学术论文

[33] Zhang X*, Wang X, Cao F, Zhang P. Quasi-real-time monitoring of variable milling parameters during multi-axis machining [J]. Mechanical Systems and Signal Processing, 2024, 211: 111196.
[32] Zhang X*, Wang X, Zhang P, Chen K,  Cao F. Fast extraction of cutter-workpiece engagement for milling force prediction in multi-axis machining [J]. Measurement, 2024, 231: 114490.
[31] Zhang W, Zhang X,  Zhao W*. Research on the multi-physical coupling characteristics of the machine tool and milling process based on the systematically integrated model [J]. Journal of Manufacturing Processes, 2023, 105, 46-69.

[30] Wang X, Zhang X*, Zhang W, Zhang P, Chen K. Boolean operation-based fast calculation of cutter-workpiece engagement during peripheral milling [C],17th International Conference on High Speed Machining, MM Science Journal, October 25-28, 2023, Nanjing, China.

[29] Zhang W, Zhang X, Zhao W*. Influence of nonlinearity of servo system electrical characteristics on motion smoothness of precision CNC machine tools [J]. Precision Engineering, 2023,83: 82-101.

[28] Chen K, Zhao W, Zhang X*. Real-time milling force monitoring based on a parallel deep learning model with dual-channel vibration fusion [J]. The International Journal of Advanced Manufacturing Technology, 2023, 126: 2545–2565. 

[27] Zhang W, Zhang X, Jin X, Zhang H, Zhao W*. Dynamic modeling and harmonic analysis of surface-mounted three-phase AC permanent magnet synchronous motor [J]. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science, 2023 0(0). doi:10.1177/09544062221147485.

[26] Chen K, Zhang X, Zhao W*. Automatic feature extraction for online chatter monitoring under variable milling conditions [J]. measurement, 2023(210)112558.

[25] Pan  T, Zhang J, Zhang X, Zhao W*, et al. Milling force coefficients-based tool wear monitoring for variable parameter milling [J]. The International Journal of Advanced Manufacturing Technology, 2022, 120: 4565-4580. 

[24] Zhang X,Gao Y,Guo Z,Zhang W,Jin J,Zhao W. Physical model-based tool wear and breakage monitoring in milling process [J]. Mechanical Systems and Signal Processing,2022,184:109641. 

[23] Zhang X,  Wang X,  Zhao Z,  Chen K,  Yin J,  Zhao W. A general on‑machine non‑contact calibration method for milling cutter runout [J]. The International Journal of Advanced Manufacturing Technology,https://doi.org/10.1007/s00170-022-09087-2.

[22] Zhang X, Zhao Z, Chen K, Zhao W. Generalized modeling of milling dynamics for the 4DOF machining system with asymmetric flexibility [J]. Mechanical Systems and Signal Processing,2022, 169(11):108750. doi: 10.1016/j.ymssp.2021.108750.

[21] Zhang X, Pan T, Ma A, Zhao W. High efficiency orientated milling parameter optimization with tool wear monitoring in roughing operation [J]. Mechanical Systems and Signal Processing, 2021, 165, 108394. doi: 10.1016/j.ymssp.2021.108394.

[20] Zhang X, Chen K, Wang Z, Zhao W. Feed direction-dependent milling dynamics of an asymmetric flexible machining system [J]. Journal of Manufacturing Science and Engineering-Transaction of the ASME, 2021, 1-13. doi: 10.1115/1.4052801.

[19] Zhang X, Zhao Z, Guo Z, Zhao W. Research on machining parameter optimization in finishing milling with multiple constraints [J]. Proceedings of the Institution of Mechanical Engineers, Part B Journal of Engineering Manufacture, 2021, 1-13. doi: 10.1177/09544054211057989.

[18] Zhang X, Yang L, Zhao Z, Yin, J. Research on the excitation characteristics of milling force for a general helix cutter [J]. The International Journal of Advanced Manufacturing Technology, 2021: 1-16.

[17] Yang L, Zhang X*, Wang L, Zhao W. Dynamic error of multi-axis machine tools considering position dependent structural dynamics and axis coupling inertial forces [J]. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, 2021, 09544054211028488.

[16] Chen K, Zhang X*, Zhao Z, Zhao W. Milling chatter monitoring under variable cutting conditions based on time series features [J]. The International Journal of Advanced Manufacturing Technology, 2021, 113: 2595–2613.

[15] 尹佳, 安攀, 张威振, 张星, 张俊, 赵万华. 五轴机床刀尖点频响特性及切削稳定域位置的演变 [J]. 机床与液压, 2020, 49(18): 22-27.

[14] Zhang X, Zhang W, Zhang J, et al. Systematic study of the prediction methods for machined surface topography and form error during milling process with flat end cutter [J]. Proceedings of the iMeche, Part B: Journal of Engineering Manufacture, 2019: 0954405417740924.

[13] Zhang W, Zhang X, Zhang J, Zhao W. Analysis of Lead Screw Pre-Stretching Influences on the Natural Frequency of Ball Screw Feed System [J]. Precision Engineering, 2019, 57(2): 30~44. doi: 10.1016/j.precisioneng.2019.03.003.

[12] Zhang X, Zhang J, Zhang W, et al. Integrated modeling and analysis of ball screw feed system and milling process with consideration of multi-excitation effect [J]. Mechanical Systems and Signal Processing, 2018, 98: 484~505.

[11] Zhang X, Zhang W, Zhang J, et al. General modeling and calibration method for cutting force prediction with flat-end cutter [J]. Journal of Manufacturing Science and Engineering-Transaction of the ASME, 2018, 140(2): 021007.

[10] Zhang X, Zhang W, Zhang J, et al. A non-contact calibration method for cutter runout with spindle speed dependent effect and analysis of its influence on milling process [J]. Precision Engineering, 2018, 51: 280~290.

[9] Song D, Xue F, Wu D, Zhang J, Zhang X, Zhao W, Lu B. Iso-parametric path-planning method of twin-tool milling for turbine blades [J]. The International Journal of Advanced Manufacturing Technology, 2018, 98(9): 3179–3189. doi: 10.1007/s00170-018-2461-4.

[8] Liang T, Zhang X, Zhao WH. An investigation of spectral characteristic of displacement fluctuation and its effect on surface quality in precision machining [J]. The International Journal of Advanced Manufacturing Technology (2018): 1-11.

[7] 张俊,王拓,张星等. 超密齿面铣刀的铣削力波动特性及其影响[J]. 东北大学学报 (自然科学版), 2018, 39(4): 543~548.

[6] 赵万华,张星,吕盾,张俊. 国产数控机床的技术现状与对策[J]. 航空制造技术,2018, 504(9): 16~22.

[5] Zhang X, Zhang J, Zheng XW, et al. Tool orientation optimization of 5-axis ball-end milling based on an accurate cutter/workpiece engagement model [J]. CIRP Journal of Manufacturing Science and Technology, 2017, 19: 106~116.

[4] Zhang X, Zhang J, Pang B, et al. An accurate prediction method of cutting forces in 5-axis flank milling of sculptured surface [J]. International Journal of Machine Tools and Manufacture, 2016, 104:26~36.

[3] Zhang X, Zhang J, Bo Pang, et al. An efficient approach for milling dynamics modeling and analysis with varying time delay and cutter runout effect [J]. The International Journal of Advanced Manufacturing Technology, 2016, 87(9~12): 3373-3388.

[2] Zhang X, Zhang J, Zhao WH. A new method for cutting force prediction in peripheral milling of complex curved surface [J]. The International Journal of Advanced Manufacturing Technology, 2015, 86(1-4): 117~128.

[1] 卢秉恒,赵万华,张俊,张星等. 高速高加速度下的进给系统机电耦合[J]. 机械工程学报,49(6) (2013): 2~11.

发明专利

[15] 张星,赵万华. 一种五轴联动铣削过程的动力学集成建模与精度预测方法. 发明专利. 申请日期:2021.11.8. 申请号:202111316259.3
[14] 张星,赵万华, 赵钊,高洋. 一种融合刀具磨损监测的难加工材料粗加工高效铣削参数优化方法. 发明专利. 申请日期:2021.11.2. 申请号:202111286175.X
[13] 张星,赵万华, 郭卓城,赵钊. 一种无颤振精加工铣削过程的高效参数优化方法. 发明专利. 申请日期:2021.11.2. 申请号:202111286179.8
[12] 张星,赵钊,杨磊,马昂扬,赵万华. 一种五轴AC转摆头龙门机床几何误差建模及分离方法. 发明专利. 申请日期:2020.11.19. 专利号:ZL202011304180.4
[11] 张星,张伟,赵钊,赵万华,尹佳. 一种单轴进给系统铣削过程的动力学集成建模方法. 发明专利. 申请日期:2020.9.12. 专利号:ZL202010956712.6
[10] 张星,张伟,湛承鹏,赵万华,尹佳. 一种单轴滚珠丝杠进给系统运动特性的机电联合建模方法. 发明专利. 申请日期:2020.9.12. 申请号:202010956741.2
[9] 张星,陈昆弘,闫文彪,赵万华,尹佳. 一种面向无颤振高效铣削的主轴转速自适应调整方法. 发明专利. 申请日期:2020.5.21. 专利号:ZL202010435891.9
[8] 张星,潘天航,赵万华,赵钊,尹佳. 一种铣刀偏心参数的通用在机非接触标定方法. 发明专利. 申请日期:2020.5.21. 专利号:ZL202010435358.2
[7] 张星,潘天航,赵万华,闫文彪,张俊,尹佳. 一种基于主轴振动特征融合的刀具磨破损实时监测方法. 发明专利. 申请日期:2020.5.21. 专利号:ZL202010435340.2

[6] 张俊,郭登刚,赵万华,张星. 一种基于数控宏程序的毛坯在机快速找正方法. 发明专利. 申请日期:2019.7.17. 申请号:201910645046.1

[5] 张俊,路壮壮,苏东旭,赵万华,张星,刘占.基于机器视觉的整体式螺旋铣刀磨破损图像采集装置及方法. 发明专利. 专利号:ZL2019105573712

[4] 张俊,杨帆,尹佳,唐宇阳,张星,赵万华, 一种基于组合加工特征的结构件加工参数计算方法. 发明专利. 专利号:ZL2019104689478

[3] 张俊,杨帆,郑小伟,唐宇阳,张星,赵万华, 一种基于零件刚度衰减的结构件加工顺序评价方法. 发明专利. 专利号:ZL2019104695322

[2] 张俊,郭登刚,赵万华,张星. 一种基于三维反求的复杂结构件毛坯加工定位方法. 发明专利. 申请日期:2018.7.5. 申请号:201810732779.4

[1] 赵万华,张星,张俊,庞博. 一种螺旋铣刀五轴加工铣削力精确预测方法. 发明专利. 申请日期:2015.12.30. 专利号:ZL201511024364.4

软件著作

[15] 钟宏、张星,马昂扬,潘天航,赵万华. 航空结构件典型加工特征铣削参数优化软件[CP]. 申请日期:2020.8.29. 登记号:2020SR1564552.

[14] 钟宏、张星,赵钊,陈昆弘,赵万华. 铣刀-工件材料对比切力系数辨识软件[CP]. 申请日期:2020.10.13. 登记号:2020SR1213704.

[13] 张星,赵钊,马昂扬,王增光,赵万华. 铣削过程刀具-工件啮合区计算软件[CP]. 申请日期:2020.7.21. 登记号:2020SR1121028.
[12] 马昂扬,张星,王增光,赵万华,闫文彪. 柔性刀具-工件系统铣削稳定性计算软件[CP]. 申请日期:2020.6.29. 登记号:2020SR1053425.

[11] 王增光,张星,马昂扬,赵万华,闫文彪. 铣削过程通用刀具铣削力计算软件[CP]. 申请日期:2020.6.3. 登记号:2020SR1055416.

[10] 闫文彪,张星,赵万华,潘天航,陈昆弘. 数控机床典型运行数据外置传感器采集系统[CP]. 申请日期:2020.6.1. 登记号:2020SR0859295.

[9] 王艺,张星,赵万华,苏东旭,赵钊. 基于球杆仪的机床旋转轴几何误差辨识软件[CP]. 申请日期:2020.5.6. 登记号:2020SR0549594.

[8] 王艺,张星,赵万华,苏东旭,蔡欣. 基于激光跟踪仪的机床平动轴几何误差辨识软件[CP]. 申请日期:2020.4.6. 登记号:2020SR0549587.

[7] 王艺,张星,赵万华,赵钊,苏东旭. 基于NC程序修正的数控机床几何误差补偿软件[CP]. 申请日期:2020.3.6. 登记号:2020SR0549579.

[6] 张俊,郭登刚,赵万华,张星. 工件自适应找正定位软件[CP]. 申请日期:2018.11.6. 登记号:2019SR0235456.

[5] 张俊,郭登刚,赵万华,张星. 毛坯在机测量找正宏程序编制软件[CP]. 申请日期:2018.11.1. 登记号:2019SR0851759.

[4] 张星,赵万华,张俊,庞博. 螺旋立铣刀铣削过程稳定性预测软件[CP]. 申请日期:2015.11.15. 登记号:2016SR071387.

[3] 张星,赵万华,张俊,庞博. 铣削过程螺旋立铣刀铣削力计算软件[CP]. 申请日期:2015.10.30. 登记号:2016SR046450.

[2] 赵万华,刘军,张星,张俊. 汽轮机叶片加工参数查询与优化系统[CP]. 申请日期:2014.3.9. 登记号:2014SR145574.

[1] 张俊、黄保华、杜超、张星、赵万华. 数控铣床切削稳定性判定系统软件[CP]. 申请日期:2011.12.27. 登记号:2012SR110178.