๐ฉโ๐ฌ Assist. Prof. Dr. Xiaohui Chen is a leading researcher in Mechanical & Materials Engineering, specializing in cyclic plasticity behavior, ratcheting, and constitutive modeling โ๏ธ๐. She holds a Ph.D. from Tianjin University ๐ and has over 60 high-impact publications in top journals ๐. Currently based at Northeast University, Qinhuangdao ๐จ๐ณ, she has also served as a visiting scholar at the University of Strathclyde, UK ๐. Dr. Chenโs innovative work using FEM and AI for structural safety has real-world applications in aerospace, pressure vessels, and energy systems ๐๐ฌ. Her collaborative, multidisciplinary approach makes her a standout in global research ๐.
Assist. Prof. Dr Xiaohui Chen, Northeastern University, China
Profile
SCOPUS
๐ Education
Dr. Xiaohui Chen has an exceptional academic background in engineering. She earned her Ph.D. in Chemical Engineering Machinery from Tianjin University (2010โ2013) ๐งช๐, one of Chinaโs top institutions. Prior to that, she completed her Masterโs degree in the same field at Hebei University of Technology (2007โ2010) ๐ง๐. Her academic journey began with a Bachelorโs in Process Equipment and Control Engineering from the same university (2003โ2007) ๐๏ธ๐. This strong progression through prestigious programs laid the foundation for her advanced research in material behavior, structural safety, and engineering innovation ๐๐.
๐ผ Professional Experience
Dr. Xiaohui Chen has built a strong career in research and international collaboration. Since January 2014, she has served as a dedicated Researcher at Northeast University, Qinhuangdao ๐ซ๐ฌ, contributing significantly to engineering research and academic development. From October 2016 to October 2017, she expanded her expertise as a Visiting Scholar at the University of Strathclyde, UK, within the Department of Mechanical & Aerospace Engineering ๐โ๏ธ. Her exposure to global research environments and sustained commitment to innovation have enhanced her technical proficiency and positioned her as a leader in advanced materials and structural mechanics ๐ก๐ ๏ธ.
๐ฌ Research Focus
Dr. Xiaohui Chenโs research is centered on the viscoplastic behavior of advanced materials under complex mechanical and thermal loading ๐ง๐ฅ. Her work explores ratcheting, creep-fatigue interactions, and multiaxial loading in materials like stainless steel and P92 steel, which are critical in pressure vessels and structural components ๐๏ธ๐งช. She has developed unified viscoplastic constitutive models and advanced finite element simulations to predict material response and ensure structural integrity. Published in top-tier journals, her research contributes directly to improving safety, reliability, and performance in aerospace, energy, and mechanical engineering sectors ๐๐๐.
๐ Publications
Unified viscoplasticity model for Type 316 stainless steel subjected to isothermal and anisothermal-mechanical loading
๐ฉโ๐ฌ Authors: Xiaohui Chen*, Shiji Liu, Yusong Tian, Lin Zhu
๐ Journal: European Journal of Mechanics A-Solids, 2023, 97: 104855
๐งช๐ฉ๐
Ratcheting response and boundary of austenitic stainless steel in a pressurized straight pipe subjected to in-plane bending cycles
๐ฉโ๐ฌ Authors: Yusong Tian, Xiaohui Chen*, Tianxiang Chen, Lin Zhu, Ahmad Varvani-Farahani
๐ Journal: International Journal of Pressure Vessels and Piping, 2023, 201: 104855
๐งฑ๐๐
Ratcheting assessment of pressurized elbow pipes using the visco-plastic Chen-Jiao-Kim hardening rule frameworks
๐ฉโ๐ฌ Authors: Xiaohui Chen*, Lang Lang, Lin Zhu, Xu Zhao, Hongru Liu
๐ Journal: International Journal of Pressure Vessels and Piping, 2023, 205: 104995
๐ฆพ๐งฐ๐
Multiaxial ratcheting assessment of Z2CND18.12N steel using modified A-V hardening rule
๐ฉโ๐ฌ Authors: Xiaohui Chen*, Yang Zhou, Wenwu Liu, Xu Zhao
๐ Journal: Steel and Composite Structures, 2023, 49(1): 1โ17
โ๏ธ๐งฒ๐งฎ
Numerical prediction of low cyclic fatigue and creep-fatigue behavior of P92 steel using a unified viscoplastic constitutive model
๐ฉโ๐ฌ Authors: Xiaohui Chen*, Lin Zhu, Wenwu Liu, Xu Zhao, Lang Lang
๐ Journal: International Journal of Pressure Vessels and Piping, 2023, 206: 105074
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