How to cite this paper
Obiko, J., Mwema, F & Akinlabi, E. (2020). Strain rate-strain/stress relationship during isothermal forging: A Deform-3D FEM.Engineering Solid Mechanics, 8(1), 1-6.
Refrences
Christiansen, P., Martins, P. A. F., & Bay, N. (2016). Friction compensation in the upsetting of cylindrical test specimens. Experimental Mechanics, 56(7), 1271-1279.
Equbal, M. I., Talukdar, P., Kumar, V., & Ohdar, R. K. (2014). Deformation behavior of micro-alloyed steel by using thermo mechanical simulator and finite element method. Procedia Materials Science, 6, 674-681.
Evans, R. W., & Scharning, P. J. (2001). Axisymmetric compression test and hot working properties of alloys. Materials Science and Technology, 17(8), 995-1004.
Lee, Y. S., Lee, S. U., Van Tyne, C. J., Joo, B. D., & Moon, Y. H. (2011). Internal void closure during the forging of large cast ingots using a simulation approach. Journal of Materials Processing Technology, 211(6), 1136-1145.
Li, H. Z., Wang, H. J., Liang, X. P., Liu, H. T., Liu, Y., & Zhang, X. M. (2011). Hot deformation and processing map of 2519A aluminum alloy. Materials Science and Engineering: A, 528(3), 1548-1552.
Liu, M. P., Sun, S. C., Roven, H. J., Yu, Y. D., Zhang, Z., Murashkin, M., & Valiev, R. Z. (2012). Deformation defects and electron irradiation effect in nanostructured Al–Mg alloy processed by severe plastic deformation. Transactions of Nonferrous Metals Society of China, 22(8), 1810-1816.
Na, Y. S., Yeom, J. T., Park, N. K., & Lee, J. Y. (2003). Simulation of microstructures for Alloy 718 blade forging using 3D FEM simulator. Journal of Materials Processing Technology, 141(3), 337-342.
Obiko, J. O., Mwema, F. M., & Bodunrin, M. O. (2019). Finite element simulation of X20CrMoV121 steel billet forging process using the Deform 3D software. SN Applied Sciences, 1(9), 1044.
Rasti, J., Najafizadeh, A., & Meratian, M. (2011). Correcting the stress-strain curve in hot compression test using finite element analysis and Taguchi method. International Journal of Iron & Steel Society of Iran, 8(1), 26-33.
Shi, R. X., & Liu, Z. D. (2011). Hot deformation behavior of P92 steel used for ultra-Super-Critical power plants. Journal of Iron and Steel Research, International, 18(7), 53-58.
Wang, L., Liu, F., Cheng, J. J., Zuo, Q., & Chen, C. F. (2015). Hot deformation characteristics and processing map analysis for Nickel-based corrosion resistant alloy. Journal of Alloys and Compounds, 623, 69-78.
Yang, C. C., & Lin, X. Y. (2016). The forming analysis of two-stage extrusion for 1010 fastener. Journal of Mechanical Engineering and Automation, 6(3), 43-50.
Yang, Z., Zhang, F., Zheng, C., Zhang, M., Lv, B., & Qu, L. (2015). Study on hot deformation behaviour and processing maps of low carbon bainitic steel. Materials & Design (1980-2015), 66, 258-266.
Zaiemyekeh, Z., Liaghat, G. H., Ahmadi, H., Khan, M. K., & Razmkhah, O. (2019). Effect of strain rate on deformation behavior of aluminum matrix composites with Al2O3 nanoparticles. Materials Science and Engineering: A, 753, 276-284.
Zhang, Z. J., Dai, G. Z., Wu, S. N., Dong, L. X., & Liu, L. L. (2009). Simulation of 42CrMo steel billet upsetting and its defects analyses during forming process based on the software DEFORM-3D. Materials Science and Engineering: A, 499(1-2), 49-52.
Equbal, M. I., Talukdar, P., Kumar, V., & Ohdar, R. K. (2014). Deformation behavior of micro-alloyed steel by using thermo mechanical simulator and finite element method. Procedia Materials Science, 6, 674-681.
Evans, R. W., & Scharning, P. J. (2001). Axisymmetric compression test and hot working properties of alloys. Materials Science and Technology, 17(8), 995-1004.
Lee, Y. S., Lee, S. U., Van Tyne, C. J., Joo, B. D., & Moon, Y. H. (2011). Internal void closure during the forging of large cast ingots using a simulation approach. Journal of Materials Processing Technology, 211(6), 1136-1145.
Li, H. Z., Wang, H. J., Liang, X. P., Liu, H. T., Liu, Y., & Zhang, X. M. (2011). Hot deformation and processing map of 2519A aluminum alloy. Materials Science and Engineering: A, 528(3), 1548-1552.
Liu, M. P., Sun, S. C., Roven, H. J., Yu, Y. D., Zhang, Z., Murashkin, M., & Valiev, R. Z. (2012). Deformation defects and electron irradiation effect in nanostructured Al–Mg alloy processed by severe plastic deformation. Transactions of Nonferrous Metals Society of China, 22(8), 1810-1816.
Na, Y. S., Yeom, J. T., Park, N. K., & Lee, J. Y. (2003). Simulation of microstructures for Alloy 718 blade forging using 3D FEM simulator. Journal of Materials Processing Technology, 141(3), 337-342.
Obiko, J. O., Mwema, F. M., & Bodunrin, M. O. (2019). Finite element simulation of X20CrMoV121 steel billet forging process using the Deform 3D software. SN Applied Sciences, 1(9), 1044.
Rasti, J., Najafizadeh, A., & Meratian, M. (2011). Correcting the stress-strain curve in hot compression test using finite element analysis and Taguchi method. International Journal of Iron & Steel Society of Iran, 8(1), 26-33.
Shi, R. X., & Liu, Z. D. (2011). Hot deformation behavior of P92 steel used for ultra-Super-Critical power plants. Journal of Iron and Steel Research, International, 18(7), 53-58.
Wang, L., Liu, F., Cheng, J. J., Zuo, Q., & Chen, C. F. (2015). Hot deformation characteristics and processing map analysis for Nickel-based corrosion resistant alloy. Journal of Alloys and Compounds, 623, 69-78.
Yang, C. C., & Lin, X. Y. (2016). The forming analysis of two-stage extrusion for 1010 fastener. Journal of Mechanical Engineering and Automation, 6(3), 43-50.
Yang, Z., Zhang, F., Zheng, C., Zhang, M., Lv, B., & Qu, L. (2015). Study on hot deformation behaviour and processing maps of low carbon bainitic steel. Materials & Design (1980-2015), 66, 258-266.
Zaiemyekeh, Z., Liaghat, G. H., Ahmadi, H., Khan, M. K., & Razmkhah, O. (2019). Effect of strain rate on deformation behavior of aluminum matrix composites with Al2O3 nanoparticles. Materials Science and Engineering: A, 753, 276-284.
Zhang, Z. J., Dai, G. Z., Wu, S. N., Dong, L. X., & Liu, L. L. (2009). Simulation of 42CrMo steel billet upsetting and its defects analyses during forming process based on the software DEFORM-3D. Materials Science and Engineering: A, 499(1-2), 49-52.