Abstract: A method for protecting a substrate from corrosion, which method comprises in sequence: a first step including plasma polymerization of a precursor monomer and deposition of the resultant polymer onto at least one surface of a substrate; a second step including exposing the polymer to an inert gas in the presence of a plasma without further deposition of polymer onto the or each surface of the substrate; a third step including plasma polymerization of the precursor monomer used in the first step and deposition of the resultant polymer onto the polymer deposited in the first step so as to increase the thickness of the polymer; and optionally, a fourth step including exposing the polymer to an inert gas in the presence of a plasma without further deposition of polymer onto the or each surface of the substrate.

Abstract: The present invention relates to hydrophilic, multi-functional ultra-thin coatings deposited onto substrates for different applications, with excellent performance in terms of stability and durability. The present invention also describes improved methods to deposit the hydrophilic, multi-functional ultra-thin coatings of the present invention. The coatings are deposited by means of a low pressure and low power plasma polymerization. The present invention also comprises substrates coated with a method and a coating according as described in the present invention.

Abstract: A plasma chamber (11?) for coating a substrate with a polymer layer, the plasma chamber includes a first electrode set (14?) and a second electrode set (14?), the first and second electrode sets are arranged either side of a sample chamber for receiving a substrate, wherein the first and second electrode sets include plural electrode layers (141?, 142?) and wherein each electrode set includes plural radiofrequency electrode layers or plural ground electrode layers for coating polymer to each surface of a substrate.

Abstract: A method is provided for at least partially preventing discolouration of a substrate by a plasma coating process, by diffusing a plasma prior to and/or during depositing of said plasma on said substrate to form a coating. Also provided is a plasma coating apparatus comprising a plasma diffuser for homogenizing a plasma density nearby a substrate to be coated.

Abstract: The present invention concerns a method comprising the steps of: introducing a substrate comprising a surface to be coated in a low-pressure reaction chamber; exposing said surface to a plasma during a treatment period within said reaction chamber; ensuring a stable plasma ignition by applying a power input, characterized in that the power input is continuously strictly higher than zero Watt (W) during said treatment period and comprises at least a lower limit power and at least an upper limit power strictly larger than said lower limit power, thereby obtaining a substrate with a coated surface. The present invention further concerns an apparatus for treating a substrate with a low-pressure plasma process and a substrate treated as such.

Abstract: The present invention provides a method for applying a surface coating on, for example, a sheet of fabric and further provides a plasma chamber (10) for coating a sheet of fabric, e.g. a textile material, with a polymer layer, the plasma chamber (10) comprising a plurality of electrode layers (RF, M) arranged successively within the plasma chamber, wherein at least two adjacent electrode layers are radiofrequency electrode layers (RF) or ground electrode layers (M), thereby providing a surface coating on both sides of a fabric sheet.

Abstract: The invention provides a method of coating a fabric, e.g. a textile material, with a polymer coating, which method comprises contacting a fabric with a monomer and subjecting the monomer to low power plasma polymerization, wherein the monomer comprises the general formula (I): CnF2n+1CmX2mCR1Y—OCO—C(R2)?CH2, wherein n is 2 to 6, m is 0 to 9, X and Y are H, F, Cl, Br or I, R1 is H or alkyl, e.g. —CH3, or a substituted alkyl, e.g. an at least partially halo-substituted alkyl, and R2 is H or alkyl, e.g. —CH3 or a substituted alkyl, e.g. an at least partially halo-substituted alkyl.

Abstract: Treating a synthesis gas includes generating a plasma jet from a non-transferred arc torch having a main axis, the jet having a propagation axis substantially collinear with the torch main axis. The plasma torch is mounted on a feed enclosure. The syngas is received at an inlet port of the feed enclosure, downstream from the plasma torch and feeding the syngas so the flow encounters the plasma jet to mix the syngas and plasma jet in a distribution chamber. The mixture is propagated in a reactor downstream from the feed enclosure to convert the syngas into an outlet gas. The reactor is in communication in its upstream portion with the feed enclosure through a flared segment, and has a longitudinal axis that is substantially collinear with the propagation axis of the plasma jet. The outlet gas is extracted via an outlet port and particles are captured by a submerged conveyor.

Abstract: A plasma chamber (11?) for coating a substrate with a polymer layer, the plasma chamber comprises a first electrode set (14?) and a second electrode set (14?), the first and second electrode sets are arranged either side of a sample chamber for receiving a substrate, wherein the first and second electrode sets comprise plural electrode layers (141?, 142?) and wherein each electrode set comprises plural radiofrequency electrode layers or plural ground electrode layers for coating polymer to each surface of a substrate.

Abstract: Method of controlling the wear of at least one of the electrodes of a plasma torch including two electrodes having the same main axis, and being separated by a chamber designed to receive a plasma-generating gas, and at least one element for generating a magnetic field placed locally to the at least one electrode for which the control of wear is sought, in which the arc root is made to sweep longitudinally over a portion of the surface of this electrode from an initial position until the arc root reaches a defined final position of the portion, the longitudinal progression of the arc root being defined by a function dependent on at least the time, f(t), which is fixed.

Abstract: The invention relates to a conformal nanocoating applied by a low pressure plasma process. The invention also relates to a method for making such a conformal nanocoating on a three-dimensional nanostructure, in particular a three-dimensional structure containing electrically conductive and non-conductive elements.

Abstract: Treating a synthesis gas includes generating a plasma jet from a non-transferred arc torch having a main axis, the jet having a propagation axis substantially collinear with the torch main axis. The plasma torch is mounted on a feed enclosure. The syngas is received at an inlet port of the feed enclosure, downstream from the plasma torch and feeding the syngas so the flow encounters the plasma jet to mix the syngas and plasma jet in a distribution chamber. The mixture is propagated in a reactor downstream from the feed enclosure to convert the syngas into an outlet gas. The reactor is in communication in its upstream portion with the feed enclosure through a flared segment, and has a longitudinal axis that is substantially collinear with the propagation axis of the plasma jet. The outlet gas is extracted via an outlet port and particles are captured by a submerged conveyor.

Abstract: Method of controlling the wear of at least one of the electrodes of a plasma torch including two electrodes having the same main axis, and being separated by a chamber designed to receive a plasma-generating gas, and at least one element for generating a magnetic field placed locally to the at least one electrode for which the control of wear is sought, in which the arc root is made to sweep longitudinally over a portion of the surface of this electrode from an initial position until the arc root reaches a defined final position of the portion, the longitudinal progression of the arc root being defined by a function dependent on at least the time, f(t), which is fixed.

Abstract: The present invention pertains to a process and an device for plasma fusion inertizing of toxic materials, consisting of a melting vessel having an internal volume defined by walls. At least one non-transferred arc plasma source intended to generate a lance of plasma is inclined toward the lower part of the melting vessel and propagated along an axis of propagation situated outside of the vertical plane containing the normal to the wall at the point of intersection of said propagation axis with said wall so as to agitate the melting bath. The melting vessel is in fluid communication with the upstream part of a refining and pouring vessel and consists of an opening to which a non-transferred arc plasma source is connected, said source being mounted so as to emit a plasma lance to strike the refining bath directly in said upstream part.

Abstract: The invention relates to a method for pre-treating fibre reinforced composite plastic materials prior to painting, wherein the materials are subjected to a low pressure cold vacuum gas plasma treatment without preheating the materials. The invention further relates to a method for applying a painting layer on a fibre reinforced composite plastic material, wherein the method comprises the steps of pre-treating the material using a method according to any one of the preceding claims, and subsequently applying the painting layer to the pre-treated material.

Abstract: Treating a synthesis gas includes generating a plasma jet from a non-transferred arc torch having a main axis, the jet having a propagation axis that is substantially collinear with the main axis of the torch. The plasma torch is mounted on a feed enclosure. The syngas is received at an inlet port of the feed enclosure, the inlet port being downstream from he plasma torch and feeding the syngas so the flow encounters the plasma jet to mix the syngas and plasma jet. The mixture is propagated in an elongate reactor placed downstream from the inlet port to convert the syngas into an outlet gas. The reactor is in communication in its upstream portion with the feed enclosure and has a longitudinal axis that is substantially collinear with the propagation axis of the plasma jet. The outlet gas is extracted via an outlet port.

Abstract: The present invention relates to a vitrification process for a pulverulent material and an apparatus for implementing said process. The process consists in introducing the pulverulent material into the fusion area of a furnace via injection means, where it is melted by means of at least one plasma torch to obtain a melt, and where the melt is removed from the furnace via a casting zone, the material being introduced laterally into the fusion zone in a direction comprising a horizontal component, and the melt being removed from the furnace by overflowing via the said casting zone, more or less along said horizontal component and away from the means for injecting the material into the furnace, in relation to the fusion zone.