The modern material assemblies require the combined use of alloys for a given commercial application. Welding technologies are of critical importance for the construction of virtually all components of the assemblies. This course aims to elaborate the physical principles of arc, plasma, laser, resistance spot, electron beam and solid state welding processes. This includes, physics of electric arc-plasma, engineering the arc-plasma for welding, metal transfer and mass flow in the weld pool, laser/electron beam - material interactions, pressure and force balance in keyhole mode power beam welding, fundamentals of heat generation by Joule heating and process principles and overview on types of resistance and solid state welding processes.
INTENDED AUDIENCE: Masters students in Metallurgical, Mechanical, Automobile and Production Engineering. Practicing welding engineers, welders, R&D personnel in academia and national laboratories, quality management personnel from welding and manufacturing industries and research scholars who are working in welding and joining.
CORE/ELECTIVE: Core
UG/PG: PG
PREREQUISITES: Graduates of Metallurgical/Mechanical/Automobile/Production Engineering
INDUSTRY SUPPORT: Construction, Fabrication, Automobile and Power generation industries and research labs
1094 students have enrolled already!!
ABOUT THE INSTRUCTOR:
Instructor is currently working as an Assistant Professor in IIT-Madras. His research and teaching interests include welding metallurgy, welding processes development, steel product development and additive manufacturing.
COURSE LAYOUT:
Week 1 : Introduction to the course, learning outcomes, general survey and classification of welding processes, Conventional fusion welding processes, Principal heat sources Week 2 : Physics of welding arc – Part IGeneral characteristics of an arc, ionisation, dissociation, arc column, anode and cathode fall zones. Week 3 : Physics of welding arc – Part IIElectrical conductivity of the arc, heat transfer inside the arc and arc ignition. Week 4 : Introduction to arc welding processes – Part I Principles of gas tungsten arc welding, plasma arc welding, advances in gas tungsten arc welding Week 5 : Electrical power sources for welding - General characteristics, conventional and electronic power regulator systems - Tapped transformers, Moving-iron control, Variable inductor, Magnetic amplifier, SCR phase control, Transistor series regulator, Secondary switched transistor power supplies, Primary rectifier-inverter, hybrid designs and microprocessor controlled power sources. Week 6 : Introduction to arc welding processes – Part II Gas metal arc, shielded metal arc, flux cored arc, submerged arc welding -consideration of shielding gases, electrode polarity, current setting, types of metal transfer, process efficiency, melting rate, spatter losses and influence of external magnetic field on arc stability and Advanced GMAW processes. Electrode coverings and their functions, types of fluxes, Week 7 : Fundamentals of resistance welding – Part IProcess principles and overview on types of processes (spot, projection, butt, seam, and flash) Joule effect and temperature distribution. Week 8 : Fundamentals of resistance welding – Part IIProcess application range and typical problems (welding thin to thick material, welding of coated/ painted materials, welding dissimilar materials,mass effect, shunt effect, Peltier effect, resistance brazing. Week 9 : Introduction to power beam welding processesPlasma, laser and electron beam welding processes - principles and modes of operation, applications and advantages. Week 10 : Principles of power beam welding processes Keyhole formation, power densities, forces acting in keyhole, pressure balance for a generalised keyhole, heat transfer in laser and electron beam welding processes. Week 11 : Introduction to pressure welding processes - solid state bonding, friction welding, friction stir welding, ultrasonic welding, explosive welding, diffusion bonding and adhesive bonding. Week 12 : Principles and operational considerations of pressure welding processes
SUGGESTED READING MATERIALS:
Advanced welding processes by John Norrish, ISBN: 978-1-84569-130-1. 2. Principles of Welding by Robert W. Messler Jr., ISBN: 978-0-471-25376-13. Welding Technology by G. den Ouden and M. Hermans, ISBN: 978-90-6562-205-1. 4. The Physics of Welding, J.F. Lancaster, ISBN: 0-08-034076.
CERTIFICATION EXAM :
The exam is optional for a fee.
Date and Time of Exams: April 27 2019(Saturday). Morning session 9am to 12 noon; Afternoon Session 2pm to 5pm.
Registration url: Announcements will be made when the registration form is open for registrations.
The online registration form has to be filled and the certification exam fee needs to be paid. More details will be made available when the exam registration form is published.
CERTIFICATION:
Final score will be calculated as : 25% assignment score + 75% final exam score
25% assignment score is calculated as 25% of average of Best 8 out of 12 assignments
E-Certificate will be given to those who register and write the exam and score greater than or equal to 40% final score. Certificate will have your name, photograph and the score in the final exam with the breakup.It will have the logos of NPTEL and IIT Madras.It will be e-verifiable at nptel.ac.in/noc.