The reflective material is adapted so as to reflect at least a portion of light emitted by the ultraviolet lamp, wherein the reflective material is at least 80 percent reflective.

Abstract: A lighting module includes a connector having a first contact and a second contact, a first device that emits ultraviolet (UV) light, and a second device that emits visible light. The UV light emitted by the first device is in a first wavelength range of 200-315 nm and the visible light emitted by the second device is in a second wavelength range of 400-750 nm. The first device emits substantially no light at a wavelength greater than 550 nm. Both the first device and the second device are coupled to the first contact. The lighting module may be used in a disinfection device.

Abstract: A system including apparatus and methods for sanitizing or otherwise reducing biologics present on thermal therapeutic treatment wraps used for treating athletes after workouts or games, physical therapy patients after injury, and hospital patients after surgery is disclosed. The system includes a storage cabinet with an internal conveyor system that exposes each wrap to periodic sanitization or other biologic reduction means, such as ultraviolet light. This prevents growth of bacteria and mold. In some embodiments, warm air is blown into the storage cabinet to assist with drying the wraps.

Abstract: A plasma generator includes an outer electrode that encloses a first inner electrode and a second inner electrode. The first inner electrodes includes a plurality of protrusions that extend towards the outer electrode. A voltage signal can be applied across the outer electrode and the first inner electrode to excite gas injected into gaps between the protrusions and the outer electrode. Plasma is generated surrounding the protrusions. The second inner electrode is at a downstream location of the excited gas relative to the first inner electrode. The second inner electrode forms a second gap with the outer electrode. A voltage signal can be applied across the second inner electrode and the outer electrode, further exciting the gas to generate second plasma at the second gap. The second plasma is spread evenly across the second inner electrode and the outer electrode.

Abstract: An electrolytic plating apparatus includes a plating tank that is filled with plating liquid; a moving mechanism configured to vertically move a processing target substrate in a direction normal to a surface of the plating liquid; a seal member that is disposed at a peripheral edge portion of a processing target surface of a processing target substrate and is configured to seal the plating liquid to a center side of the processing target surface when the processing target substrate is immersed in the plating tank; and a contact member that is separated from the seal member and is electrically connected to the processing target surface.

Abstract: Many hospitals and medical facilities have a need to safely dispose of their biomedical waste. Onsite processing, particularly with ozone, is often less expensive and safer than off site handling, but many facilities lack the room for conventional ozone equipment with appropriate capacity to meet their needs. Accordingly, the present inventors devised, among other things, an exemplary system that includes, among other features, an shredder, an upwardly inclined auger chamber, and a waste receptacle. The shredder shreds unsterilized waste and feeds into the lower end of the inclined auger chamber. The chamber includes ozone injectors to treat waste as the auger conveys it upward toward an outlet that drops the sterilized waste into the waste receptacle. The incline of the chamber allows for a smaller system footprint with sufficient processing capacity to satisfy the needs of smaller hospitals and clinics.

Abstract: An electrochemical cell includes a working electrode in contact with an aqueous electrolyte solution, a counter electrode in contact with the aqueous electrolyte solution, and a reference electrode in contact with the aqueous electrolyte solution. The working electrode comprises a plasma modified epitaxial synthesized graphene surface fabricated on SiC.

Abstract: Provided herein is a method for producing a multicoat paint system on a metallic substrate by producing a basecoat or a plurality of directly successive basecoats directly on a metallic substrate coated with a cured electrocoat system, producing a clearcoat directly on the one or the topmost of the plurality of basecoats, and subsequently jointly curing the one or the plurality of basecoats and the clearcoat, wherein at least one basecoat material used for producing the basecoats includes at least one aqueous dispersion which includes a polymer whose preparation includes successive radical emulsion polymerization of three mixtures of olefinically unsaturated monomers.

Abstract: A method for the electrohydrodynamic deposition of carbonaceous materials utilizing an electrohydrodynamic cell comprising two electrodes comprised of a conductive material, by first combining a solid phase comprising a carbonaceous material and a suspension medium, placing the suspension between the electrodes, applying an electric field in a first direction, varying the intensity of the electric field sufficiently to drive lateral movement, increasing the electrical field to stop the lateral transport and fix the layers in place, then removing the applied field and removing the electrodes. Among the many different possibilities contemplated, the method may advantageously utilize: varying the spacing between the electrodes; removing the buildup from one or both electrodes; placing the electrodes into different suspensions; adjusting the concentration, pH, or temperature of the suspension(s); and varying the direction, intensity or duration of the electric fields.

Abstract: An electrode assembly, comprising (a) a conductive electrode, having (i) a first electrode surface, (ii) a second electrode surface, opposite the first electrode surface, (iii) an electrode edge, connecting the first and second electrode surfaces, and (iv) an electrode tab, for making an electrical connection to the electrode. The electrode assembly further comprises (b) a dielectric, enclosing the first and second electrode surfaces and the electrode edge, and (c) a first working surface, on the first electrode surface, wherein the dielectric is present between the first working surface and the first electrode surface. The dielectric is conformal with the first electrode surface, the second electrode surface and the electrode edge.

Abstract: Exemplary methods of and system for generating an antimicrobial wipe to clean and disinfect a surface contaminated with bacteria, viruses, spores, fungi, or combinations thereof. In some embodiments, the method includes applying non-thermal plasma to a moistened wipe to activate a liquid in the wipe. In some embodiments, the method includes applying non-thermal plasma to a liquid and then applying the activated liquid to a wipe. In one embodiment of a system for generating an antimicrobial wipe the system includes a housing having an opening; a supply of wipes disposed within the housing; a non-thermal plasma generator disposed within the housing; a power supply electrically coupled to the non-thermal plasma generator; and a feed system disposed within the housing, wherein the feed system moves one or more wipes from the supply of wipes past the plasma generator and out of the opening. As the feed system moves the wipes past the plasma generator, the plasma generator applies non-thermal plasma to the wipes.

Abstract: An apparatus and method for abating ozone and reducing sulfuric acid from an exhaust stream. In a semiconductor manufacturing plant the processing of wafers involves the cleaning and etching of wafers, the resultant processing may produce gasses which must be abated. The apparatus and method utilizes UV light in high doses to convert ozone (O3) to oxygen (O2). By ensuring laminar flow through the UV light chambers, the efficiency of the system is sufficient to allow for the remaining impurities in the exhaust air to be removed through the use of an RTO.

Abstract: An apparatus for producing reforming liquid includes a treatment tank in which an introduced liquid is swirled so as to generate a gas phase in the vicinity of a swirling center of a swirling flow of the liquid, a first electrode which has at least a portion which is disposed in the treatment tank and comes into contact with the liquid in the treatment tank, a second electrode which is disposed so as to come into contact with the liquid in the treatment tank and a power source which is configured to apply a voltage between the first electrode and the second electrode so as to generate plasma in the gas phase. A reformed liquid is produced in a manner that the plasma is generated in the gas phase so as to form a reformed component, and the formed reformed component is dissolved and dispersed in the liquid.

Abstract: Provided is an ion wind generation device which is capable of providing a wide range of ion delivery and providing ion wind having a reduced ozone concentration near a nozzle without use of a filter or the like. The ion wind generation device includes an electrode pair including a discharge electrode body having a discharge portion and a counter electrode body having a plurality of end portions, and generates ion wind by corona discharge that occurs due to a potential difference generated between the discharge portion and the end portions. The end portions are located spaced apart from one another in a single plane and disposed around an axis of the discharge electrode body in the single plane or disposed along a line in the single plane.

Abstract: A device and method for forming NO-containing gas flow to treat a biological object is disclosed. The device may include an anode, a cathode, an interelectrode area between the cathode and the anode, an NO-containing gas flow outlet channel leading from the interelectrode area to a nozzle for directing and releasing the NO-containing gas flow from the device and a mechanism to adjust a relative position between the anode and the cathode to produce varying concentrations of NO. In addition, the device may include one or more features for interconnecting the various components to ensure proper and consistent assembly of the device.

Abstract: The present application relates to a cold plasma device (13) for treating a surface (6) with cold plasma. The device (13) has a cold plasma generator (14) adapted to generate cold plasma that produces reactive species for treating the surface (6). The device (13) also includes a treatment head (5) that is positionable relative to the surface (6) such that the reactive species are imparted toward the surface (6) during treatment. The device (13) is also provided with an air flow generator (8) to generate an air flow over the surface (6) and a controller (9) configured to control operation of the air flow generator (8) to generate an air flow over the surface (6) after the treatment has been completed such that remaining by-products of the cold plasma are dissipated.

Abstract: A photocatalytic element including: a photocatalytic layer containing at least one photocatalytic material; and a light emitting source in optical communication with the photocatalytic material, the light emitting source disposed sufficiently proximal to the photocatalytic material to raise the surface temperature of at least some of the photocatalytic material to a temperature between 10° C. and 90° C. is provided.

Abstract: Disclosed are high and low impedance systems and methods for the generation and use of constant intensity electric fields for a variety of applications. Electric fields may be generated through gas, liquid, or solid phase materials for a variety of purposes on a subject material itself, or on materials, particles, or objects mixed, dissolved, suspended, or otherwise entrained in such materials, or on both. A number of systems and methods involve certain device geometries, parallel alignment of the electric field vector with the material under treatment, separation of the high impedance electrodes from the material under treatment, voltage or current sourcing linear and quasilinear voltage ramp input waveforms, and the employment of a high impedance dielectric coating on one side of conductive substrates of electrodes that function as barriers to electronic and ionic current.

Abstract: Disclosed is a plasma sterilizer apparatus for a pipe and, more particularly, to a plasma sterilizer apparatus for a pipe, which can be easily mounted on a pipe and effectively sterilize harmful microorganisms contained in water or raw materials flowing through a pipe. A plasma sterilizer apparatus for a pipe comprises: a first connection member connected to one side of a pipe; a second connection member connected to the other side of the pipe; a first electrode mounting member disposed in contact with the first connection member; a second electrode mounting member disposed in contact with the second connecting member; a first electrode member provided on the first electrode mounting member; and a second electrode member provided on the second electrode mounting member.