A volatile corrosion inhibitor detection device includes a coupling configured to couple to a system configured to be closed, and a housing in fluid communication with the coupling and containing an indicator element configured to visually change upon contact with volatile corrosion inhibitor. A bendable and crushable portion of the housing contains the indicator element and further contains an indicator capillary, the indicator capillary contains indicator fluid, and the indicator element and the indicator capillary are arranged such that, upon breaking of the indicator capillary by bending or crushing a portion of the housing, the indicator fluid is released from the indicator capillary and reaches the indicator element to render the indicator element sensitive to volatile corrosion inhibitor, thereby providing an indication upon contact with the volatile corrosion Inhibitor.

Disclosed is a protective textile embodiment for use to prevent corrosion and deterioration of iron, steel and similar metal containing materials by environmental conditions such as sea water, fresh water, humidity, dust, sand, extreme wind, UV lights, too low/high temperatures, immediate temperature changes etc. A method for production of the protective textile embodiment is also disclosed.

Disclosed is a protective textile embodiment for use to prevent corrosion and deterioration of iron, steel and similar metal containing materials by environmental conditions such as sea water, fresh water, humidity, dust, sand, extreme wind, UV lights, too low/high temperatures, immediate temperature changes etc. A method for production of the protective textile embodiment is also disclosed.

A corrosion risk reduction method includes introducing volatile corrosion inhibitor into a piping system, and distributing the volatile corrosion inhibitor inside the system. A corrosion risk reduction apparatus comprises at least one corrosion risk reduction module, which comprises a housing including inlet and outlet ports. The housing contains a volatile corrosion inhibitor. An outlet of the corrosion risk reduction apparatus is configured for fluid communication with a system, and is further configured to direct gas containing volatile corrosion inhibitor from the inside of the housing of the at least one corrosion risk reduction module into the system for distribution inside the system. A volatile corrosion inhibitor detection device comprises a coupling for coupling to a system configured to be closed, and a housing in fluid communication with the coupling and containing an indicator element configured to visually change upon contact with volatile corrosion inhibitor.

A method of preventing or mitigating corrosion on a metallic surface exposed to a supercritical fluid is disclosed. The method includes adding a corrosion inhibitor composition to a supercritical fluid comprising a supercritical carbon dioxide; and contacting the supercritical fluid with a metallic surface, wherein the corrosion inhibitor composition comprises a corrosion inhibitor that has a solubility of greater than 5,000 ppm in the supercritical fluid at 48.9° C. and 2,200 psi.

A hydrocarbon tank system environment corrosion inhibitor includes use of inert gas, preferably Nitrogen, to blanket ullage and interstice through the tank system. Blanket gas is provided is controller into coupling to access ullages. Blanket gas is provided upon fueling events to stabilize the pressure in the system and prevent entry of atmospheric air and water (vapor). Blanket gas may be continuously run into the ullage and/or other spaces in tank system. A controlled system allows for monitoring of pressures in the tank, and thereby identifies pressure events and even leaks in system due to unusual events, or general loss of pressure.

A hydrocarbon tank system environment corrosion inhibitor includes use of inert gas, preferably Nitrogen, to blanket ullage and interstice through the tank system. Blanket gas is provided is controller into coupling to access ullages. Blanket gas is provided upon fueling events to stabilize the pressure in the system and prevent entry of atmospheric air and water (vapor). Blanket gas may be continuously run into the ullage and/or other spaces in tank system. A controlled system allows for monitoring of pressures in the tank, and thereby identifies pressure events and even leaks in system due to unusual events, or general loss of pressure.

A rust inhibitor for a gasket, a gasket for a secondary battery including the same, and a secondary battery are provided. The rust inhibitor includes an anti-rust material and a polymer resin, wherein the polymer resin includes at least one of polyethylene or a copolymer which includes 2 or more derived units selected from the group consisting of an ethylene-derived unit, a propylene-derived unit, a butylene terephthalate-derived unit, an ethylene terephthalate-derived unit, and a methyl acrylate-derived unit.

Embodiments of the present disclosure relate to articles, coated articles, and methods of coating such articles with a corrosion resistant coating. The corrosion resistant coating can comprise hafnium aluminum oxide. The corrosion resistant coating may be deposited by a non-line of sight deposition, such as atomic layer deposition. Articles that may be coated may include chamber components, such as gas lines.

A storage solution that provides substantial advantages over existing storage solutions. The storage solution includes a corrosion inhibition system that provides or facilitates free progression or dispersion of volatile corrosion inhibitor (VCI) molecules in a chamber or cavity formed or enveloped in the storage solution.