摘要:
A brazing sheet of aluminum alloy composed of a core material and a first brazing filler metal covering one surface of the core material. The core material contains as an essential component 0.2-1.0 mass % of Cu and as optional components at least one species of no more than 1.5 mass % of Si, no more than 1.8 mass % of Mn, no more than 0.35 mass % of Ti, and no more than 0.5 mass % of Mg, with the remainder being Al and inevitable impurities. The first brazing filler metal has a liquid phase ratio (X %) at 600° C. and a thickness (Y μm) such that X and Y satisfy the following relationship: (1) 30≦X≦80, (2) Y≧25, and (3) 1000≦X×Y≦24000. The brazing sheet provides good brazeability and maintains high corrosion resistance after brazing on the surface cladded with the brazing filler metal.
摘要:
A brazing sheet of aluminum alloy composed of a core material and a first brazing filler metal covering one surface of the core material. The core material contains as an essential component 0.2-1.0 mass % of Cu and as optional components at least one species of no more than 1.5 mass % of Si, no more than 1.8 mass % of Mn, no more than 0.35 mass % of Ti, and no more than 0.5 mass % of Mg, with the remainder being Al and inevitable impurities. The first brazing filler metal has a liquid phase ratio (X %) at 600° C. and a thickness (Y μm) such that X and Y satisfy the following relationship: (1) 30≦X≦80, (2) Y≧25, and (3) 1000≦X×Y≦24000. The brazing sheet provides good brazeability and maintains high corrosion resistance after brazing on the surface cladded with the brazing filler metal.
摘要:
Disclosed is an aluminum alloy brazing sheet (1) for heat exchangers, the brazing sheet provided with a core material (2) and a filler material (3) that comprises an Al—Si—Zn alloy and is formed on at least one side of the core material (2). The core material (2) has a pitting potential of −650 mV or more (vs. Ag/AgCl). The filler material (3) has a zinc concentration of from 1 to 10 percent by mass; a liquid fraction X, at the brazing temperature, satisfying the relation 0.3≦X≦0.88; and a clad ratio d (%) satisfying the relation 15
摘要:
Disclosed is an aluminum alloy brazing sheet (1) for heat exchangers, the brazing sheet provided with a core material (2) and a filler material (3) that comprises an Al—Si—Zn alloy and is formed on at least one side of the core material (2). The core material (2) has a pitting potential of −650 mV or more (vs. Ag/AgCl). The filler material (3) has a zinc concentration of from 1 to 10 percent by mass; a liquid fraction X, at the brazing temperature, satisfying the relation 0.3≦X≦0.88; and a clad ratio d (%) satisfying the relation 15
摘要:
The present invention provides an aluminum alloy material which is used as a core material for an aluminum alloy brazing sheet and has superior strength at a high temperature. The aluminum alloy material of the present invention is used as a core material C1 for an aluminum alloy brazing sheet B31 (or B32) which has a filler alloy F formed on at least one side of the core material C1. The aluminum alloy material contains more than 2.5% by mass and 3.5% by mass or less of Cu, and the balance being made of aluminum and unavoidable impurities.
摘要:
A titanium alloy material includes a Ti—Al alloy and an oxide film on the Ti—Al alloy. The Ti—Al alloy contains 0.50-3.0 mass % Al and a balance of Ti and unavoidable impurities. The titanium alloy material has excellent hydrogen absorption resistance and can be used as a basic structural material in hydrogen absorption environments.
摘要:
An amorphous carbon (DLC) film having excellent adhesion at high temperature is provided. An amorphous-carbon-based hard multilayer film, which is formed on a surface of a substrate, includes a base layer formed at a substrate side, a surface layer formed at a surface side, and a compositional gradient layer formed between the base layer and the surface layer, wherein the base layer includes a nitride or a carbo-nitride of an element M expressed by the following formula (1), the surface layer includes an amorphous carbon film containing C of 50 atomic percent or more, and the compositional gradient layer is a layer in which the element M and nitrogen are decreased, and carbon is increased from the base layer to the amorphous carbon film: M1-x-yCxNy (1), (wherein M is at least one selected from a group 4A element in the periodic table, a group 5A element, a group 6A element, Al, and Si, and x and y denote atomic ratios in the formula, and x is 0.5 or less, y is 0.03 or more, and 1-x-y is more then 0).
摘要:
An amorphous carbon (DLC) film having excellent adhesion at high temperature is provided. An amorphous-carbon-based hard multilayer film, which is formed on a surface of a substrate, includes a base layer formed at a substrate side, a surface layer formed at a surface side, and a compositional gradient layer formed between the base layer and the surface layer, wherein the base layer includes a nitride or a carbo-nitride of an element M expressed by the following formula (1), the surface layer includes an amorphous carbon film containing C of 50 atomic percent or more, and the compositional gradient layer is a layer in which the element M and nitrogen are decreased, and carbon is increased from the base layer to the amorphous carbon film: M1-x-yCxNy , (1) (wherein M is at least one selected from a group 4A element in the periodic table, a group 5A element, a group 6A element, Al, and Si, and x and y denote atomic ratios in the formula, and x is 0.5 or less, y is 0.03 or more, and 1-x-y is more then 0).
摘要:
A titanium alloy scarcely undergoing brittling caused by hydrogen even in case of being used under hydrogen-absorbing conditions. This alloy comprises a Ti—Al alloy composed of from 0.50 to 3.0% of Al with the balance of Ti together with unavoidable contaminants. A Ti—Al alloy material excellent in hydrogen absorption-resistance wherein an oxidized film of 1.0 to 100 nm in thickness is formed on a bulk made of a Ti—Al alloy satisfying the chemical composition as described above, and, further, a concentrated Al layer having an Al concentration of 0.8 to 25% higher by 0.3% or more than the bulk is optionally formed between the bulk and the oxidized film.