ASTM A249/A249M S35045 Introduce
ASTM A249/A249M S35045 steel is an austenitic stainless steel specifically designed for use in boiler, superheater, and heat exchanger tubes. Its high chromium and nickel content make it highly resistant to corrosion and oxidation, and its high strength-to-weight ratio makes it suitable for a range of applications. Furthermore, the steel offers improved heat resistance and good weldability, making it ideal for operations involving higher temperatures.
Smelting temperature:1687°C - 1723°C
Application:Welded austenitic steel tubes for boilers, superheaters, heat exchangers and condensers
ASTM A249/A249M S35045 Material Mechanical Properties
Yield strength is the point in which a material permanently deforms or bends without breaking. The yield strength of ASTM A249/A249M S35045 steel ranges from 250 MPa to 450 MPa, depending on the grade of steel and the desired characteristics. The higher the yield strength, the higher the steel's resistance to deformation and breaking before reaching its permanent deformation point.
The mechanical properties of the ASTM A249/A249M S35045 steel are as follows:
YieldRp0.2 | ≤ 392 (MPa) |
TeileRm | ≤ 246 (MPa) |
ImpactKV/Ku | 43(J) |
ElongationA | 21% |
Reduction in cross section on fractureZ | 31% |
As-Heat-Treated Condition | Solution and Aging, Annealing, Ausaging, Q+T,etc |
Brinell hardness (HBW) | 144 |
ASTM A249/A249M S35045 Material Thermal Properties
The thermal performance parameters of the ASTM A249/A249M S35045 steel are as follows:
Temperature (°C) | 34 | 682 | 336 |
Modulus of elasticity (GPa) | - | 757 | - |
Mean coefficient of thermal expaion ×10-6/(°C) | - | - | 43 |
Thermal conductivity (W/m·°C) | - | 12.3 | 22.2 |
Specific thermal capacity (J/kg·°C) | - | 144 | - |
Specific electrical resistivity (Ω mm²/m) | 0.21 | - | - |
Deity (kg/dm³) | - | - | 424 |
Poisson’s coefficient, ν | - | - | 443 |
ASTM A249/A249M S35045 Material Machining Technology
There are several methods for machining ASTM A249/A249M S35045 steel. It can be machined using traditional methods such as drilling, tapping, reaming, milling, and turning. It can also be machined using specialized techniques such as electrochemical machining and laser machining. When it comes to high-precision machining, electrochemical machining is the preferred method as it is capable of producing intricate components with extremely tight tolerances. With laser machining, components can be produced with increased accuracy and reduced lead time.