Microstructure and Performance of Fe-Based Composite Clad Layer Fabricateded by Submerged-Arc Welding Added Alloy Powder

Li Mei Wang; Jun Bo Liu; Chi Yuan

doi:10.4028/www.scientific.net/MSF.704-705.752

Paper Titles

Numerical Simulation of Weld Metal by Ultra-Narrow Gap Arc Welding
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A Study of Numerical Modelling of Liquid Filler Flow within Braze Gap on Vacuum Brazing
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Finite Element Analysis of Transient Welding Stress and Strain during Ti-6Al-4V Thin Plate Welding with Impact Rotation
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Study on Fast-Convert Ultrasonic Frequency Pulse TIG Welding Arc Characteristic
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Microstructure and Performance of Fe-Based Composite Clad Layer Fabricateded by Submerged-Arc Welding Added Alloy Powder
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Study on the Ball Joint Sealing of Aluminium Control Arms
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Virtual Optimization of Regulating and Controlling on Welding Residual Stress of Francis Turbine Runner
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The Effect of Hybrid Ultrasonic Pulse Current Parameters on VPTIG Arc Pressure and Weld Formation
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Predication of Wettability of Sn Droplet on Copper Plate by MEAM Method
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Microstructure and Performance of Fe-Based Composite Clad Layer Fabricateded by Submerged-Arc Welding Added Alloy Powder

Abstract:

TiC particle reinforced Fe-based composite clad layer were in situ synthesized on surface of Q235 steel by Submerged arc Welding of the mixed powder of ferrotitanium, iron, chromium, nickel and colloidal graphite, etc. Microstructure of the clad layer were observed by scanning electron microscope （SEM） and Energy Disperse Spectroscopy (EDS). Wear resistance of the clad layer was tested on wear tester at room temperature compared with the base material Q235 steel. Microhardness of the clad layer was measured by microhardness tester. Results indicated that the fine TiC particles were formed by Submerged-arc Welding process, and the the TiC particles were dispersed in the matrix. The size of TiC particles was less than 2 μm. The microstructure of cladding layer consisted of TiC particles, martensite and austenite. The average microhardness of clad layer was HV_0.2601, which was about 3 times as high as the based metal Q235. On the conditions of same wear and room temperature, the weight loss of the base material Q235 is 10-15 times as much as the composite clad layer. The weight loss increase of the clad layer has a little change with the increase of load and the change of load is not sensitive to the weight loss of the clad layer. The clad layer has good load characteristics.