Yong Zang received his Master Degree in Metallurgical Machinery from Beijing Institute of Iron and Steel Engineering in 1989. Now he is a professor at the School of Mechanical Engineering, as well as a vice president in University of Science and Technology Beijing. His research interests mainly include non-linear dynamics, plastic process and equipment and innovation and development of industrial equipment.

In recent years, he has presented more than 30 scientific research projects, such as the National Technology Research and Development Program (863), National Natural Science Foundation of China (NSFC), the National Key Technology Development Project, Ministry level key or key promotion projects, the Combination of the efforts of Enterprises, Universities and Research Institutions of Ministry of Education of Guangdong Province and Beijing Central University Co-construction project, etc. Until now, he has published over 150 academic papers on domestic and foreign journals like International Journal of Plasticity (IJP), International Journal of Mechanical Science (IJMS), Chinese Journal of Mechanical Engineering and Journal of Plasticity Engineering, etc. In 1994, he was awarded the young academic leader of Beijing and enjoyed the Special allowance of the State Council. Also, he is President of China Metallurgical Education Association and vice President of Salary Management Research Branch of China Association of Higher Education.

Degrees Earned:

 M.S. Metallurgical Machinery, Beijing Institute of Iron and Steel Engineering, 07/1989

 B.S. Steel rolling machinery, Northeast Heavy Machinery College, 01/1983

Prior Positions:

Professor, School of Mechanical Engineering, University of Science and Technology  Beijing, 07/1996-present

Associate Professor, School of Mechanical Engineering, University of Science and Technology Beijing, 07/1991-07/1996

Lecturer, Department of Mechanics, Beijing Institute of Iron and Steel Engineering, 07/1990-07/1991

Assistant, Department of Mechanics, Beijing Institute of Iron and Steel Engineering, 06/1986-07/1990

Representative articles:

[1]  Mu L, Jia Z, Ma Z W, Shen F H, Sun Y K, Zang Y*. A theoretical prediction framework for the construction of a fracture forming limit curve accounting for fracture pattern transition[J]. International Journal of Plasticity, 2020, 129: 102706.

[2]  Li X, Zang Y*, Lian Y. An interface shear damage model of chromium coating/steel substrate under thermal erosion load[J]. Defence Technology, 2020.

[3]  Li X, Zang Y*, Mu L. Erosion analysis of machine gun barrel and lifespan prediction under typical shooting conditions[J]. Wear, 2019, 444-445: 203177.

[4]  Li X, Mu L, Zang Y*. Study on performance degradation and failure analysis of machine gun barrel[J]. Defence Technology, 2019.

[5]  Guan B, Zhang C, Zang Y, et al. Model for the whole roller leveling process of plates with random curvature distribution based on the curvature integration method[J]. Chinese Journal of Mechanical Engineering, 2019, 32(1).

[6]  Guan B, Zang Y, Yang F, et al. Thermomechanical voupling model for a stainless steel-clad plate on heat treatment[J]. Strength of Materials, 2019, 51(1):40-55.

[7]  Mu L, Zang Y*, Wang Y, Li X L, Stemler P M A. Phenomenological uncoupled ductile fracture model considering different void deformation modes for sheet metal forming[J]. International Journal of Mechanical Sciences, 2018, 141: 408-423.

[8]  Guan B, Zang Y, Han X, et al. Cold-rolled strip steel stress detection technology based on a magnetoresistance sensor and the magnetoelastic effect. Sensors, 2018, 18(5).

[9]  Guan B, Chen B Y, Zang Y, et al. Prediction of a high temperature bonding condition at the interface for the hot-rolled stainless steel clad plate on rolling[J]. Strength of Materials, 2018, 50(2).

[10]  Guan B, Zang Y, Wu D, et al. Stress-inheriting behavior of H-beam during roller straightening process[J]. Journal of Materials Processing Technology, 2017, 244:253-272.

[11]  Mu L, Wang Y, Zang Y*, Stemler P M A. Edge fracture prediction using uncoupled ductile fracture models for DP780 sheet[J]. Journal of Failure Analysis and Prevention, 2017, 17(2): 321-329.

[12]  Mu L, Zang Y*, Li X L, Stemler P M A. A micromechanically-motivated phenomenological model for predicting ductile fracture initiation[J]. Procedia engineering, 2017, 207: 2054-2059.

[13]  Zeng L, Zang Y*, Gao Z. Hopf bifurcation control for rolling mill multiple-mode-coupling vibration under nonlinear friction[J]. Journal of Vibration and Acoustics-Transactions of the ASME, 2017, 139(6): 061015.

[14]  Huang J, Zang Y*, Gao Z, et al. Influence of asymmetric structure parameters on rolling mill stability[J]. Journal of Vibroengineering, 2017, 19(7):4840-4853.

[15]  Liu X, Zang Y*, Gao Z. Rolling mill chatter mechanism based on the unsteady lubrication performance[J]. Journal of Vibroengineering, 2017, 19(3):1569-1584.

[16]  Fu K, Zang Y*, Gao Z. Non-linear dynamics of inlet film thickness during unsteady rolling process[J]. Chinese Journal of Mechanical Engineering, 2016, 29(3): 522-530.

[17]  Zeng L, Zang Y*, Gao Z. Multiple-modal-coupling modeling and stability analysis of cold rolling mill vibration[J]. Shock and Vibration, 2016: 2347386.

[18]  Kang H, Shan Z, Zang Y*, et al. Effect of yarn distortion on the mechanical properties of fiber-bar composites reinforced by three-dimensional weaving, Applied Composite Materials, 2016, 23(2):119-138.

[19]  Liu X, Zang Y*, Gao Z, et al. Time Delay Effect on Regenerative Chatter in Tandem Rolling Mills[J]. Shock & Vibration, 2016, 4025650.

[20]  Zeng L, Zang Y*, Gao Z, Effect of rolling process parameters on stability of rolling mill vibration with nonlinear friction[J], Journal of Vibroengineering, 2016,18(2): 1288-1306.

[21]  Guan B, Zang Y , Chen B , et al. Study on computer aided inspected point planning based on human-computer interaction[J]. Journal of Computational Methods in sciences and Engineering, 2015, 15(3):569-583.

[22]  Zeng L, Zang Y*, Gao Z, et al, Stability analysis of the rolling mill multiple-modal-coupling vibration under nonlinear friction[J]. Journal of Vibroengineering, 2015, 17(6):2824-2836.

[23]  Zeng Q, Zang Y*, Qin Q, The effect of roll with passive segment on the planetary rolling process[J]. Advances in Mechanical Engineering, 2015, 7(2).