Effect of the Cooling Condition and Corresponding Microstructure on Tensile and Impact Behaviour of Low Carbon Steel (EN8)
Authors
-
Department of Mechanical Engineering, Ramaiah Institute of Technology, MSR Nagar, MSRIT Post Bengaluru, Karnataka 560054 ,IN
P. Rajendra -
Department of Mechanical Engineering, Ramaiah Institute of Technology, MSR Nagar, MSRIT Post Bengaluru, Karnataka 560054 ,INK. R. Phaneesh
-
Department of Mechanical Engineering, Ramaiah Institute of Technology, MSR Nagar, MSRIT Post Bengaluru, Karnataka 560054 ,INC. M. Ramesha
-
Aircraft Research and Design Centre HAL, Bengaluru, Karnataka 560037 ,INMadev Nagaral
-
Department of Mechanical Engineering, Siddaganga Institute of Technology, Tumkur, Karnataka 572103 ,INV. Auradi
DOI:
https://doi.org/10.18311/jmmf/2023/33356Keywords:
Heat Treatment, Critical cooling Temperature, cooling medium, and Microstructure ExaminationAbstract
Steels benefit significantly from the heat treatment and quenching procedure because it modifies mechanical characteristics and affects phase change in the structure. To test EN8 steels, we execute this heat treatment procedure in a variety of quenching media. A few EN8 steel specimens were investigated and evaluated after being heated in the resistance furnace between 760°C and 950°C and then quenched in a different media. As diverse quenching mediums, oil, water, and air are employed. Mechanical characteristics such as hardness using Vickers hardness equipment and the quenched samples hardness were substantially more prominent than the base material. Followed by Charpy impact test is carried out on the samples according to ASTM E-23 and the Vickers hardness test according to ASTM-E92. In the present work, medium carbon steel (EN8) was used, and its composition is shown in the table below. The samples are prepared in 20mm cylindrical bars, which were then machined to final dimensions of 10x10x75 mm3 on a lathe as per the ASTM-E23 and v - cut notch of 2 mm depth the center for impact testing. Tensile testing was conducted using an ASTM-E2 compliant servo-hydraulic machine with a 100 kN load cell. A clip-on extensometer and the result recorded for ultimate tensile strength, increase with fine grains.
Downloads
Metrics
Downloads
Published
How to Cite
Issue
Section
License
This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
References
Akeel, N., Kumar, V. and Zaroog, O. S. (2021): Impact of the Heat Treatment Process on the Properties of Stainless Steel Material. Solid State Technology, 64, 1461–1471.
Rashed, M. G., Ashraf, M., Mines, R. A. W. and Hazell, P. J. (2016): Metallic microlattice materials: A currentstate of the art on manufacturing, mechanical properties and applications. Materials & Design, 95, 518-533.
ASM International. Handbook Committee. (1990): Properties and Selection– Irons, Steels, and Highperformance Alloys, ASM International, 1, 1-603
Clarke, T. M. (1997): Upgrading the Bausch & Lomb Research I Metallography. Microscope-London Then Chicago, 45, 47-52.
Calcagnotto, M., Ponge, D. and Raabe, D. (2010): Effect of grain refinement to 1ìm on strength and toughness of dual-phase steels. Materials Science and Engineering: A, 527(29), 7832–7840.
Chandan, B. R., Pramod, V., Ramesha, C. M. and Sharanraj, V. (2017): Evaluation of Mechanical Properties of Medium Carbon Low Alloy Forged Steels by Polymer Quenching. IOP Conference Series: Materials Science and Engineering, 225, 012185.
Aweda, J. O., Orhadahwe, T. A. and Ohijeagbon, I. O. (2018). Rapid cyclic heating of mild steel and its effects on microstructure and mechanical properties. In IOP Conference Series: Materials Science and Engineering 413(1) 012016)
Zhang, C., Wang, Q., Ren, J., Li, R., Wang, M., Zhang, F. and Sun, K. (2012): Effect of martensitic morphology on mechanical properties of as-quenched and tempered 25CrMo48V steel. Materials Science and Engineering: A, 534, 339-346.
Tomita, Y. and Okabayashi, K. (1986): Effect of microstructure on strength and toughness of heattreated low alloy structural steels. Metallurgical Transactions A, 17(7), 1203-1209.
Hidalgo, J. and Santofimia, M. J. (2016): Effect of prior austenite grain size refinement by thermal cycling on the microstructural features of as-quenched lath martensite. Metallurgical and Materials Transactions A, 47(11), 5288-5301.
Shen, J., Li, Y., Li, F., Yang, H., Zhao, Z., Kano, S. and Abe, H. (2016): Microstructural characterization and strengthening mechanisms of 12Cr-ODS steel. Materials Science and Engineering: A, 673, 624-632.
Ohaeri, E., Omale, J., Rahman, K. M. and Szpunar, J. (2020): Effect of post-processing annealing treatments on microstructure development and hydrogen embrittlement in API 5L X70 pipeline steel. Materials Characterization, 161, 110124.
J. W. Morris, Jr., Lee, C. S. and Guo, Z. (2003). TheNature and Consequences of Coherent Transformations in Steel. ISIJ International, 43(3), 410–419.
Kim, H. J., Kim, Y. H. and J. W. Morris, Jr. (1998): Thermal Mechanisms of Grain and Packet Refinement in a Lath Martensitic Steel. ISIJ International, 38(11), 1277–1285.
Long, S., Liang, Y., Jiang, Y., Liang, Y., Yang, M. and Yi, Y. (2016): Effect of quenching temperature on martensite multi-level microstructures and properties of strength and toughness in 20CrNi2Mo steel. Materials Science and Engineering: A, 676, 38–47.
Momoh, I. M., Bamike, B. J., Saliu, A. M. and Adeyemi, O. A. (2015): Effects of Polyethylene Glycol on the Mechanical Properties of Medium Carbon Low Alloy Steel. Nigerian Journal of Technological Development, 12(2), 61–64.
Mosa, S. J. (2019): Effect of Different Quenching Media on Mechanical Properties of Aisi 1018 Low Carbon Steel. Journal of Mechanical Engineering Research & Developments (JMERD), 42(3), 81–83.
Najafkhani, F., Kheiri, S., Pourbahari, B. and Mirzadeh, H. (2021): Recent advances in the kinetics of normal/ abnormal grain growth: A review. Archives of Civil and Mechanical Engineering, 21(1), 29
Senthilkumar, T. and Ajiboye, T. K. (2012): Effect of Heat Treatment Processes on the Mechanical Properties of Medium Carbon Steel. Journal of Minerals and Materials Characterization and Engineering, 11(02), 143–152.
Singh, S., Samir, S., Kumar, K. and Thapa, S. (2021): Effect of heat treatment processes on the mechanical properties of AISI 1045 steel. Materials Today: Proceedings, 45, 5097–5101.
Lan, L. Y., Qiu, C. L., Zhao, D. W., Gao, X. H. and Du, L. X. (2011): Effect of austenite grain size on isothermal bainite transformation in low carbon microalloyed steel. Materials Science and Technology, 27(11), 1657- 1663.
Tomita, Y. and Okabayashi, K. (1986): Effect of microstructure on strength and toughness of heattreated low alloy structural steels. Metallurgical Transactions A, 17(7), 1203–1209.
Furuhara, T., Kikumoto, K., Saito, H., Sekine, T., Ogawa, T., Morito, S. and Maki, T. (2008): Phase transformation from fine-grained austenite. ISIJ International, 48(8), 1038-1045.
