A base material adjusting method capable of removing an already-existing coating film with one time construction, which is suitable in terms of prevention of health problems of operators and in terms of environmental protection, and capable of suppressing disposal costs of waste. The base material adjusting method includes a coating film removing step of removing an already-existing coating film of a work object of the repainting operation by a wet blast method, and a rust removing step of removing rust generated after the coating film removing step by a dry blast method, and rust inhibitor is not included in slurry used in the wet blast method in the coating film removing step.

A base material adjusting method capable of removing an already-existing coating film with one time construction, which is suitable in terms of prevention of health problems of operators and in terms of environmental protection, and capable of suppressing disposal costs of waste. The base material adjusting method includes a coating film removing step of removing an already-existing coating film of a work object of the repainting operation by a wet blast method, and a rust removing step of removing rust generated after the coating film removing step by a dry blast method, and rust inhibitor is not included in slurry used in the wet blast method in the coating film removing step.

A coated panel may include at least a substrate and a top layer with a printed motif. The top layer may be provided on the substrate. The top layer may also include a transparent or translucent synthetic material layer, which is provided above the printed motif. The top layer and preferably at least the transparent or translucent synthetic material layer may include a foamable or foamed synthetic material.

A coated panel may include at least a substrate and a top layer with a printed motif. The top layer may be provided on the substrate. The top layer may also include a transparent or translucent synthetic material layer, which is provided above the printed motif. The top layer and preferably at least the transparent or translucent synthetic material layer may include a foamable or foamed synthetic material.

The invention relates to a polymer composition (P), comprising at least one acrylonitrile-butadiene-styrene copolymer (A) (ABS copolymer (A)), characterized in that the polymer composition (P) has a surface energy of >38 dyne/cm. The invention further relates to a process for painting a surface of a polymer moulded article comprising the polymer composition (P), wherein no pre-treatment of the surface of the polymer moulded article, such as primer coating, is required prior to the application of the paint.

The invention relates to a polymer composition (P), comprising at least one acrylonitrile-butadiene-styrene copolymer (A) (ABS copolymer (A)), characterized in that the polymer composition (P) has a surface energy of >38 dyne/cm. The invention further relates to a process for painting a surface of a polymer moulded article comprising the polymer composition (P), wherein no pre-treatment of the surface of the polymer moulded article, such as primer coating, is required prior to the application of the paint.

The purpose of the invention is a method for coating a substrate made of an aluminum alloy in the AA3000 or AA5000 series, comprising the following steps: a) coating by (co-)extrusion of a polypropylene modified by maleic anhydride adhesion layer on each face of said substrate, and a surface layer made of polypropylene comprising at least one slip agent, so as to form a metalloplastic strip; b) calendering said metalloplastic strip; c) heat treatment of said metalloplastic strip; d) cooling of the metalloplastic strip, to obtain an H48 metallurgical temper and a coefficient of friction of 0.06 or less. The method being particularly suitable for the fabrication of food packaging and particularly for beverage can lids.

The purpose of the invention is a method for coating a substrate made of an aluminum alloy in the AA3000 or AA5000 series, comprising the following steps: a) coating by (co-)extrusion of a polypropylene modified by maleic anhydride adhesion layer on each face of said substrate, and a surface layer made of polypropylene comprising at least one slip agent, so as to form a metalloplastic strip; b) calendering said metalloplastic strip; c) heat treatment of said metalloplastic strip; d) cooling of the metalloplastic strip, to obtain an H48 metallurgical temper and a coefficient of friction of 0.06 or less. The method being particularly suitable for the fabrication of food packaging and particularly for beverage can lids.

The corrosion laminate system (CLS) comprises cleaning the produced water (PW) storage tank through debris removal, wet blasting the tank, and drying the tank. The nozzle is inserted and sealed, leaving only the fiberglass portion of the nozzle in contact with the interior of the PW storage tank. The product for sealing the PW storage tank is then applied to the entire interior surface of the tank, the product is cured, and the PW storage tank can be used for storage.

The corrosion laminate system (CLS) comprises cleaning the produced water (PW) storage tank through debris removal, wet blasting the tank, and drying the tank. The nozzle is inserted and sealed, leaving only the fiberglass portion of the nozzle in contact with the interior of the PW storage tank. The product for sealing the PW storage tank is then applied to the entire interior surface of the tank, the product is cured, and the PW storage tank can be used for storage.