A method for investigating an electrolyte solution for processing a component, particularly a component or a component material of an aircraft engine, by near infrared spectroscopy.

A method for decorating metallic or non-metallic surfaces treated with Physical Void Deposition, PVD, comprising: an electrochemical activation action of the decoration by means of an electrical circuit with electrodes in electrical contact and for at least one thereof with the mediation of an electrolytic solution towards a surface being treated; an electrically conductive surface facing one of said electrodes to form said surface being treated; at least one masking resistant to the electrochemical activation action of the decoration and interposed between the facing electrode and the surface being treated; and has the electrochemical action of activating the decoration of the treated surface occurs by electrochemical oxidation of the metallic oxide layer normally present on the electrically conductive surface whether it is placed below the PVD coating layer, i.e., performed before such PVD coating, or such electrochemical oxidation action is performed above said vacuum metallic coating, electrically conductive PVD layer; the electrochemical oxidation acts with the surface of the treated metal, its natural oxide, or the PVD coating itself, i.e., on the oxides, carbides, nitrides forming it, without any removal of metallic material but with the aesthetic modification of the treated surface in the shape determined by the aforesaid masking.

An exterior material of a home appliance having improved corrosion resistance and fingerprint resistance by changing a treatment method of a surface of the exterior material, and the home appliance including the same, and a manufacturing method therefor are provided. The method of manufacturing the exterior material of the home appliance, the method including applying a diamond like carbon (DLC) coating on the substrate to form a DLC coating layer; and conducting anti-fingerprint coating to form the anti-fingerprint coating on the DLC coating layer.

An exterior material of a home appliance having improved corrosion resistance and fingerprint resistance by changing a treatment method of a surface of the exterior material, and the home appliance including the same, and a manufacturing method therefor are provided. The method of manufacturing the exterior material of the home appliance, the method including applying a diamond like carbon (DLC) coating on the substrate to form a DLC coating layer; and conducting anti-fingerprint coating to form the anti-fingerprint coating on the DLC coating layer.

An electro-anti deposit device is coupled to an irrigation pipe for removing mineral deposit from drippers of the pipe. The electro-anti deposit device includes an engine configured to move the electro-anti deposit device along the pipe. The electro-anti deposit device also includes a mineral deposit removal module. The mineral deposit removal module includes a water container, a battery, and two electrodes. The water container may be configured to create an ionic environment at a dripper. The dripper may be covered with the mineral deposit. The battery may be configured to generate electric current. The two electrodes may be connected to two poles of the battery with a space separating tips of the two electrodes.

Metal surface pretreatments using ionic liquids prior to electroplating are disclosed. The surface treatments include forming an activated metal substrate surface by removing any naturally formed metal oxide layers formed on the surfaces of the metal substrates. According to some embodiments, the surface treatments include exposing the metal substrate to a non-aqueous ionic liquid. In some embodiments, an electrical current is applied to the metal substrate to assist removal of the metal oxide layer. The electrical current can be a pulsed anodic current. After activating the surface, a metal layer can be deposited on the activated surface. In some embodiments, the metal layer is electrodeposited in the same ionic liquid used to form the activated surface. The resultant metal coating is resistant to scratching and peeling.

Metal surface pretreatments using ionic liquids prior to electroplating are disclosed. The surface treatments include forming an activated metal substrate surface by removing any naturally formed metal oxide layers formed on the surfaces of the metal substrates. According to some embodiments, the surface treatments include exposing the metal substrate to a non-aqueous ionic liquid. In some embodiments, an electrical current is applied to the metal substrate to assist removal of the metal oxide layer. The electrical current can be a pulsed anodic current. After activating the surface, a metal layer can be deposited on the activated surface. In some embodiments, the metal layer is electrodeposited in the same ionic liquid used to form the activated surface. The resultant metal coating is resistant to scratching and peeling.

An electrode for an electrolytically acting doctor blade (1) for pickling and cleaning both planar and curved metal surfaces, comprising a linear metal element supported on the structure of the doctor blade and electrically connected to the electric circuit for initiating the pickling electrolytic action; a pad made of a felt-like absorbent plastic material, resistant to high temperatures and to the chemicals contained in the electrolytic solution used; characterised in that a the linear metal element consists in a metal wire (8, 38), and a pad (7, 34, 41) having a constant thickness (S), made of a felt-like absorbent plastic material, resistant to high temperatures and to the chemicals contained in the electrolytic solution used, is wrapped therearound; the metal wire being connected to the structure of the doctor blade only at the ends of the doctor blade (25) in the active face of the deformable electrode (2, 20, 33, 35).

Different constructive forms of the electrode for doctor blade are described, wherein the metal wire is associated with carbon elements of various shapes to facilitate electrical contact with the pad.

An electrode for an electrolytically acting doctor blade (1) for pickling and cleaning both planar and curved metal surfaces, comprising a linear metal element supported on the structure of the doctor blade and electrically connected to the electric circuit for initiating the pickling electrolytic action; a pad made of a felt-like absorbent plastic material, resistant to high temperatures and to the chemicals contained in the electrolytic solution used; characterised in that a the linear metal element consists in a metal wire (8, 38), and a pad (7, 34, 41) having a constant thickness (S), made of a felt-like absorbent plastic material, resistant to high temperatures and to the chemicals contained in the electrolytic solution used, is wrapped therearound; the metal wire being connected to the structure of the doctor blade only at the ends of the doctor blade (25) in the active face of the deformable electrode (2, 20, 33, 35).

Different constructive forms of the electrode for doctor blade are described, wherein the metal wire is associated with carbon elements of various shapes to facilitate electrical contact with the pad.

An electrolytically acting doctor blade for pickling and cleaning curved metal surfaces comprises an electrode (2, 26, 34) embodied by a metal wire (8, 32) around which a pad (7, 30) made of a felt-like absorbent plastic material, resistant to high temperatures and to the chemicals contained in the electrolytic solution used, is wrapped; gripping means of the doctor blade on the electrode over the length of the face (F) of the doctor blade; electrical connection of the ends of the metal wire (8, 32) by means of a power supply electric cable (16) to initiate the electrolytic action; and has the gripping means of the doctor blade (1) on the electrode (2, 26, 34) connected to each other by the means placed alongside, in which the connection section, in the deformable body of the doctor blade (3) which has been made pliable, is oriented towards the face (F) of the doctor blade; a push or pull mechanism acts on the ends (25) of the doctor blade and, to obtain a reaction, with a middle part of the mechanism, connected to the middle part of the deformable body of the doctor blade (3), deforms the face of the doctor blade from rectilinear into the arched, convex or concave conformation, depending on the pull or push on the ends of the doctor blade, with respect to the middle part of the doctor blade, exerted by the said mechanism.

Different constructive forms of electrolytically acting doctor blade for pickling and cleaning curved metal surfaces with the use of different deformable electrodes are described.