AISI 1035 Carbon Steel Chemical Properties, Grade, Tables and Pdf

AISI 1035 is a middle-carbon steel that exhibits very good welding and machining capabilities and also poses good strength properties. It consists of elemental carbon, manganese and others at a given ratio to meet the mechanical requirements. The extent of carbon content also places it in the category of medium carbon steel, which can range from 0.32% to 0.38%. The AISI 1035 is widely used in several industries where gear teeth, shafts, forgings, and other machinery components are needed. The chemical properties include the minimum of Phosphorus and Sulfur 0.050% per maximum. The standard hardeners from MOST are in 170 to 210 BHN range. Full tables, chart and PDF reports that provide all the information one needs about the specific features, grades, and applications of the material is found in wherever well known sources are lacking for later consultation.

AISI 1035 Carbon Steel Chemical Composition And Grade Table

The carbon steel AISI 1035 is a widely used medium carbon steel for its wide range of desirable physical properties including the high welding and machining qualities. It also offers good tensile strength level. Its chemical makeup has been observed as varying, including carbon, manganese, phosphorus, sulfur, and other small elements in tiny amount. As an average, it consists of carbon at a level of around 0.32-0.38%, manganese at 0.60-0.90%, the maximum of phosphorus at 0.2% and sulfur at 0.05%. The right intensity of heat, in AISI 1035, can achieve a wide array of mechanical properties, aiding different tasks. This stainless steel grade is typically employed in particular machines parts, such as shafts, gears, and other components that demand robustness and hardiness.

AISI 1035 Carbon Steel Composition Table
Elements Fe Mn C S P
Min (%) - 0.6 0.32 - -
Max (%) Balance 0.9 0.38 0.05 0.04

Advantages and Disadvantages of AISI 1035 Carbon Steel

    Advantages:

  • Heat Treatable: Can be heat treated to alter mechanical properties for specific applications.

  • Tensile Strength: Higher toughness and ductility compared to low carbon steels.

  • Good Ductility: Retains ductility despite having more carbon.

  • Versatile Use: Suitable for many industrial applications due to good stress corrosion cracking resistance.

    Disadvantages:

  • Corrosion Prone: Lacks rust resistance like other carbon steels.

  • Machining Difficulties: Less malleable and more difficult to machine than low carbon steel.

  • Brittleness: Can become brittle without proper heat treatment.

  • Fatigue Resistance: Moderate fatigue resistance, not suitable for highly demanding applications.

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