AISI 9262 Alloy Steel Chemical Composition, Grade, Tables and Pdf

AISI 9262 type alloy steel, alloy steel with silicon-manganese composition, is among alloy steels with perfect chemical composition designed for applications that require high performance. Its composition is made up of the like silicon metal, manganese, chromium, nickel, and carbon that are balanced in precision to the ones with the best strength by properties. This grade comes labeled with a quality indicator so it can be used for specific purposes too. AISI 9262 demonstrates that its properties include high strength, great toughness, as well as excellent resistance to fatigue therefore they can be employed for springs and similar components that are heavily loaded with cyclic stresses. Detailed chemical composition tables, chart and PDF documents, which explain what mechanical properties and grade specifications Titanium alloy has, are all invaluable resources engineers, manufacturers, and researchers seeking to master the usage of Titanium alloy in many industrial sectors.

AISI 9262 Alloy Steel Chemical Composition And Grade Table

AISI 9262 alloy steel, nickel-chromium-molybdenum type, is a famous low-alloy steel because of its high whipcrack and elevated fatigue strength. Most of it made up of the following in chemical construction: carbon (0.56-0.64%), manganese (0.75-1.00%), phosphorus (max 0.035%), sulfur (max 0.040%), silicon (0.15-0.35%), chromium (0.40-0. This steel alloy is famous for its superior capabilities like the autobody suspensions and other heavy duty applications such as industrial machine built parts. It meets the requirements of the ASTM A29 standard and is usually undergone heat treatment for enhanced mechanical properties.

AISI 9262 Alloy Steel Composition Table
Elements Si S P Mn Cr C Fe
Min (%) 1.8 - - 0.75 0.25 0.55 -
Max (%) 2.2 0.025 0.025 1 0.4 0.65 Balance

Advantages and Disadvantages of AISI 9262 Alloy Steel

    Advantages:

  • Fatigue Strength: Good fatigue strength, stable under fast alternating loads.

  • Hardness: Exhibits high hardness after heat treatment.

  • Toughness: Retains strength regardless of the hardness obtained.

  • Shock Resistance: Resistant to shock loads and impact forces.

    Disadvantages:

  • Complex Heat Treatment: Requires stringent heat-treatment procedures and techniques.

  • Machining Difficulty: Difficult to machine due to its hardness.

  • Corrosion Susceptibility: Prone to corrosion unless protected from corrosive elements.

  • Welding Challenges: Not easy to weld, requiring specific techniques and equipment.

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