Microstructure and tensile properties of AISI 410 stainless steel welded TIG method

Abstract

In this study, the microstructure and tensile properties of AISI 410 stainless steel were studied. TIG welding was carried out on steels by using welding wire ER 410 (AWS A5.9) 2.8 mm in diameter. The obtained results showed that while tensile and yield strength increased, the elongation value decreased significantly. The yield strength and tensile strength were measured as 619 and 801 MPa after welding process, respectively. On the other hand, the microstructure of weld metal region had a dual phase such as martensite and ferrite.

Keywords

• AISI 410 stainless steel
• tensile properties
• microstructure
• TIG
• failure

Kaynakça

1. [1] Mahato, J. R. Handbook for Mechanical Maintenance Engineers Paperback, IK International Publishing House, 2019.
2. [2] Wang, Y., Sebeck, K., Tess, M., Gingrich, E., Feng, Z., Haynes, J. A., Lance, M. J., Muralidharan, G., Marchel, R., Kirste, T. and Pierce, D., (2023). Interfacial microstructure and mechanical properties of rotary inertia friction welded dissimilar 422 martensitic stainless steel to 4140 low alloy steel joints. Materials Science and Engineering A 885; 145607.
3. [3] Digges, T. G. and Rosenberg, S. I. J., Heat Treatment and Properties of Iron and Steel, National Bureau of Standards Library, Washington, 1960.
4. [4] Loto, C. A., Fayomia, O. S. I. and Loto, R. T., (2015). Electrochemical corrosion resistance and inhibition behaviour of martensitic stainless steel in hydrochloric acid, Der Pharma Chemica, 7;102-111.
5. [5] M. K. Howlader, Cold-forming effect on stainless steel, PhD thesis, Czech Technical University, 2015.
6. [6] Saravanan, G., Rahul, V., Mahatme, Reddy, G. K., Sharon, T., Suresh, G., Karthikeyan, R. and Subbiah, R., (2023). Assessment of Wear Properties on Treated AISI 410 Martensitic Stainless Steel by Annealing Process, E3S Web of Conferences, 391; 01108.
7. [7] Al-Sayed, S. R., Hussein, A. A., Nofal,A. A., Hassab Elnaby, S. I. and Elgazzar, H., (2017). Characterization of a Laser Surface-Treated Martensitic Stainless Steel, Materials, 10; 595.
8. [8] Köse, C. and Topal, C., (2020). Lazer Kaynağı İle Birleştirilen AISI 410S Ferritik Paslanmaz Çeliğin Mikroyapı ve Mekanik Özelliklerine Gerilme Giderme Isıl İşleminin Etkileri, European Journal of Science and Technology, 20; 922-931.

9. [9] Muthusamy, C., Karuppiah, L., Paulrajc, S., Kandasamid, D. and Kandhasamy, R., (2016). Effect of Heat Input on Mechanical and Metallurgical Properties of Gas Tungsten Arc Welded Lean Super Martensitic Stainless Steel, Materials Research, 19; 572-579.
10. [10] Kim, S. K., Jung, S. B. and Lee, D. B., (2013). Characteristics of Microstructure, Micro hardness and Oxidation of FSW and MIG Welded Steels, Chiang Mai Journal of Science, 40; 831-838.
11. [11] Tutar, M., Aydin, H. and Bayram, A., (2017). Effect of Weld Current on the Microstructure and Mechanical Properties of a Resistance Spot-Welded TWIP Steel Sheet, Metals, 7; 519.
12. [12] Tolvanen, S., Influence of welding process and alloy composition on microstructure and properties, PhD thesis, Chalmers University of Techonology, Gothenburg, Sweden 2018.
13. [13] Tsai, M. C., Chiou, C. S., Du, J. S. and Yang, J. R., (2002). Phase transformation in AISI 410 stainless steel, Materials Science and Engineering A, 332;1-10.
14. [14] de Paula, M. A., Ribeiro, M. V., Souza, J. V. C. and Kondo, M. Y., (2019). Analysis of the performance of coated carbide cutting tools in the machining of martensitic stainless steel AISI 410 in dry and mql conditions, Materials Research Express, 6, 016512.
15. [15] Kumar, S. and Shahi, A. S., (2011). Effect of heat input on the microstructure and mechanical properties of gas tungsten arc welded AISI 304 stainless steel joints, Materials and Design, 32; 3617–3623.
16. [16] Lu, S. P., Qin, M. P. and Dong, W. C., (2013). Highly efficient TIG welding of Cr13Ni5Mo martensitic stainless steel, Journal of Materials Processing Technology, 213; 229-237.
17. [17] Bayrak, M. A., Onar, V. and Isıtan, A., (2018). The Investigation of Microstructure and Mechanical Properties of Austenitic Stainless Steel Joints Obtained by Different Welding Methods and Different Welding Parameters, ETSCI Conference Indexing System, 3; 324-327.
18. [18] Molak, R. M., Paradowski, K., Brynk, T., Ciupinski, L., Pakiel, Z. and Kurzydlowski, K. J., (2009). Measurement of mechanical properties in a 316L stainless steel welded joint, International Journal of Pressure Vessels and Piping, 86; 43–47.
19. [19] Akhatova, A., Robaut, F., Verdier, M., Yescas, M., Roch, F., Tassini, C and Van Landeghem, H. P., (2020). Microstructural and mechanical investigation of the near fusion boundary region in thermally aged 18MND5 / Alloy 52 narrow-gap dissimilar metal weld, Materials Science and Engineering: A, 788; 139592.
20. [20] Ata, F., Calik, A and Ucar, N., (2022). Investıgatıon on the mıcrostructure and mechanıcal propertıes of astm a131 steel manufactured by dıfferent weldıng methods, Advances ın materıals scıence, 22; 32-40.
21. [21] Tehçi, T., AISI 316 serisi ostenitik paslanmaz çeliklerde kaynak parametrelerinin nufuziyete ve mekanik özelliklere etkisi, Yüksek Lisans Tezi, Sakarya Üniversitesi, 2011.
22. [22] Rana, H., Badheka, V., Patel, P., Patel, V., Li, W. and Andersson, J., (2021). Augmentation of weld penetration by flux assisted TIG welding and its distinct variants for oxygen free copper, Journal of Materials Research and Technology, 10; 138-151.