EFFECT OF WELDING ON THE IMPACT TOUGHNESS OF LOW CARBON STEEL

Authors

  • Jaimon D. Quadros Department of Mechanical Engineering, Birla Institute of Technology, Offshore campus, Ras-Al- Khaimah, UAE
  • Vilas Bhosle Department of Mechanical Engineering, Birla Institute of Technology, Offshore campus, Ras-Al- Khaimah, UAE
  • Singh R.P Department of Mechanical Engineering, Birla Institute of Technology, Offshore campus, Ras-Al- Khaimah, UAE
  • Vaishak N. L Department of Mechanical Engineering, Sahyadri College of Engineering and Management, Mangalore, India
  • Suhas Department of Mechanical Engineering, Sahyadri College of Engineering and Management, Mangalore, India

Keywords:

Welding, current, electrode diameter, Charpy impact test

Abstract

The present study examines the effect of welding parameters on impact toughness of welded low carbon steel samples. The welding parameters selected were welding current and welding electrode diameter. The welding operation was conducted on low carbon mild steel specimens. The welding currents used for welding the specimen were 95, 110 and 125 Amps and the electrode diameters used were 2.5 mm, 3.2 mm and 4 mm respectively. The specimens were welded at the junction of the 450V-notch primarily to facilitate Charpy impact test rig for determining impact toughness. The results showed that, an increase in the welding current results in increase in the impact toughness of the weld. Moreover, impact toughness of the welded specimen also increased as the electrode diameter increased from 2.5 mm to 3.2 mm, however decreased for further increase of 4mm. This is mainly due to residual stresses in welded joint that primarily develops due to differential weld thermal cycle (heating, peak temperature and cooling at the any moment during welding) experienced by the weld metal and region close to fusion boundary i.e. heat affected zone.

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References

Quadros J D, Vaishak N , and Suhas (2016), “Influence of Burr Height and Surface Roughness in Drilling Low Alloy Steels for different drill-point angles using Design of Experiments and Artificial Neural Network”, International Journal of Materials Engineering and Technology, Vol. 15, 109-133.

Kulekci M K (2008), “Magnesium and its Alloys Applications in Automotive Industry”, International Journal of Advanced Manufacturing Technology, Vol. 39, 851–865.

Munitz C, Cotler A, Stern and Kohn G (2001), “Mechanical Properties and Microstructure of Gas Tungsten Arc Welded Magnesium AZ91D Plates”, Material Science Engineering A, Vol. 302, 68–73.

Kou S, “Welding Metallurgy”, 2nd Edition, John Wiley& Sons, Inc., Hoboken, New Jersey, 17-20.

Muthupandi V, Srinivasan P, Bala S K and Sundaresan S (2003), “Effect of Weld Metal Chemistry and Heat Input on the Structure and Properties of Duplex Stainless Steel Welds”, Material Science Engineering A, Vol. 358, 9-16.

Yan J, Goa M, and Zeng X (2010), “Study on Microstructure and Mechanical Properties of 304 Stainless Steel Joints by TIG, Laser and Laser-TIG Hybrid Welding”, Optical Lasers Engineering, Vol. 4, 512-517.

Monika K, Bala M C, Nanda P K, and Prahalada KR (2013), “Effect of Heat Input on the Mechanical Properties of MIG Welded Dissimilar Joints”, International Journal of Engineering Research and Technology, Vol. 2, 1406-1413.

Ueji R, Fujii H, Cui L, Nishiokioka A, Kunishige K and Nogi K (2006), “Friction Stir Welding of Ultrafine Grained Plain Low- Carbon Steel Formed by the Martensite Process”, Material Science Engineering A, Vol. 423, 324-330.

Afolabi A S (2008), “Effect of electric arc welding parameters on corrosion behaviour of austenitic stainless steel in chloride medium”, AU Journal of Technology, Vol. 11, 171-180.

Marashi P, Pouranvari M, Amirabdollahian S and Abedi G (2008), “Microstructure and Failure Behavior of Dissimilar Metal Spot Welds between Low Carbon Steel, Galvanized and Austenistic Stainless Steels”, Material Science Engineering A, Vol. 420, 175-180.

Quadros J D, Vaishak N L and Suhas (2017), “Evaluation of Mechanical Properties of Aluminium Alloy 7075 Reinforced with Short Coated Carbon Metal Matrix Composites”, American Journal of Materials Science, Vol. 7, 102-107.

Vas J S, Fernandes A, D’Souza A, Rai A and Quadros J D (2017), “Analysis of Temperature Changes during Dry Drilling of Austenitic Stainless Steels on Twist Drills Having Different Point Angles”, Journal of Mechanical Engineering and Automation, Vol. 6, 121-125.

Suhas, Quadros J D and N L. Vaishak (2016),“Evaluation and Characterization of Tensile Properties of Short Coated Carbon Fiber Reinforced Aluminium 7075 Alloy Metal Matrix Composites via Liquid Stir Casting Method”, Material Science Research India, Vol. 13, 66-73.

Kotecki D J (1996) “Dilution control in single wire stainless steel submerged arc cladding”, Welding Journal, Vol. 75, 35-45.

Eroglu M and Aksoy M, (2006) “Effect of nickel on microstructure and mechanical properties of heat affected zone of low carbon steel”, Journal of Material Science Technology, Vol. 18, 35–40.

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Published

2018-12-01

How to Cite

[1]
“EFFECT OF WELDING ON THE IMPACT TOUGHNESS OF LOW CARBON STEEL”, JME, vol. 13, no. 4, pp. 194–198, Dec. 2018, Accessed: Nov. 21, 2024. [Online]. Available: https://smenec.org/index.php/1/article/view/133

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