Effects of Heat Treatment Process on Mechanical Properties of Medium Carbon Steel

Date Received: Oct 27, 2020

Date Published: Dec 31, 2021

Views

1935

Download

344

Section:

ENGINEERING AND TECHNOLOGY

How to Cite:

Hang, P. (2021). Effects of Heat Treatment Process on Mechanical Properties of Medium Carbon Steel. Vietnam Journal of Agricultural Sciences, 4(4), 1283–1292. https://doi.org/10.31817/vjas.2021.4.4.07

Effects of Heat Treatment Process on Mechanical Properties of Medium Carbon Steel

Pham Thi Hang (*) 1

  • Corresponding author: pthang@vnua.edu.vn
  • 1 Faculty of Engineering, Vietnam National University of Agriculture
  • Keywords

    Hardness, heat treatment, mechanical properties, microstructure, S45C steel

    Abstract


    In order to select an appropriate heat treatment process for an industrial application of S45C medium carbon steel, it is necessary to investigate the influence of technological parameters during the heat treatment process such as heating temperature, holding time and cooling medium on the microstructure and mechanical properties. In this study, the experiments were conducted in various heating temperatures, holding times and cooling mediums for specimens made of S45C steel. Then, the relationship between the microstructure and the hardness of the steel was examined. The obtained results show that the heating temperature and cooling medium strongly affect the microstructure of this steel, leading to considerable changes in the hardness. The hardness of S45C steel was markedly improved when heated above 800oC and cooled in water. Moreover, the holding time needs to be carefully calculated to obtain finer grain structure to prevent an increase in the brittleness.

    References

    Adeyemi T. M. B. & Adedayo S. M. (2009). Vegetable oils as quenchants for hardening medium carbon steel. Journal of Applied Science and Technology. 14: 74-78.

    Bansal G. K., Rajinikanth V., Ghosh C., Srivastava V. C., Dutta M. & Chowdhury S. G. (2020). Effect of cooling rate on the evolution of microstructure and mechanical properties of nonisothermally partitioned steels. Materials Science & Engineering A. 788(24): 139614.

    Bhosale A., Shinde R. S. & Farane B. (2016). To Study the Heat Transfer Characteristics of AISI 1045 Steel Component for Quenching Process. International Engineering Research Journal. Special issue. 216-222.

    Bouissa Y., Shahriari D., Champliaud H. & Jahazi M. (2019). Prediction of heat transfer coefficient during quenching of large size forged blocks using modeling and experimental validation. Case Studies in Thermal Engineering. 13: 100379-100391.

    Callister Jr. W. D. & Rethwisch D. G. (2007). Materials Science and Engineering: An Introduction, seventh ed., John Wiley & Sons, Inc., New York: 975.

    Canale L. C. F., Mesquita R. A. & Totten G. E. (2008). Failure Analysis of Heat Treated Steel Components. first ed., ASM International, Ohio: 636.

    Fadare D. A., Fadara T. G. & Akanbi O. Y. (2011). Effect of heat treatment on mechanical properties and microstructure of NST 37-2 steel, Journal of Minerals & Materials Characterization & Engineering. 10: 299-308.

    Hajek J., Dlouha Z. & Prucha V. (2021). Comparison of industrial quenching oils. Metals. 11: 250-261.

    Ibrahim A. & Sayuti M. (2015). Effect of heat treatment on hardness and microstructures of AISI 1045. Advanced Materials Research. 1119: 575-579.

    Johnson O. T., Ogunmuyiwa E. N., Udec A. U., Gwangwava N. & Tenkorang R. A. (2019). Mechanical properties of heat-treated medium carbon steel in renewable and biodegradable oil. Procedia Manufacturing. 35: 229-235.

    Jo H., Kang M., Park G. W., Kim B. J., Choi C. Y., Park H. S., Shin S., Lee W., Ahn Y. S. & Jeon J. B. (2020). Effects of cooling rate during quenching and tempering conditions on microstructures and mechanical properties of carbon steel flange. Materials. 13(18): 4186.

    Liu P., Wang Y. Y., Li J., Lu C., Quek K. P. & Liu G. R. (2003). Parametric study of a sprocket system during heat-treatment process. Finite Elements in Analysis and Design. 40: 25-40.

    Long N. N. P., Ngon D. T., Cuong L. C. & Phoi N. V. (2018). Solution for heat treatment in quenching process of S45C steel small diameter machine parts having strong texture. The 4th International Conference on Green Technology and Sustainable Development (GTSD): 241-245.

    Mathews N. G., Pranesh Rao K. M., Nayak U. V. & Prabhu K. N. (2019). Comparison of cooling behaviour of carbon steels in polymer, oil and carbonated quench media. Transactions of the Indian Institute of Metals. 72: 1405-1408.

    Odusote J. K., Rabiu A. B. & Ajiboye T. K. (2012). Evaluation of mechanical properties of medium carbon steel quenched in Æ°ater and oil. Journal of Minerals and Materials Characterization and Engineering. 11(09): 218-224.

    Schindler I., Janosec M., Mistecky E., Ruzicka M., Cizek L., Dobrzanski L. A., Rusz S. & Suchanek P. (2009). Effect of cold rolling and annealing on mechanical properties of HSLA Steel. International Scientific Journal. 36(1): 41-47.

    Sun H., Wang Y., Wang Z., Liu N., Peng Y., Zhao X., Ren R. & Zhang H. (2020). Twinned substructure in lath martensite of water quenched Fe-0.2 %C and Fe-0.8 %C steels. Journal of Materials Science & Technology. 49(15): 126-132.

    Uyama H., Nakashima M., Morishige K., Mine Y. & Murakami Y. (2006). Effects of hydrogen charge on microscopic fatigue behaviour of annealed carbon

    steels. Fatigue & Fracture Engineering Materials & Structure. 29: 1066-1074.

    Yoo Y. T., Ahn D. G., Ro K. B., Song S. W., Shin H. J. & Im K. (2004). Welding characteristics of S45C medium carbon steel in laser welding process using a high power CW Nd: YAG laser. Journal of Materials Science. 39: 6117-6119.