TY - JOUR
T1 - Theoretical model for predicting the yield strength of metal materials under electrically-assisted deformation
AU - Yang, Jiabin
AU - Ma, Yanli
AU - Dong, Pan
AU - He, Yi
AU - Ma, Jianzuo
AU - Li, Weiguo
AU - Qu, Zhaoliang
N1 - Publisher Copyright:
© 2024 Elsevier Ltd
PY - 2025/3
Y1 - 2025/3
N2 - In this paper, based on the Force-Heat equivalence energy density principle, considering the thermal and athermal effects caused by current, the theoretical model for the current density dependent yield strength of metallic materials is developed. The novelty of this work lies in the fact that no adjustable fitting parameters were introduced during the modeling process, and both the Joule heating effect and the energy changes brought about by free electrons were considered in the contribution to the yield behavior of metallic materials, on which basis a critical energy density related to yield under the action of electric current was proposed. This model reveals the quantitative relationships between elastic modulus, steady-state temperature, electrical resistivity, thermal conductivity, current density, and yield strength under the action of current. The theoretical prediction results have achieved good consistency with experimental results. Furthermore, based on the principles of energy conservation and the assumption of steady-state, a theoretical expression was derived to predict the steady-state temperature caused by Joule heating. In addition, the results of the model analysis indicate that increasing the electrical resistivity of the material or decreasing its thermal conductivity can both facilitate plastic deformation and processing in electrically-assisted forming processes, especially at high current densities. This work provides an effective method for quantitatively evaluating the yield strength of metallic materials under the action of electric current, which can offer theoretical basis and optimization guidance for the extensive application and further development of electrically-assisted processes.
AB - In this paper, based on the Force-Heat equivalence energy density principle, considering the thermal and athermal effects caused by current, the theoretical model for the current density dependent yield strength of metallic materials is developed. The novelty of this work lies in the fact that no adjustable fitting parameters were introduced during the modeling process, and both the Joule heating effect and the energy changes brought about by free electrons were considered in the contribution to the yield behavior of metallic materials, on which basis a critical energy density related to yield under the action of electric current was proposed. This model reveals the quantitative relationships between elastic modulus, steady-state temperature, electrical resistivity, thermal conductivity, current density, and yield strength under the action of current. The theoretical prediction results have achieved good consistency with experimental results. Furthermore, based on the principles of energy conservation and the assumption of steady-state, a theoretical expression was derived to predict the steady-state temperature caused by Joule heating. In addition, the results of the model analysis indicate that increasing the electrical resistivity of the material or decreasing its thermal conductivity can both facilitate plastic deformation and processing in electrically-assisted forming processes, especially at high current densities. This work provides an effective method for quantitatively evaluating the yield strength of metallic materials under the action of electric current, which can offer theoretical basis and optimization guidance for the extensive application and further development of electrically-assisted processes.
KW - Current density
KW - Free electrons
KW - Joule heating
KW - Theoretical modeling
KW - Yield strength
UR - http://www.scopus.com/inward/record.url?scp=85210122094&partnerID=8YFLogxK
U2 - 10.1016/j.ijheatmasstransfer.2024.126496
DO - 10.1016/j.ijheatmasstransfer.2024.126496
M3 - Article
AN - SCOPUS:85210122094
SN - 0017-9310
VL - 238
JO - International Journal of Heat and Mass Transfer
JF - International Journal of Heat and Mass Transfer
M1 - 126496
ER -