M390 high carbon martensitic stainless steel and 304 austenitic stainless steel are joined by Tungsten Inert Gas arc welding (TIG) experiments in the manufacturing of high-end cutting tools. The mechanical properties and microstructure of the welded joint were characterized by tensile experiment, vickers microhardness test, Scanning Electron Microscope (SEM) and Energy Dispersive Spectrometer (EDS). Analysis of phase composition in each location using X-ray diffraction. The grain sizes in different areas on M390 side are measured and joining mechanism of the welded joint was revealed. The results show that: M390 high carbon martensitic stainless steel and 304 austenitic stainless steel TIG welding joints with beautiful weld appearance, no holes, no inclusions and other defects can be achieved. The best welding process parameters are welding current of 120 A, welding voltage of 16 V, welding speed of 3.3 mm/s, the corresponding tensile strength can reach 266 MPa. The weld metal is composed of martensitic、M,23,C,6, and M,7,C,3,. The grain size in weld metal is the largest, which can reach an average grain size of 17.96 μm. Because the weld metal matrix is martensitic, with the highest grain size, cleavage fracture occurs in the weld metal. The carbides in M390 side and weld metal are mainly (Cr, V) carbides. The carbide morphology gradually evolves from block shape to long strip shape from M390 base metal to the coarse-grained region.
关键词
M390高碳马氏体不锈钢TIG焊微观组织力学性能
Keywords
M390 high carbon martensitic stainless steelTIGmicrostructuremechanical properties
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