1. National Institute of Technology Puducherry
Karaikal-609609
Department of Mechanical Engineering
Research Progress Meeting
Date : 17.11.2022
Supervisor Scholar
Dr. A. Karpagaraj, Name : Vinoth Kumar. D
Assistant Professor, Roll No : ME22D1006
Dept of Mechanical Engg. Mode : Full Time
2. Data Sheet
Name : Vinoth Kumar.D
Roll No : ME22D1006
Broad Area of Research : Welding
Category : Full Time ( Institute Fellowship)
Date of Registration : 25.07.2022
Date of last DC meeting : 05.09.2022
DOCTORAL COMMITTEE
Name of The Doctoral Committee Chairperson
Dr. JACK J KENNNED Assistant Professor
Department of Mechanical Engineering
National Institute of Technology Puducherry
Name of The Supervisor (Guide)
Dr. A. KARPAGARAJ, Assistant Professor,
Department of Mechanical Engineering
National Institute of Technology, Puducherry
Doctoral Committee Member(Internal)
Dr. N.M . SIVARAM, Assistant Professor,
Department of Mechanical Engineering
National Institute of Technology, Puducherry
Doctoral Committee Member(Internal)
Dr. JOHNNEY MERTENS, Assistant Professor,
Department of Mechanical Engineering
National Institute of Technology, Puducherry
Doctoral Committee Member(Allied Department)
Dr. RAJAN SINGARAVEL M.M, Assistant Professor,
Department of Electrical and Electronics Engineering
National Institute of Technology, Puducherry-609609
3. COURSE WORK
COURSE CODE COURSE NAME GRADES
ME 811 Materials and Metallurgy On Going
ME 823 Material Characterization Methods On Going
ME 831 Advanced Manufacturing Process Next Semester
ME 817 Fracture Mechanics Next Semester
4. Introduction
Dissimilar materials welding refers to the joining of:
Two different alloy systems (e.g., steel, stainless steel)
Materials of different fundamental types
Metals, ceramics, polymers, composite
Ferrous to non-ferrous
Materials with different compositions within a particular type (e.g., austenitic
stainless steel, ferritic stainless steel, duplex stainless steel, etc.).
Importance to industry:
Dissimilar lightweight material welding is used to connect different metals
together for automotive industries
Used where an object is subjected to multiple environments in one application
such as in chemical and petrochemical industries, power generation, and oil
and gas industries
5. Challenges of Welding Dissimilar Metals
The existence of a transition zone between the metals and the
intermetallic compounds formed in the heat affected zone:
If there is mutual solubility of the two metals, the dissimilar joints
can be made successfully
If there is little or no solubility between the two metals to be joined,
the weld joint will not be successful.
The formation of intermetallic compounds and their effects on:
Increasing the crack sensitivity
Reducing the ductility
Increasing the susceptibility to corrosion
6. Challenges of Welding Dissimilar Metals
Differences in the coefficient of thermal expansion:
The residual stresses in welds are generated by the thermal contraction of the
weld metal and the adjacent base metal. As a result, the residual stress
distribution and magnitude are not similar across the dissimilar weld joint
If these are widely different, there will be internal stresses set up in the inter-
critical HAZ leading to service failure.
The difference in melting temperatures, since one metal will be
molten and overheated before the other when subjected to the same
heat source.
The difference of the electrochemical potential could increase the
susceptibility to corrosion at HAZ. If they are far apart on the scale,
corrosion can be a serious problem.
10. Weldability of Metals and Alloys
• Weldability of carbon steel alloys is inversely proportional to its
hardenability due to martensite formation.
• Austenitic stainless steels tend to be the most weldable, but suffer from
distortion due to high thermal expansion leading to cracking and reduced
corrosion resistance.
• Ferritic and martensitic stainless steels are not easily welded, often to be
preheated and use special electrodes.
• Aluminum alloys are susceptible to hot cracking, oxide inclusions, dross,
and porosity (hydrogen).
• Titanium alloys with low amounts of alloying elements are more readily
welded, while highly stabilized β titanium alloys are difficult to weld due to
segregation.
11. References
• Tauheed Shehbaz, Fahd Nawaz Khan, Massab Junaid, Julfikar Haider
Investigating the bonding mechanism of P-TIG welded CpTi/Inconel
718 dissimilar joint with Nb interlayer Materials Letters 313 (2022)
131748
• Sanjeev Kumar, Chandan Pandey, Amit Goyal Microstructure and
mechanical behavior of P91 steel dissimilar welded joints made with
IN718 filler International Journal of Pressure Vessels and Piping 190
(2021) 104290
• Yanan Gao, Lujun Huang, Yang Bao, Qi An, Yuan Sun, Rui Zhang,
Lin Geng, Jie Zhang Joints of TiBw/Ti6Al4V composites- Inconel 718
alloys dissimilar joining using Nb and Cu interlayers Journal of Alloys
and Compounds 822 (2020) 153559
12. • Sidharth Deva, K. Devendranath Ramkumar, N. Arivazhagan, R.
Rajendran Investigations on the microstructure and mechanical
properties of dissimilar welds of inconel 718 and sulphur rich
martensitic stainless steel, AISI 416 Journal of Manufacturing
Processes 32 (2018) 685–698
• Fatemeh Hejripour, Daryush K. Aidun Consumable selection for arc
welding between Stainless Steel 410 and Inconel 718 Journal of
Materials Processing Technology 245 (2017) 287–299
• Sanjeev Kumar, Chandan Pandey, Amit Goyal Microstructure and
mechanical behavior of P91 steel dissimilar welded joints made with
IN718 filler International Journal of Pressure Vessels and Piping 190
(2021) 104290