The disclosed technology generally relates welding wires, and more particularly to coated welding wires. A consumable welding wire comprises a base wire comprising a steel composition and a coating comprising an iron surrounding the base wire, wherein the iron oxide has an oxygen to iron (O/Fe) ratio such that an outer surface of the welding wire has a dark gray to black color.

A composition for coating stainless steel includes sodium silicate, lithium silicate, sodium tetraborate, and a solvent as the remainder so that a contaminant on the surface of stainless steel is easily removed and yellowing of the stainless steel can be prevented. A cooking appliance includes the stainless steel surface coated with the composition.

An additive comprising one or more C.sub.3-C.sub.12 hydroxycarboxylic acids and/or one or more C.sub.3-C.sub.12 hydroxycarboxylic acid salts may be added to an aqueous system having galvanized metallurgy or a carbon steel surface in an effective amount to passivate a galvanized coating on the metallurgy or to decrease white rust formation or other types of corrosion upon the galvanized metallurgy or carbon steel surface in an aqueous system. In a non-limiting embodiment, the C.sub.3-C.sub.12 hydroxycarboxylic acid or the C.sub.3-C.sub.12 hydroxycarboxylic acid salt additive may utilize the zinc in the galvanized coating to achieve passivation. The passivation may occur while the system is shut down or in service. The aqueous system may be or include a cooling tower, a cooling water system, and combinations thereof. The additive may be used with or in the absence of a phosphorous-containing compound.

A composite can include a substrate and a conversion coating overlying the substrate and comprising at least one of a zirconium oxide, a hafnium oxide, or a combination thereof. The conversion coating can be formed from a zirconia or hafnia-based complex obtained by reacting at least one of a zirconium ion source, a hafnium ion source, or a combination thereof, with a chelating compound in a reaction and another chelating compound in another reaction.

A composite can include a substrate and a conversion coating overlying the substrate and comprising at least one of a zirconium oxide, a hafnium oxide, or a combination thereof. The conversion coating can be formed from a zirconia or hafnia-based complex obtained by reacting at least one of a zirconium ion source, a hafnium ion source, or a combination thereof, with a chelating compound in a reaction and another chelating compound in another reaction.

A composition with corrosion inhibiting properties is provided that includes a first phosphate salt of at least one of trimetaphosphate, hexametaphosphate, or tripolyphosphate. A second phosphate salt of at least one of a disodium phosphate and tetrasodium pyrophosphate is also present with the first phosphate salt present in a weight ratio relative to the second phosphate salt of from 1-4:1. Upon dissolution from 0.1 to 5 total weight percent in a solvent a corrosion inhibiting solution results that is well suited for usage as a water conditioner in cooling systems. A process of protecting an iron containing metal from corrosion is also provided that includes exposing the metal to the solution. The corrosion of the metal over time is monitored to assure the protection of the metal.

A composition with corrosion inhibiting properties is provided that includes a first phosphate salt of at least one of trimetaphosphate, hexametaphosphate, or tripolyphosphate. A second phosphate salt of at least one of a disodium phosphate and tetrasodium pyrophosphate is also present with the first phosphate salt present in a weight ratio relative to the second phosphate salt of from 1-4:1. Upon dissolution from 0.1 to 5 total weight percent in a solvent a corrosion inhibiting solution results that is well suited for usage as a water conditioner in cooling systems. A process of protecting an iron containing metal from corrosion is also provided that includes exposing the metal to the solution. The corrosion of the metal over time is monitored to assure the protection of the metal.

A surface treatment agent for metal material may include a compound (A) that is obtained by modifying a silicic acid (a) with a hydrolysate (b) of an epoxy group-having silane coupling agent, a silicic acid (B) represented by M.sub.2O.SiO.sub.2 (wherein a mass ratio of M.sub.2O to SiO.sub.2 is 0.1 to 1 and M represents an alkali metal), and water. A mass ratio (B/A) of the silicic acid (B) to the compound (A) is 1.1 to 17.9.

A surface treatment agent for metal material may include a compound (A) that is obtained by modifying a silicic acid (a) with a hydrolysate (b) of an epoxy group-having silane coupling agent, a silicic acid (B) represented by M.sub.2O.SiO.sub.2 (wherein a mass ratio of M.sub.2O to SiO.sub.2 is 0.1 to 1 and M represents an alkali metal), and water. A mass ratio (B/A) of the silicic acid (B) to the compound (A) is 1.1 to 17.9.

This disclosure relates to hydrophobic metal phosphate ceramic comprising a Group IV element of silicon, germanium, tin, or lead having at least one hydrocarbon covalently bonded thereto. Methods of providing water proofing and/or anti-corrosion protection are provided.