This invention covers a formulation providing protection against corrosion in liquid and vapor phase. Such formulations are used in applications where engine parts or fuel cell systems are subjected to a running-in or hot-test prior to final assembly or storage. The invention includes a concentrate as well as a dilute solution. The synergistic combination of inorganic ammonium derivatives in combination with monocarboxylic or dicarboxylic acids increases the period of protection. This enables storage for a longer period when the engine parts are shipped or stored prior to assembling. The use of the described invention pre-conditions the metal surface and provides protection even if afterwards the liquid is almost completely removed.

This invention covers a formulation providing protection against corrosion in liquid and vapor phase. Such formulations are used in applications where engine parts or fuel cell systems are subjected to a running-in or hot-test prior to final assembly or storage. The invention includes a concentrate as well as a dilute solution. The synergistic combination of inorganic ammonium derivatives in combination with monocarboxylic or dicarboxylic acids increases the period of protection. This enables storage for a longer period when the engine parts are shipped or stored prior to assembling. The use of the described invention pre-conditions the metal surface and provides protection even if afterwards the liquid is almost completely removed.

The present invention relates to a formula for an improved, volatile vapor corrosion inhibitor (VCI), and methods for using the VCI. More particularly, it relates to a fluid composition, and applications for the fluid composition, that inhibits corrosion and tarnishing and that is relatively non-toxic.

The present invention relates to a formula for an improved, volatile vapor corrosion inhibitor (VCI), and methods for using the VCI. More particularly, it relates to a fluid composition, and applications for the fluid composition, that inhibits corrosion and tarnishing and that is relatively non-toxic.

This invention covers a formulation providing protection against corrosion in liquid and vapor phase. Such formulations are used in applications where engine parts or fuel cell systems are subjected to a running-in or hot-test prior to final assembly or storage. The invention includes a concentrate as well as a dilute solution. The synergistic combination of inorganic ammonium derivatives in combination with monocarboxylic or dicarboxylic acids increases the period of protection. This enables storage for a longer period when the engine parts are shipped or stored prior to assembling. The use of the described invention pre-conditions the metal surface and provides protection even if afterwards the liquid is almost completely removed.

A process and system to protect an apparatus such as parts, components, equipment, vehicles and the like from environmental effects such as corrosion or rust using the oil-based VCI and a water-based film. In one aspect of the disclosure, the water-based film can be applied on top of a layer of an oil-based VCI that has been applied on an apparatus such as a vehicle (described below). In other aspects of the disclosure, the oil-based VCI is mixed in with the water-based film and then applied on top of the apparatus. In still other aspect of the disclosure, the oil-based VCI is applied on top of a layer of water-based film that has been applied to the apparatus.

An alkalinity control agent is sprayed upstream of a compressor in a first impurity separator to discharge impurities containing at least sulfur oxides in exhaust gas together with drain from an aftercooler in the first impurity separator.

A smart enclosure protection system for packages containing one or more metals comprises various sensors such as relative humidity, temperature of the metal, temperature within the package, a volatile corrosion inhibitor sensor, as well as a relative humidity sensor. Upon a computer receiving a signal from one or more of the noted sensors that the sensing item is either above or below a predetermined value, it will send a signal to one or more dispensers such as a dehumidifying compound dispenser, a volatile corrosion inhibitor compound dispenser, a soluble corrosion inhibitor compound dispenser, or a chemical fluid absorber or scavenger dispenser to dispense one or more such dispensing compounds that abates or removes an actual or a potential corrosion inhibiting situation.

A smart enclosure protection system for packages containing one or more metals comprises various sensors such as relative humidity, temperature of the metal, temperature within the package, a volatile corrosion inhibitor sensor, as well as a relative humidity sensor. Upon a computer receiving a signal from one or more of the noted sensors that the sensing item is either above or below a predetermined value, it will send a signal to one or more dispensers such as a dehumidifying compound dispenser, a volatile corrosion inhibitor compound dispenser, a soluble corrosion inhibitor compound dispenser, or a chemical fluid absorber or scavenger dispenser to dispense one or more such dispensing compounds that abates or removes an actual or a potential corrosion inhibiting situation.

A system for protecting storage tank soil side bottoms against corrosion includes a pipe system comprising non-perforated inlet pipes and perforated pipes connected thereto. A sleeve container having solid VCI compounds therein is inserted into the perforated pipes. The sleeves are permeable to vapors emitted by the solid VCI compounds and flow through the pipe to a perforation where they are admitted into an area beneath a storage tank so that they can contact the tank bottom (soil side) and protect the same from corrosion. Alternatively, solid SCI compounds can be used in combination with VCI compounds. The corrosion protection system is designed to be used with aboveground storage tanks. This includes, but is not limited to, single bottom tanks: newly installed or existing tanks undergoing bottom replacement or installation of double bottoms. These tanks are located on substrates such as the compacted soil/sand or hard substrates such as concrete, bitumen mixtures and asphalt where channels can be cut into the substrate for installation of the pipe system.