Exploring friction stir welding for joining 316L steel pipes for industrial applications: Mechanical and metallurgical characterization of the joint and analysis of failure

•316L industrial grade steel pipes have been successfully joined by friction stir welding with PCBN coated tool.•Weld process parameters viz. spindle speed and welding speed significantly affect the properties and performance of FSW weldments in 316L pipes.•Influence of heat generation on metallurgi...

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Bibliographic Details
Published in:Engineering failure analysis 2023-08, Vol.150, p.107331, Article 107331
Main Authors: Gain, Suresh, Kalyan Das, Suman, Sanyal, Dipankar, Kumar Acharyya, Sanjib
Format: Article
Language:English
Subjects:
Austenitic steel
Circular welding
Defects
FSW
Microstructure
Pipe welding
Tensile strength
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Summary:•316L industrial grade steel pipes have been successfully joined by friction stir welding with PCBN coated tool.•Weld process parameters viz. spindle speed and welding speed significantly affect the properties and performance of FSW weldments in 316L pipes.•Influence of heat generation on metallurgical and mechanical properties of the weldments were investigated.•Excessive heat generation results in defects viz. void and porosity which make the joint weak and lead to failure of the weldments.•Optimum amount of heat generation during welding results in good quality weldments that displayed higher strength and hardness compared to base metal. Efficient welding of pipelines is critical for industries like power plants. Friction stir welding (FSW) has shown the ability to provide higher strength joints and is envisaged to be suitable for joining industrial pipelines as well. Hence, the present study assesses the application of FSW for joining 316L stainless steel industrial grade pipes. The welding is carried out by varying the process parameters, viz., spindle speed (rpm) and welding speed (mm/min), within a suitable range under force control mode. Microhardness and tensile tests have been conducted to evaluate the mechanical strength of the joints, whereas microstructure evaluation by optical microscopy (OM) and field emission scanning electron microscopy (FE-SEM) has been done in order to comprehend the mechanical performance of the weldments. It is found that both the selected welding process parameters (spindle speed and welding speed) have significant influence on the metallurgical and mechanical properties of the welded joints. High grain refinement due to dynamic recrystallization (DRX) in the stir zone results in enhanced hardness. At the optimal combination of parameters, i.e., 400 rpm spindle speed and 50 mm/min welding speed, the weld zone displays higher tensile strength than that of base metal. Also, at the same combination of parameters, stir zone of the welded samples displayed maximum hardness (255HV0.5kg). Some of the weldments displayed early failure during tensile tests. The present study also explains the cause of these failures. Optimum amount of heat generation during FSW process is key to achieving defect free good quality weldments.
ISSN:1350-6307
1873-1961
DOI:10.1016/j.engfailanal.2023.107331