职称:教授
研究方向:数智化设计与风险控制,先进材料关键性能建模,构件成形仿真与多目标优化设计,结构服役风险的实时仿真,大变形弹塑性新模型及其高效算法,软物质变形行为仿真模型及其在医疗健康中的应用。
Email:yyhxiao@fyust.org.cn
肖衡,德国洪堡学者,国家特聘专家。
主要从事高端装备智能设计与风险控制的研究及其工程应用,智能设计聚焦于构件成形设计的准确仿真模型及其高效高精度数值算法,而风险控制则致力于装备的实时服役仿真,旨在于预测与控制服役中装备由于屈曲、损伤、断裂、疲劳等失稳和失效行为引发的安全风险。
在德期间主持/主参德国研究基金会及西门子集团等资助项目9项,主持教育部211工程高层次人才团队项目2项,主持/主参国家自然科学基金面上项目5项,主持科技部高端外专项目1项;发表论文200余篇,兼任多个SCI期刊编委,连续十年位列中国高被引学者榜单。
相关论文被权威刊物Proc.Roy.Soc.A的评审人评审为“有限弹塑性理论方面的一个重大里程碑。一个延续了二十多年的争论现已获得在物理观点上高度令人满意的解决…是具有最高度国际重要性的杰出论文…是最高质量的贡献”;在Springer出版的学科历史著作中以及发表于期刊ZAMM的弹塑性理论历史回顾专题文献中,所创立的自洽欧拉弹塑性新模型位列弹塑性理论发展史上当代发展阶段的标志性成就。
教育经历:
1983年获武汉大学水利水电工程专业学士学位
1986年获华中科技大学固体力学专业硕士学位
1990年获上海大学应用数学和力学专业博士学位
工作经历:
1990-1992年以及1992-1994年分别在西北大学现代物理研究所和北京大学数学学院从事博士后研究
1994-1995年任北京大学副教授
1995-1997年任德国鲁尔大学土木与环境工程学院洪堡访问教授
1998-2002年任德国鲁尔大学土木与环境工程学院科研助理
2003-2011年任德国鲁尔大学土木与环境工程学院教授兼总工程师
2011-2018年任上海大学上海市应用数学和力学研究所教授
2018-2024任暨南大学教授力学与建筑工程学院教授
2024-至今任福耀科技大学智造与未来技术学院教授
专著:
[1] Heng Xiao, Otto T. Bruhns and Albert T.M. Meyers, Modern Theory of Vectors and Tensors in Mechanics and Engineering, Ruhr-University, 2003.
[2] Heng Xiao, Otto T. Bruhns and Albert T.M. Meyers, A Modern Introduction to Theory of Elastoplasticity, Ruhr-University, 2004.
期刊:
[1] Hao-Nan He, Si-Yu Wang, Hui-Feng Xi, Heng Xiao*, Lin Zhan, Jia-Shun Zhou, The large strain snap-through effect in free torsion of highly elastic thin-walled soft tubes. Thin-Walled Struct. 199, 11803, 2024.
[2] Meng-Liang Han, Hui-Yu Wang, Si-Yu Wang, Heng Xiao*, Exact large strain analysis for the Poynting effect of freely twisted tubes made of highly elastic soft materials. Thin-Walled Struct. 184, 110503, 2023.
[3] Hui-Feng Xi, Z.C. Zhou, H.H. Zhang, S.Q. Huang, Heng Xiao*, Multi-morphology TPMS structures with multi-stage yield stress platform and multi-level energy absorption: Design, manufacturing, and mechanical properties. Engrg. Struct. 294, 116733, 2023.
[4] Hui-Feng Xi, Gui-Cheng Zhao, Otto Bruhns, Si-Yu Wang, Heng Xiao, Exact simulation for direction-dependent large elastic strain responses of soft fibre-reinforced composites. Appl. Math. Mech.-Engl. Ed. 44(9), 1497-1510, 2023.
[5] Lin Zhan, Si-Yu Wang, Otto T. Bruhns, Heng Xiao*. High-efficiency algorithms for metal fatigue failure effects under multi-axial repeated loadings. Int. J. Num. Meth. Engrg. 123, 1277-1293, 2022.
[6] Si-Yu Wang, Lin Zhan, Hui-Feng Xi, Otto T. Bruhns, Heng Xiao*. Unified simulation of hardening and softening effects for metals up to failure. Appl. Math. Mech.-Engl. Ed. 42, 1583-1596, 2021.
[7] Heng Xiao*. Notes on micro-continua exhibiting quantum effects, Appl. Math. Mech.-Engl. Ed. 41, 1597-99, 2020.
[8] Si-Yu Wang, Lin Zhan, Hui-Feng Xi, Heng Xiao*. New elastoplastic equations for accurately and explicitly simulating pseudoelastic-to-plastic transition effects of SMAs. Appl. Math. Mech. Engl. Ed. 41, 1583-1596, 2020.
[9] Lin Zhan, Xiao-Ming Wang, Si-Yu Wang, Hui-Feng Xi, Heng Xiao*. An explicit and accurate approach toward simulating plastic-to-pseudoelastic transitions of SMAs under multiple loading-unloading cycles. Int. J. Solids Struct. 185-186, 104-115, 2019.
[10] Heng Xiao*. Deformable micro-continua in which quantum mysteries reside. Appl. Math. Mech.-Engl. Ed. 40(12): 1805-1830, 2019.
[11] Zhao-Ling Wang, Heng Xiao*. Direct modeling of multi-axial fatigue failure for metals. Int. J. Solids Struct. 125: 216–231, 2017.
[12] H. Xiao*. Quantum enigma hidden in continuum mechanics. Appl. Math. Mech.-Engl. Ed. 38, 39-56, 2017.
[13] H. Xiao*. An explicit, direct simulation of multiaxial finite strain inelastic behavior for polymeric solids. Int. J. Plasticity 71, 146-169, 2015.
[14] H. Xiao*, X.M. Wang, Z.L. Wang, Z.N. Yin. Explicit, comprehensive modeling of multi-axial finite strain pseudo-elastic SMAs up to failure. Int. J. Solids Struct. 88-89, 215-226, 2016.
[15] Heng Xiao*, X.F. Ding, J. Cao, Z.N. Yin. New multi-axial constitutive models for large elastic deformation behaviors of soft solids up to breaking. Int. J. Solids Struct. 109, 123-130, 2017.
[16] H. Xiao, O.T. Bruhns, A. Meyers. Free rate-independent elastoplastic equations. ZAMM-J. Appl. Math. Mech. 94, 461-476, 2014.
[17] Z.N. Yin, H. Xiao*. Automatic consistency integrations for the stress update of J2 elastoplastic rate constitutive equations with combined hardening. Int. J. Numer. Meth. Engrg. 98, 590-611, 2014.
[18] H. Xiao*. Thermo-coupled elastoplasticity model with asymptotic loss of the material strength. Int. J. Plasticity 63, 211-228, 2014.
[19] H. Xiao*. An explicit, straightforward approach to modeling SMA pseudoelastic hysteresis. Int. J. Plasticity 53, 228-240, 2014.
[20] H. Xiao. Pseudoelastic hysteresis out of recoverable finite elastoplastic flows. Int. J. Plasticity 41, 82-96, 2013.
[21] H. Xiao, O. T. Bruhns, A. Meyers. Thermodynamic laws and consistent Eulerian formulation of finite elastoplasticity with thermal effects. J. Mech. Phys. Solids 55: 338-365, 2007.
[22] H. Xiao, O. T. Bruhns, A. Meyers. Elastoplasticity beyond small deformation. Acta Mechanica 182: 31-111, 2006.
[23] A. Meyers, H. Xiao*, O. T. Bruhns. Choice of objective rate in single parameter hypoelastic deformation cycles. Computers & Structures 84, 1134-1140, 2006.
荣誉与奖励:
[1] 1995年获洪堡研究基金,洪堡学者
[2] 2013年受聘国家特聘专家