陈顺华SH Chen

教授

教授 博士生导师 硕士生导师

所在单位:机械工程学院

学历:博士研究生毕业

办公地点:机械楼

主要任职:机械制造工程系主任、领域交叉融合制造技术团队负责人

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个人简介

   香港理工大学博士、博士后(Postdoctoral Fellow),现任合肥工业大学机械工程学院教授、博士生导师,省级领军人才,机械制造工程系主任,领域交叉融合制造技术科研团队负责人;先后入选香港理工大学博士后计划、合肥工业大学“黄山青年学者”、安徽省高层次人才计划。

   面向制造业“新材料,新工艺,新技术,新装备”四新战略发展需,陈顺华教授于2017年创立领域交叉融合制造技术科研团队,融合新材料、传统加工技术、特种加工技术、智能装备、智能制造等不同领域前沿,开展领域交叉融合制造技术研究。团队目前拥有教授、副教授、讲师、博士后、研究生等40余人,具体研究方向如下图所示。

   欢迎相关领域专家、学者、企业家洽谈合作!!

   欢迎有志于从事领域交叉融合制造技术的同学们报考我们团队博士、硕士研究生!!


团队方向.jpg





 陈顺华教授近年来在Acta Materialia, Scripta Materialia, Applied Physics Letters, Journal of Manufacturing Processes, Materials Science & Engineering A, Journal of Materials Science & Technology, Materials and Design, Intermetallics, Journal of Alloys and Compounds, The International Journal of Advanced Manufacturing Technology等国际知名期刊上发表SCI收录学术论文80余篇,申报发明专利40余项,其中已获授权发明专利20余项。部分代表性成果如下: 

一、研究论文

(1) H.H. Tang, X.B. Li, J.S. Zhang, D. Zhou, Z.W. Wu, and S.H. Chen, Fractal analysis on the uniformity between the shear bands and serrated flows of a Zr-based bulk metallic glass, Intermetallics, 2023, 162: 107999.

(2) C. Li, S.H. Chen, H.H. Tang, J.S. Zhang, J.Q. Liu, and Y.C. Wu, Dendrite structure-induced tunable plastic deformation behavior in (Ti-V-Cr)100-xWx refractory high entropy alloys, International Journal of Refractory Metals and Hard Materials, 2023, 116: 106329.

(3) J.S. Zhang, Y.S. Shang, H.D. Yang, H.H. Tang, and S.H. Chen, On the stress field redistribution of tool–chip interface for micro‑groove textured tools, The International Journal of Advanced Manufacturing Technology, 2023, 126: 4637-4650.

(4) S.H. Chen, H.W. Gu, J.Y. Wang, W.J. Chang and K.C. Chan, Processing of monolithic bulk metallic glass using sinking electrical discharge machining, The International Journal of Advanced Manufacturing Technology, 2023, 126: 5057-5080.

(5) S.H. Chen, H.W. Gu, K.K. Feng, H.M. Zheng and K. Chen, A comparative study on the die‑sinking EDM performance of bulk metallic glass composites under rough and refined conditions, The International Journal of Advanced Manufacturing Technology, 2022, 121: 4865-4883.

(6) W.J. Chang, X.X. Li, H.D. Yang, J.S. Zhang, J.C. Zhang, H.H. Tang and S.H. Chen, On the wire EDM of metastable atomic structured bulk metallic glasses, The International Journal of Advanced Manufacturing Technology, 2022, 120: 5411-5430.

(7) S.H. Chen, J.S. Zhang, S. Guan, T. Li, J.Q. Liu, F.F. Wu and Y.C. Wu, Microstructure and mechanical properties of WNbMoTaZrx (x=0.1, 0.3, 0.5, 1.0) refractory high entropy alloys, Materials Science and Engineering A, 2022, 835: 142701.

(8) H.H. Tang, L. Meng, J.S. Zhang, D. Zhou and S.H. Chen, On the serration evolution of cellular bulk metallic glass monitored by fractal analysis, Journal of Non-Crystalline Solids, 2022, 596: 121844.

(9) H.H. Tang, L. Meng, J.C. Zhang, H.D. Yang, J.S. Zhang, D. Zhou, W.J. Chang and S.H. Chen, On the fractal analysis of the serration behavior of a bulk metallic glass composite, Journal of Alloys and Compounds, 2022, 895: 162605.

(10)  W.J. Chang, S.Y. Wang, H.H. Wang, B.L. Dong, Q. Yang, J.Y. Chen and S.H. Chen, Development of a micro-electrochemical machining nanosecond pulse power supply, Review of Scientific Instruments, 2022, 93: 024707.

(11)  H.D. Yang, Y.S. Wu, J.S. Zhang, H.H. Tang, W.J. Chang, J.C. Zhang and S.H. Chen, Study on the cutting characteristics of high‑speed machining Zr‑based bulk metallic glass, The International Journal of Advanced Manufacturing Technology, 2022, 119: 3533-3544.

(12) S.H. Chen, K. Xu, W.J. Chang, Y. Wang and Y.C. Wu, On the WEDM of WNbMoTaZrx (x = 0.5, 1) refractory high entropy alloys, Entropy, 2022, 24, 1796.

(13) C. Li, S. H. Chen, Z.W. Wu, Z.F. Zhang and Y.C. Wu, Development of high‑strength WNbMoTaVZrx refractory high entropy alloys, Journal of Materials Research, 2022, 37: 1664–1678.

(14) S.H. Chen, Q. Chen, J.Q. Liu, J.S. Zhang and Y.C. Wu, Recent advances in W-Containing refractory high-entropy alloys—An overview, Entropy, 2022, 24: 1533.

(15) S.H. Chen, Q. Ge, J.S. Zhang, W.J. Chang, J.C. Zhang, H.H. Tang and H.D. Yang, Low-speed machining of a Zr-based bulk metallic glass, Journal of Manufacturing Processes, 2021, 72: 565-581.

(16) S.H. Chen, C. Li, J.S. Zhang, Y.Q. Qin, H.D. Yang, J.C. Zhang, W.J. Chang, H.H. Tang and Y.C. Wu, On the relationship between the accumulation and release of elastic energy during the flow serrations of a Zr-based bulk metallic glass, Materials Science and Engineering A, 2021, 817: 141423.

(17) S.H. Chen, T. Li, W.J. Chang, H.D. Yang, J.C. Zhang, H.H. Tang, S.D. Feng, F.F. Wu and Y.C. Wu, On the formation of shear bands in a metallic glass under tailored complex stress fields, Journal of Materials Science & Technology, 2020, 53: 112-117.

(18) S.H. Chen, H.H. Tang, H.M. Zheng, W.J. Chang, J.C. Zhang, H.D. Yang, Z.F. Zhang, D.B. Yu, K.C. Chan and R.P. Liu, Achieving stable plastic flows in a Zr-based bulk metallic glass under tailored mixed-mode (I/II) loading conditions, Materials Science and Engineering A, 2020, 772: 138695.

(19) S.H. Chen, K.C. Chan, D.X. Han, L. Zhao and F.F. Wu, Programmable super elastic kirigami metallic glasses, Materials & Design, 2019, 169: 107687.

(20)   H.Y. Cheng, S.H. Chen, Y.Q. Qin, S.D. Feng, K.C. Chan and Y.C. Wu, On the variation of the mechanical energy accumulation rates during the flow serrations of a Zr-based bulk metallic glass, Journal of Non-Crystalline Solids, 2019, 508: 1-6.

(21) H.H. Tang, Y.C. Cai, Q. Zuo, S.H. Chen and R. P. Liu, Achieving high uniformity of the elastic strain energy accumulation rate during the serrated plastic flows of bulk metallic glasses, Materials Science and Engineering A, 2018, 736: 269-275.

(22) S.H. Chen, K.C. Chan, T.M. Yue and F.F. Wu, Highly stretchable kirigami metallic glass structures with ultra-small strain energy loss, Scripta Materialia, 2018, 142: 83-87.

(23) S.H. Chen, A. Domel, T.M. Yue, C.P. Tsui, K.C. Chan, K.A. Dahmen and P.K. Liaw, Deformation behavior of bulk metallic glasses under a mixed-mode (I/II) loading condition, Intermetallics, 2018, 93: 148-154.

 

二、授权专利

(1)      陈顺华等,一种分布式模块化车载电池管理系统;

(2)      陈顺华等,一种电火花成形加工复杂型腔的装置及方法;

(3)      陈顺华等,一种电极群孔电解加工工艺装置;

(4)      陈顺华等,一种手机壳出声孔加工设备;

(5)      陈顺华等,一种用于柔性零件的电解加工工具;

(6)      陈顺华等,一种薄壁圆筒群孔加工装置及其加工方法;

(7)      陈顺华等,一种高塑性的Nb25Mo25Ta25Ti20W5CX系难熔高熵合金及其制备方法;

(8)      陈顺华等,一种单相WNbMoTaZr系难熔高熵合金及其制备方法;

(9)      陈顺华等,一种高强度高硬度的W-Ta-V-Zr系难熔高熵合金及其制备方法;

(10)   陈顺华等,一种连续制备多种致密合金的装置;

(11)   陈顺华等,一种多工位多角度的电火花加工装置;

(12)   陈顺华等,一种熔点分级的合金熔炼装置;

(13)   陈顺华等,一种金相样品打磨装置。


工作经历

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研究方向

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团队成员

团队名称:领域交叉融合制造技术团队

团队介绍:

面向制造业“新材料,新工艺,新技术,新装备”四新战略发展需求,陈顺华教授于2017年创立领域交叉融合制造技术科研团队,融合新材料、传统加工技术、特种加工技术、智能装备、智能制造等不同领域前沿,开展领域交叉融合制造技术研究。团队目前拥有教授、副教授、讲师、博士后、研究生等40余人,近年来承担国家自然科学基金、省科技重大专项、省重点研发等各类纵向课题共30余项,承担企业委托课题40余项,具有丰富的基础研究、技术开发、新产品开发经验。