陈明松   教授、博导 

     办公室：机电楼A-521
     E-mail：chenms18@csu.edu.cn

     

项目信息

    在研项目：

     1）国家重点研发计划子课题      1项   主持

     2）企业委托横向课题：跨运车自主定位与导航技术开发      1项     主持

     3）湖南省自然科学基金面上项目   1项    主持

     4）企业委托横向课题：机车实时状态监控系统的研究    1项     主持

     5）企业委托横向课题：钛合金棒材锻造过程智能化解决方案  1项   参与

  结题项目：

    1）国家自然科学基金面上项目  1项   主持

    2）国家自然科学基金青年基金项目  1项   主持

    3）博士后特别资助项目  1项   主持

    4）湖南省自然科学基金面上项目   1项    主持

    5）湖南省自然科学基金青年基金项目 1项    主持

    6)  企业委托横向课题：高空作业机器人控制技术研究   1项    主持

   此外，主持其他横向课题20余项。

欢迎有需求企业合作研发或者委托研发。主要可以承接：视觉/激光SLAM系统开发、基于视觉伺服的复杂曲面恒力打磨系统开发（即视即磨），四足机器人和轮式移动机器人导航/跟随系统开发，四足机器人巡检系统（变电站、矿山等场景）、基于UWB的人员定位系统（矿山、商城等场景）等方向的项目。

欢迎有志青年报考研究生，共同为祖国的社会主义科研事业奉献自己的力量！

近年来主要成果：

授权发明专利

2025年授权

1) 张驰洲，陈明松，蔺永诚等：一种基于深度强化学习的移动机器人自主探索方法，专利申请号：202411312042.9，授权公告日：2025.3.07. 

2) 张驰洲，陈明松，蔺永诚等：一种地面约束的多传感器融合定位与建图方法，专利号：ZL202410108411.6，授权公告日：2025.2.18. （专利权转让）

2024年授权

3) 陈明松, 张驰洲, 王冠强, 蔺永诚. 一种面向移动机器人的GNSS/激光雷达回环检测方法,专利号: ZL202111071687.4, 授权公告日: 2024.04.12. （专利权转让）

4) 张驰洲, 陈明松, 王冠强, 蔺永诚, 吴敏杰, 王秋. 一种基于深度学习的激光SLAM定位系统及方法,专利号: ZL202111223949.4, 授权公告日: 2024.04.26. （专利权转让）

5) 张驰洲, 吴敏杰, 陈明松, 蔺永诚, 王冠强, 王秋. 一种基于主动激光SLAM的导航系统,专利号: ZL 202111310689.4, 授权公告日: 2024.04.26. （专利权转让）

6) 王冠强, 陈明松, 蔺永诚, 谭先华, 张驰洲. 一种基于YOLO的轻量高效的检测网络, 专利号: ZL202211074565.5, 授权公告日：2024.01.26. （专利权转让）

7) 王冠强, 陈明松, 蔺永诚, 张驰洲, 谭先华. 一种面向工业图像质量的智能反馈控制方法与系统, 专利号: ZL 202310643591.3，授权公告日：2024.02.20. （专利权转让）

8) 王冠强, 陈明松, 蔺永诚, 谭先华, 张驰洲. 一种提高缺陷检测能力的多轮多模型融合检测方法, 专利号: ZL202310643591.3, 授权公告日：2024.01.30. （专利权转让）

9) 王秋, 陈明松, 颜欣, 蔺永诚, 蒋文杰, 张驰洲, 吴敏杰, 曾维栋. 一种管道内机器人定位的非视距误差识别和缓解方法, 专利号: ZL202311469680.7, 授权公告日：2024.04.19. （专利权转让）

10)王秋, 陈明松, 蔺永诚, 姚文欣, 高百会, 张驰洲, 曾维栋. 一种矩形板材组批排样高效协同方法, 专号: ZL 202211443774.2, 授权公告日：2024.04.26. （专利权转让）

11)王秋,陈明松,蔺永诚,刘嘉杰,颜欣,张驰洲. 一种基于域对抗学习的UWB非视距多分类识别方法及系统, 专号: ZL 202410923860.6 授权公告日：2024.09.13.

12) 陈明松, 彭诚旭, 蔺永诚, 王冠强, 蔡金亮, 邹奋扬, 曾维栋. 一种针对复杂曲面的机器人力控磨抛装置及控制方法，专利号: ZL202210414139, 授权公告日: 2024.04.20. （专利权转让）

2023年授权

13) 王秋, 陈明松, 蔺永诚, 张驰洲, 姚文欣, 邹奋扬, 彭诚旭, 王冠强, 曾维栋. 一种高空管道检测用涵道动力机器人, 专利号: ZL202210477273.X, 授权公告日：2023.12.29. （专利权转让）

14) 王冠强, 陈明松, 蔺永诚, 谭先华, 张驰洲, 梁佩. 基于机器视觉的实时工件表面缺陷检测评价系统及方法, 专利号: ZL202210754869.X, 授权公告日：2023.11.24. （专利权转让）

2022年授权

15) 陈明松，蔡金亮，蔺永诚，王冠强，曾维栋，张驰洲，彭诚旭，邹奋扬，李凯. 一种基于实时点云的大型复杂构件表面打磨路径规划方法, 申请专利号：ZL202111384297.2. 授权公告日：2022年11月15日

16) 王秋，陈明松，蔺永诚，曾维栋，王冠强，吴敏杰，一种无物理刹车爬壁机器人用驱动系统及方法. ZL：202110804060.9. 授权时间：2022-05-27

17) 曾维栋，吴敏杰，陈明松，蔺永诚，王秋，彭诚旭，爬壁机器人自主充电系统及自主充电方法. 授权号：ZL202011530742.7，授权公告日：2022.08.23

18) 曾维栋，王秋，陈明松，蔺永诚，吴敏杰，一种基于脑机控制的爬壁打磨装置及其控制方法.授权号：ZL 202011279972.0，授权公告日：2022.2.18

19) 曾维栋，吴敏杰，陈明松，蔺永诚，王秋，复合型爬壁机器人及其控制方法. 授权号： ZL202110362003.X，授权公告日：2022.08.23 （专利权转让）

2021年授权

20) 陈明松，马艳永, 蔺永诚，曾维栋，王冠强，蔡金亮，邹奋杨，彭诚旭，一种获得GH4169合金超细金锻件的方法，ZL 202010620994.2，授权公告日：2021.11.26

21) 陈明松;  王冠强; 蔺永诚; 马艳永，一种均匀细化固溶态GH4169合金锻件混晶组织的方法，ZL 202010622921.7，授权公告日：2021.7.20

22) 曾维栋、王秋、陈明松、蔺永诚、吴敏杰，面向复杂环境的自适应爬壁机器人，ZL202010925358.0，授权公告日：2021.6.22

23) 曾维栋、吴敏杰、陈明松、蔺永诚、吴敏杰，王秋，一种局部真空吸盘，ZL202020912670.8，授权公告日：2021.4.13

2020年授权

24) 陈明松;  王冠强; 蔺永诚; 邹宗怀，一种均匀细化GH4169合金锻件组织的方法，ZL2018111262186，授权公告日：2020.12.18

2019年授权

25) 陈明松，邹宗怀, 李阔阔. 一种通过热处理提升镍基合金锻件组织均匀性的方法，2019.06，ZL201711231943.5

26) 蔺永诚, 李佳，刘延星，陈明松. 一种涡轮盘等温模锻预成形坯料的多目标设计方法，2019.06，ZL201610522957.1

27) 蔺永诚, 谌东东，陈明松，基于BP神经网络的镍基高温合金微观组织预测控制方法，2019.2，中国，ZL2016105522135.3

2018年授权

28) 陈明松，蔺永诚, 李阔阔，一种采用两段阶梯应变速率工艺细化GH4169合金锻件晶粒组织的方法， 2018.2.23，中国，ZL2016 1 0523629.3

29) 蔺永诚，陈小敏，陈明松，一种面向锻件目标晶粒组织的等温模锻工艺轨迹规划方法，2018.9.07，中国，ZL2016 1 1149155.7

2017年授权

30) 陈明松，蔺永诚, 李阔阔，一种预测时变工况下高合金化材料动态再结晶分数的方法，2017.11.14，中国，ZL201610522942.5

31) 陈明松，蔺永诚, 李阔阔，一种循环加载与卸载变形细化GH4169合金锻件组织的方法，2017.1，中国，ZL201510100965.4

32) 蔺永诚, 陈明松，吴先洋，一种等温模锻模具温度场的在线重构方法，2017.12.01，中国，ZL201510400997.4

代表性论文（第一作者/通讯作者）

2025年

1.   Qiu Wang; Ming-song Chen∗; Xin Yan; Yong-cheng Lin; Kai Li; Jia-jie Liu，Domain-Adversarial Learning for UWB NLOS Identification in Dynamic Obstacle Environments，IEEE Sensors Journal， 10.1109/JSEN.2024.3491178. Q1

2.   An Liu, Ming-Song Chen∗, Quan Chen, Y.C. Lin, Guan-Qiang Wang, Hong-Wei Cai, Hong-Bin Li. A cellular automata model for recrystallization annealing of aged GH4169 superalloy and its application, Materials Today Communications, 2025, 42, 111191, https://doi.org/10.1016/j.mtcomm.2024.111191. Q2

2024年

3.   Chizhou Zhang; Mingsong Chen∗; Guanqiang Wang; Yongcheng Lin; Kai Li; Minjie Wu; Zehao Li; Qiu Wang, LIWOM-GD: Enhanced LiDAR–Inertial–Wheel Odometry and Mapping by Fusion With Ground Constraint and Dynamic Points Elimination, IEEE Sensors Journal, 2024, 24(19): 30287-30303 10.1109/JSEN.2024.3431102. IF 4.3 Q1,  2024年7月25日

4.   Chizhou Zhang, Guanqiang Wang, Mingsong Chen∗, Yongcheng Lin, Kai Li, Minjie Wu, Zehao Li, QiuWang, E-Planner: An Efficient Path Planner on A Visibility Graph in Unknown Environments, IEEE Transactions on Instrumentation and Measurement, 2024，72： 8506214: DOI 10.1109/TIM.2024.3440401. IF 5.6 Q1 

5.  Chi-Zhou Zhang, Ze-Hao Li, Ming-Song Chen∗, Yong-Cheng Lin, Guan-Qiang Wang, Qiu Wang, and Wei-Dong Zeng, Advanced Multi-Sensor Person-Following System on a Mobile Robot: Design, Construction and Measurements. IEEE Instrumentation & Measurement Magazine, 2024, 27(5):38-44, doi: 10.1109/MIM.2024.10623162.  IF 1.6 Q3

6.  Guanqiang Wang, Mingsong Chen∗, Yongcheng Lin, Xianhua Tan, Chizhou Zhang, Kai Li, Baihui Gao, Yuxin Kang and Weiwei Zhao, High-accuracy and lightweight weld surface defect detector based on graph convolution decoupling head, Measurement Science and Technology, 35 (2024) 105025. https://doi.org/10.1088/1361-6501/ad63c2

7.   Ming-Song Chen∗, Hong-Wei Cai, Yong-Cheng Lin, Guan-Qiang Wang, Hong-Bin Li , An Liu, Ze-Hao Li, Shan Peng. Investigation on Mechanism of Microstructure Evolution during Multi-Process Hot Forming of GH4169 Superalloy Forging, Materials, 2024, 17, 1697. https://doi.org/10.3390/ma17071697  IF 3.1

8.   Qiu Wang, Mingsong Chen* , Jiajie Liu, Yongcheng Lin, Kai Li , Xin Yan, Chizhou Zhang, 1D-CLANet: A Novel Network for NLoS Classification in UWB Indoor Positioning System, Appl. Sci. 2024, 14, 7609. https://doi.org/10.3390/app14177609. IF 2.5 Q1

9.   Qiu Wang, Ming-song Chen*,  Guan-qiang Wang, Kai Li , Yong-cheng Lin , Ze-hao Li ,Chi-zhou Zhang，A Novel NLOS Identification and Error Mitigation，Method for UWB Ranging and Positioning，IEEE Communications Letters,2024,28(1): 48 - 52，https://DOI 10.1109/LCOMM.2023.3340248，IF:4.1，Q2

10.    Guan-Qiang Wang, Ming-Song Chen*, Yong-Cheng Lin, Xian-Hua Tan, Chi-Zhou Zhang, Wen-Xin Yao, Bai-Hui Gao, Wei-Dong Zeng, An efficient parallel fusion structure of distilled and transformer-enhanced modules for lightweight image super-resolution, The Vision Computer, 2024,40,8377–8396 DOI: 10.1007/s00371-023-03243-9, IF: 3.5, Q2

11.    Guan-Qiang Wang, Ming-Song Chen*, Yong-Chen Lin*, Xian-Hua Tan, Chi-Zhou Zhang, Wen-Xin Yao, Bai-Hui Gao, Kai Li, Ze-Hao Li, Wei-Dong Zeng, Efficient multi-branch dynamic fusion network for super-resolution of industrial component image, Displays, 2024, 82, 102633, DOI: 10.1016/j.displa.2023.102633, IF: 4.3, Q1  https://doi.org/10.1016/j.displa.2023.102633, 发表日期：

12.    Guan-Qiang Wang，Chi-Zhou Zhang， Ming-Song Chen*, Y.C Lin , Xian-Hua Tan, Yu-Xin Kang，  Qiu Wang，Wei-Dong Zeng, Wei-Wei Zhao，A high-accuracy and lightweight detector based on a graph convolution network for strip surface defect detection，Advanced Engineering Informatics， 59（2024）102280. DOI10.1016/j.aei.2023.102280, IF: 8.8 ，Q1

2023年

13.    Guan-Qiang Wang，Chi-Zhou Zhang，Ming-Song Chen⁎，Yong-Cheng Lin，Xian-Hua Tan，Pei Liang，Yu-Xin Kang，Wei-Dong Zeng，Qiu Wang，Yolo-MSAPF: Multiscale Alignment Fusion With Parallel Feature Filtering Model for High Accuracy Weld Defect Detection，IEEE Transactions on Instrumentation and Measurement，2023，72，5022914，DOI: 10.1109/TIM.2023.3302372 , IF: 5.6，Q1

14.Hong-Wei Cai ,Quan Chen ,Ming-Song Chen⁎, Y.C. Lin , Guan-Qiang Wang, Hong-Bin Li. A novel recrystallization annealing method to cooperatively control the grain size and δ phase content for initial aged GH4169 superalloy forging, Materials Characterization, 2023, 205:113246，Q1

15.    王冠强，张驰洲，陈明松*，蔺永诚，邹奋扬，王秋，吴敏杰，曾维栋，融合RRT-Connect和DWA算法的室内移动机器人单目标点导航任务研究[J]. 中南大学学报(自然科学版), 2023,54(11): 4326-4337. https://kns.cnki.net/kcms2/detail/43.1426.n.20230602.1659.002.htm

A类期刊

16.    Qiu-Mei Yang, Y.C. Lin, Wei-Wei Zhao, Guan Liu, Zi-Jian Chen, Jun-Cheng Zhu, Ming-Song Chen, Yu-Liang Qiu，Formation and elimination mechanisms of prior particle boundaries in a new powder metallurgy superalloy，Journal of Materials Research and Technology，2023，27，8037-8049. 

17.    Guan-Qiang Wang, Yong-Chen Lin, Ming-Song Chen*, Chi-Zhou Zhang, A Weld Surface Defect Detection System With Multi-Detection Function Integration, 2023 3rd IEEE International Conference on Electrical Engineering and Mechatronics Technology (ICEEMT), Nanjing, China, 2023, pp. 416-419, doi: 10.1109/ICEEMT59522.2023.10263158.

2022年

18. Wei-Dong Zeng, Li-Jiu Zheng, Ming-Song Chen*，Y.C. Lin, Guan-Qiang Wang, Bai-Hui Gao, Shi-Quan Huang, A Generalized Multivariable Adaptive Super-Twisting Control and Observation for Amphibious Robot, IEEE Access, 2022.3228284. Q2,

19.Ming-Song Chen（陈明松）*, Quan Chen, Yu-Min Lou, Y.C. Lin*, Hong-Bin Li, Yan-Yong Ma, Guan-Qiang Wang, Effect of cooling recrystallization annealing treatment on properties of an initial aged deformed GH4169 superalloy, Materials Science & Engineering A 831 (2022) 142232  Q（IF: 6.044）https://doi.org/10.1016/j.jallcom.2022.164325

20.    Ming-Song Chen⁎ , Yan-Yong Ma , Y.C. Lin⁎ , Yu-Min Lou , Hong-Bin Li , Guan-Qiang Wang , Quan Chen，An innovative annealing treatment method and its mechanism to refine deformed mixed grains of initial aged GH4169 superalloy，Journal of Alloys and Compounds，2022，907，164325  Q1 https://doi.org/10.1016/j.jallcom.2022.164325（IF: 6.371）

21.    Guan-Qiang Wang，Chen Ming-Song (陈明松)*; Lin Y.C.;Li Hong-Bin;Jiang Yu-Qiang;Ma Yan-Yong; Peng Cheng-Xu;Cai Jin-Liang;Chen Quan，Recrystallization nucleation under close-set 8 phase in a nickel-based superalloy during annealing，Journal of Materials Science & Technology, 2022，115(0): 166-176. （IF: 10.319）

22.    Ming-Song Chen*, Quan Chen, Yu-Min Lou, Y.C. Lin*, Hong-Bin Li, Guan-Qiang Wang, Hong-Wei Cai. Effect of Deformation Parameters of an Initial Aged GH4169 Superalloy on Its Microstructural Evolution during a New Two-Stage Annealing, Materials, 2022, 15(16), 5508; https://doi.org/10.3390/ma15165508  Q1 （IF: 3.748）

23.    Qiu-Mei Yang , Yong-Cheng Lin* , Ming-Song Chen，Zi-Jian Chen，Modeling Dynamic Recrystallization Behavior in a Novel HIPed P/M Superalloy during High-Temperature Deformation，Materials, 2022, 15, 4030

2021年

24.    G.Q. Wang, M.S. Chen*, Y.C. Lin, Y.M. Lou, H.B. Li, Y.Y. Ma, Z.H. Zou, Q. Chen, Y.C Xia, Effects of Double-Stage Annealing Parameters on Tensile Mechanical Properties of Initial Aging Deformed GH4169 Superalloy, Materials 2021, 14, 4339.  https:// doi.org/10.3390/ma14154339 Q1 

25.    G.Q. Wang, M.S. Chen*, H.B. Li, Y.C. Lin, W.D. Zeng, Y.Y. Ma, Methods and mechanisms for uniformly refining deformed mixed and coarse grains inside a solution-treated Ni-based superalloy by two-stage heat treatment[J]. Journal of Materials Science & Technology, 2021, 77: 47-57.（中科院一区, TOP期刊） Q1  

26.    G.Q. Wang, M.S. Chen*, Y.C. Lin, H.B. Li, W.D. Zeng, Y.Y. Ma, J.L. Cai, C.X. Peng, F.Y. Zou, A novel annealing method to uniformly refine deformed mixed grain microstructure of a solution-treated Ni-based superalloy. SCIENCE CHINA Technological Sciences, 2021, 64, (8)：1741-1751.  https://doi.org/10.1007/s11431-020-1784-x Q2（中科研2区

27. G.Q. Wang, H.B. Li, M .S. Chen*, Y.C. Lin, W.D. Zeng, Y.Y. Ma, Q. Chen, Y.Q. Jiang, Effect of initial mixed grain microstructure state of deformed Ni-based superalloy on its refinement behavior during two-stage annealing treatment，Materials Characterization，2021,176, 111130. Q1

28. G.Q. Wang, M.S. Chen*, Y.C. Lin, H.B. Li, Y.Y. Ma, Z.H. Zou, Q. Chen, Effects of Deformation Processing Parameters on the Microstructure Evolution and Microhardness of GH4169 Superalloy during Annealing Treatment, Advanced Engineering Materials, 2021, 23(8):2100104.  Q2  

2020年

29.     Li H-B，Chen M S*; Tian Y Q; Chen L S, Chen L Q, Ultra-fine-Grained ferrite prepared from dynamic reversal austenite during warm deformation [J]. Acta Metallurgica Sinica (English Letters), 2020, 33(2): 290-298. Q1 

2019年

30.    Ming-Song Chen*，Guan-Qiang Wang, Hong-Bin Li, Y.C. Lin, Zong-Huai Zou, Yan-Yong Ma, Annealing Treatment Methods and Mechanisms for Refining Mixed and Coarse Grains in a Solution Treatment Nickel-Based Superalloy, Advanced Engineering Materials,2019, 21(9): (JCR 2区) 

31.    Ming-Song Chen*, Guan-Qiang Wang, Hong-Bin Li, Y. C. Lin,  Zong-Huai Zou, Yan Yong Ma, Dao Guang He, Wei Dong Zeng, Precipitation and dissolution behaviors of δ phase inside a deformed nickel based superalloy during annealing treatment, Applied Physics A, 2019, 125: 447. (JCR  2区)  SCI 找不到

32.    Ming-Song Chen*, Zong-Huai Zou, Y. C. Lin, Hong-Bin Li, Guan-Qiang Wang，Formation mechanism of large grains inside annealed microstructure of GH4169 superalloy by cellular automation method，Journal of Materials Science & Technology, Volume 35, Issue 7, July 2019, Pages 1403-1411 (JCR　1区) Q1

33.    Ming-Song Chen*, Wu-Quan Yuan, Hong-Bin Li, Y. C. Lin, Zong-Huai Zou，New insights on the relationship between flow stress softening and dynamic recrystallization behavior of magnesium alloy AZ31B，Materials Characterization, Volume 147, January 2019, Pages 173-183　 (JCR　1区) Q1

34.    Ming-Song Chen*, Zong-Huai Zou, Y. C. Lin, Hong-Bin Li, Yan-Yong Ma，Microstructural evolution and grain refinement mechanisms of a Ni-based superalloy during a two-stage annealing treatment，Materials Characterization, Volume 151, May 2019, Pages 445-456 (JCR１区) Q1 

2018年

35.    Ming-Song Chen*, Zong-Huai Zou, Y.C.Lin, Kuo-KuoLi, Hot deformation behaviors of a solution-treated Ni-based superalloy under constant and changed strain rates[J]. Vacuum, 2018,155:531-538. (JCR　2区)  IF: 3.627 他引12次

36.    Ming-Song Chen*, Zong-Huai Zou, Y.C. Lin, Hong-Bin Li, Wu-Quan Yuan. Effects of annealing parameters on microstructural evolution of a typical nickel-based superalloy during annealing treatment[J]. Materials Characterization, 2018,141:212-222. (JCR1区)

2017年

37. Ming-Song Chen*, Wu-Quan Yuan, Hong-Bin Li, Zong-Huai Zou, Modeling and simulation of dynamic recrystallization behaviors of magnesium alloy AZ31B using cellular automaton method, Computational Materials Science, 2017, 136, 163-172. 38

38.Ming-Song Chen*, Wu-Quan Yuan, Y.C. Lin, Hong-Bin Li, Zong-Huai Zou, Modeling and simulation of dynamic recrystallization behavior for 42CrMo steel by an extended cellular automaton method,Vacuum,2017,146,142—151（IF：2.515）24 Q2 

39.    Ming-Song Chen*, Y.C. Lin, Kuo-Kuo Li，Dynamic recrystallization behaviors  of typical solution-treated and aged Ni-based superalloy under stepped strain rates，Procedia Engineering, 2017，207，2125-2130 (EI) 

2016年

40.    Chen Ming-Song*, Lin Y. C.*, Li Kuo-Kuo, Zhou Ying, A new method to establish dynamic recrystallization kinetics model of a typical solution-treated Ni-based superalloy, Computational Materials Science, 2016, 122, 150-158. 

41. Ming-Song Chen*, Kuo-Kuo Li, Yong-Cheng Lin*, Wu-Quan Yuan, An improved kinetics model to describe dynamic recrystallization behavior under inconstant deformation conditions, Journal of Materials Research, 2016, 31:  2994-3003 . 

42. Chen Ming-Song, Lin Y. C.*, Li Kuo-Kuo, Chen Jian, The nonlinear unloading behavior of a typical Ni-based superalloy during hot deformation: A new elasto-viscoplastic constitutive model, Applied Physics A, 2016, 122: 869  Q2

43. Chen Ming-Song, Lin Y. C.*, Li Kuo-Kuo, Chen Jian, The nonlinear unloading behavior of a typical Ni-based superalloy during hot deformation: A unified elasto-viscoplastic constitutive model, Applied Physics A, 2016, 122: 854. Q2

44. Li Kuo-Kuo, Chen Ming-Song, Lin Y. C., Yuan Wu-Quan, Microstructural evolution of an aged Ni-based superalloy under two-stage hot compression with different strain rates. Materials & Design. 2016, 111: 344-352  Q1 

2016年之前

45. Chen Ming-Song, Lin Y. C.*, Chen Kang-Hua, Evolution of elliptic-cylindrical and circular-cylindrical voids inside power-law viscous solids, International Journal of Plasticity, 2014, 53, 206-227. Q1

46. Chen Ming-Song, Lin Y. C.*, Numerical simulation and experimental verification of void evolution inside large forgings during hot working, International Journal of Plasticity, 2013, 49, 53-70.  Q1

47. Chen, Ming-Song, Lin, Y. C., Ma, Xue-Song，The kinetics of dynamic recrystallization of 42CrMo steel，Materials Science and Engineering A, 2012,556, 260-266 Q1