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教育教学

科学研究 Scientific Research 主持国家自然科学基金1项，省部级自然科学基金3项及其它纵向横向项目16项；参研173、973、国家科技重大专项等课题。以第一/通信作者发表SCI论文15篇，授权国家发明专利21项、软件著作权23项。研究方向（不局限于）：[1] 高效精密加工与抗疲劳制造[2] CAD/CAE/CAM软件系统开发[3] 数值计算及其工程应用[4] 制造工艺数据库与专家系统主要发表论文：[1]  Junfeng Xiang*, JieYi. Deformation mechanism in wax supported milling of thin-walled structures based on milling forces stability[J]. CIRP Journal of Manufacturing Science and Technology, 2021, 32: 356-369. SCI[2]  Junfeng Xiang,  Lijing Xie, Feinong Gao. Modeling high-speed cutting of SiCp/Al composites using a semi-phenomenologically based damage model[J]. Chinese Journal of Aeronautics, 2021, 34(8):218-229. SCI[3] Jie Yi, Junfeng Xiang*, Fengyan Yi, Yanhua Zhao, Xibin Wang, Li Jiao. Prediction of mesoscale deformation in milling micro thin wall based on cantilever boundary[J]. International Journal of Advanced Manufacturing Technology, 2020, 106(7-8):2875-2892. SCI[4] Jie Yi, Xibin Wang, Li Jiao, Junfeng Xiang*, Fengyan Yi. Research on deformation law and mechanism for milling micro thin wall with mixed boundaries of titanium alloy in mesoscale[J]. Thin-walled Structures, 2019, 144:10639. SCI[5] Junfeng Xiang, Lijing Xie, Shiyan Huo, Siqing Pang, Xibin Wang. Simulation and experimental research on ultra-precision turning of SiCp/Al Composites[J]. Rare Metal Materials and Engineering, 2019, 48(5):1687-1696. SCI[6] Li Zhou, Junfeng Xiang*, Jie Yi, Peng Gao, Jiaqing Xie, Experimental and Numerical Study of Edge Defects When Turning 17vol.% SiCp/2009Al Composites[J]. Applied Sciences, 2019, 9(18): 3817. SCI[7] Junfeng Xiang, Lijing Xie, Feinong Gao, Jie Yi, Siqin Pang, Xibin Wang. Diamond tools wear in drilling of SiCp/Al matrix composites containing Copper[J]. Ceramics International, 2018, 44(5): 5341-5351. SCI[8] Junfeng Xiang, Lijing Xie, Feinong Gao, Jie Yi, Siqin Pang, Xibin Wang. Methodology for dependence-based integrated constitutive modelling: an illustrative application to SiCp/Al composites[J]. Ceramics International, 2018, 44(9):10028-10034. SCI[9] Junfeng Xiang, Siqin Pang, Lijing Xie, Feinong Gao, Xin Hu, Jie Yi. Mechanism-based FE simulation of tool wear in diamond drilling of SiCp/Al composites[J]. Materials, 2018, 11(2): 252. SCI[10] Junfeng Xiang, Siqin Pang, Lijing Xie, Xin Hu, Tao Wang. Investigation of cutting forces, surface integrity, tool wear when high-speed milling of high volume fraction SiCp/Al6063 composites in PCD tooling[J]. International Journal of Advanced Manufacturing Technology, 2018, 98(5-8):1237-1251. SCI[11] Junfeng Xiang, Lijing Xie, Feinong Gao, Yu Zhang, Jie Yi, Siqin Pang, Xibin Wang. On multi-objective based constitutive modelling methodology and Numerical validation in small-hole drilling of Al6063/SiCp composites[J]. Materials, 2017, 11(1):97. SCI[12] Junfeng Xiang, Lijing Xie, Shaker A. Meguid, Siqin Pang, Jie Yi, Yu Zhang, Ruo Liang. An atomic-level understanding of the strengthening mechanism of aluminum matrix composites reinforced by aligned carbon nanotubes[J]. Computational Materials Science, 2017, 128:359-372. SCI[13] Junfeng Xiang, Siqin Pang, Lijing Xie, Guanhua Cheng, Ruo Liang, Feinong Gao. A numerically low-cost and high-accuracy periodic FE modelling of shot peened 34CrNiMo6 and experimental validation[J]. International Journal of Advanced Manufacturing Technology, 2018, 97(5-8): 1673-1685. SCI[14] Jian Luo, Junfeng Xiang, Dejia Liu, Fei Li, Keliang Xue. Radial friction welding interface between brass and high carbon steel[J]. Journal of Materials Processing Technology, 2012, 212(2):385-292. SCI授权国家发明专利：[1]    用于复合材料加工的多用途工具、辅助设备及使用方法. ZL201710553132.0[2]   用于改善复合材料加工质量的复合加工方法及加工工具. ZL201710553131.6[3]    一种基于切屑分离裂纹扩展策略的钻削高效建模方法，ZL202010412789.7[4]    一种用于大平面大切深高效铣削的盘铣刀，ZL202010412880.9[5]    一种用于切削加工中切屑形成的极限剪切应力确定方法，ZL202010412092.X[6]    一种基于材料塑性本构的槽加工铣削力预测方法，ZL202010412770.2[7]    一种面向高速切削加工的复合材料塑性本构建模方法，ZL202010412819.4[8]    一种厚度非均匀变化的薄壁铣削装置的控制方法. ZL201910086555.5[9]    一种具有微小薄壁防变形功能的铣削装置. ZL201910051617.9[10]  一种介观尺度下微小曲叶轮的铣削装置. ZL201910051632.3[11]  一种循环冷却的微型发动机. ZL201910264700.4[12]  一种发动机缸体加工装置. ZL201910264688.7[13]  一种微型涡喷发动机燃油阻流雾化喷嘴结构. ZL201910264674.5[14]  一种曲线式微通道冷板的加工方法. ZL201910086554.0[15]  一种双铣刀铣削装置. ZL201910087427.2[16]  一种基于像素理论的颗粒增强复合材料有限元建模方法.  ZL201711106783.1 [17]  一种用于复合材料本构公式参数确定的多目标优化方法.  ZL201710395720.6[18]  一种基于依赖性的集成唯象本构的多目标优化方法. ZL201710933397.3[19]  考虑微观组织界面的颗粒增强复合材料有限元建模方法. ZL201710957057.4[20]  一种微细切削测量转换装置及其公差预测方法. ZL201610012230.9[21]  一种介观尺度弹性薄壁件变形在线预测及补偿方法. ZL201610810762.7授权软件著作权：[1]  基于机器学习的超声滚压加工表面完整性预测软件V1.0 [2]  基于机器学习的超声滚压加工疲劳寿命预测软件V1.0 [3]  基于Python语言的abaqus正交自由切削参数化仿真系统V1.0[4]  基于Python语言的二维切削参数化仿真插件V1.0[5]  基于Visual Basic语言的麻花钻参数化建模程序V1.0[6]  基于Visual Basic语言的球头立铣刀参数化建模程序V1.0[7]  基于 Fortran编程语言的3D超声辅助铣削薄壁件仿真系统V1.0[8]  基于Python语言的多相材料切削仿真系统V1.0[9]  基于Python语言的三维钻削仿真软件V1.0[10]  加工SiC/Al复合材料金刚石刀具磨损三维仿真软件V1.0[11]  考虑测量误差加权的复合材料本构方程参数确定的多目标优化软件V1.0[12] 二维复合材料微观界面构建程序V1.0[13] 基于ABAQUS平台和Python语言的随机弹丸三维喷丸仿真系统  V1.0[14] 基于DEFORM平台和Fortran语言的三维超声辅助钻削仿真系统V1.0[15] 一种通用的本构模型材料参数确定软件V1.0[16] 考虑测量误差加权的复合材料本构方程参数确定的多目标优化软件V1.1[17] 基于DEFORM平台和Fortran语言的硬质合金刀具三维磨损仿真系统V1.0[18] 颗粒增强复合材料有限元几何建模软件V1.0

荣誉获奖

荣誉获奖 Awards Information 2018年北京理工大学优秀博士学位论文2015年重庆市优秀硕士学位论文2013年重庆大学优秀硕士学位论文

科学研究

社会兼职 Social Appointments 中国航空学会会员中国机械工程学会会员中国仿真学会会员国际学术期刊审稿人：International Journal of Advanced Manufacturing TechnologyJournal of Materials Processing TechnologyMaterials & Design

学术成果

综合介绍