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Alloy steel forgings are made by adding other alloying elements in addition to iron and carbon. A ferrocarbon alloy formed by adding an appropriate amount of one or more alloying elements on the basis of ordinary carbon steel. By adding different elements and adopting hot forgings techniques, special properties such as high strength, high toughness, wear resistance, corrosion resistance, low-temperature resistance, high-temperature resistance, and non-magnetic properties can be obtained.
After quenching and tempering, the alloy steel forgings have a combination of high strength, good plasticity and toughness, which means it has good comprehensive mechanical properties.
The forged alloy steel blanks have a carbon content is 0.3-0.5% with alloy elements mainly including Cr, Mn, Ti, Mo, etc., is mainly used to improve hardenability, refine grains, and prevent overheating.
Pre heat treatment is annealing or normalizing, and final heat treatment is quenching+ high-temperature tempering.
Forged alloy steel blanks are with various special properties such as high strength, high toughness, wear resistance, corrosion resistance, low temperature resistance, high temperature resistance, and non-magnetism. They have a wide range of applications, mainly including the following aspects:
Alloy steel forging is used to manufacture engine blocks, crankshafts, pistons, and various components of automobiles.
Alloy steel forging is used to manufacture gears, gear shafts, connecting rods and worm gears, etc.
Alloy steel forging is used to manufacture ship main shafts, large gears, sprockets, pistons, tubes etc.
Alloy steel forging is used to manufacture various valves, fittings, and containers, which can improve the reliability and service life of equipment.
In structural steel and tool steel, chromium can significantly improve strength, hardness, and wear resistance, but at the same time reduce plasticity and toughness. Chromium can also improve the oxidation resistance and corrosion resistance of steel, making it an important alloying element for stainless steel and heat-resistant steel.
Nickel can improve the strength of steel while maintaining good plasticity and toughness. Nickel has high corrosion resistance to acid and alkali, and has rust and heat resistance at high temperatures. However, as nickel is a relatively scarce resource, other alloying elements should be used instead of nickel chromium steel as much as possible.
Molybdenum can refine the grain size of steel, improve its hardenability and thermal strength, and maintain sufficient strength and creep resistance at high temperatures (deformation occurs due to long-term stress at high temperatures, known as creep). Adding molybdenum to structural steel can improve its mechanical properties. It can also suppress the brittleness of alloy steel caused by quenching. In tool steel, redness can be improved.
Vanadium is an excellent deoxidizer for steel. Adding 0.5% vanadium to steel can refine the grain structure, improve strength and toughness. The carbides formed by vanadium and carbon can improve their resistance to hydrogen corrosion under high temperature and pressure.