Feedrate scheduling method for constant peak cutting force in five-axis flank milling process 被引量：8

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摘要 It is extremely important to select appropriate feedrates for the stable machining of parts with ruled surface in modern aviation industrial applications.However,the current studies take too much time to achieve this goal.Therefore,this paper presents an efficient feedrate optimization method for constant peak cutting force in five-axis flank milling process.The solution method of the instantaneous undeformed chip thickness(IUCT)is proposed using least squares theory with the cutter entry angle and feedrate as variables.Based on this method,an explicit analytical expression of the peak cutting force for each cutting point is established.Furthermore,a feedrate scheduling method is developed to quickly solve the appropriate feedrate under constant peak cutting force.To verify the proposed IUCT model,the fitting IUCT is compared with the accuracy data at different feedrates.Additionally,some experiments of five-axis flank milling are conducted to demonstrate the effectiveness of the peak force model and the feedrate scheduling method.And the surface roughness before and after feedrate scheduling is detected.The results show that the proposed feedrate scheduling method can quickly adjust the feedrate and ensure constant peak force during machining.At the same time,the surface quality is kept at a high level.

作者 Liping WANG Xing YUAN Hao SI Feiyu DUAN

机构地区 School of Mechanical and Electrical Engineering Department of Mechanical Engineering

出处《Chinese Journal of Aeronautics》 SCIE EI CAS CSCD 2020年第7期2055-2069,共15页 中国航空学报（英文版）

基金 co-supported by the Major National S&T Program(2017ZX04002001) the Major National S&T Program(2016ZX04004004)。

关键词 Cutter runout Feedrate scheduling Force control Instantaneous undeformed chip thickness Peak cutting force

分类号 V26 [航空宇航科学与技术—航空宇航制造工程]

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参考文献3

1Liping WANG,Hao SI,Liheng GU.Prediction of cutting forces in flank milling of parts with non-developable ruled surfaces[J].Chinese Journal of Aeronautics,2019,32(7):1788-1796. 被引量：6
2WAN Min ZHANG Wei-hong TAN Gang QIN Guo-hua.New Cutting Force Modeling Approach for Flat End Mill[J].Chinese Journal of Aeronautics,2007,20(3):282-288. 被引量：9
3Wu Baohai,Yan Xue,Luo Ming,Gao Ge.Cutting force prediction for circular end milling process[J].Chinese Journal of Aeronautics,2013,26(4):1057-1063. 被引量：19

二级参考文献22

1Sutherland J W,De Vor R E.An improved method for cutting force and surface error prediction in flexible end milling systems.Transactions of the ASME Journal of Engineering for Industry 1986; 108(4):269-279.
2Wan M,Zhang W H.Calculations of chip thickness and cutting forces in flexible end milling.International Journal of Advanced Manufacturing Technology 2006; 29(7):637-647.
3Wang J J,Liang S Y.Chip load kinematics in milling with radial cutter runout.Transactions of the ASME Journal of Engineering for Industry 1996; 118(1):111-116.
4Armarego E J A,Despande N P.Computerized predictive cutting model for cutting forces in end-milling including eccentricity effects.Annals of the CIRP 1989; 38(1):45-49.
5Zheng L,Liang S Y.Identification of cutter axis tilt in end milling.Transactions of the ASME Journal of Manufacturing Science and Engineering 1997; 119(2):178-185.
6Wang J J,Zheng C M.Identification of cutter offset in end milling without a prior knowledge of cutting coefficients.International Journal of Machine Tools and Manufacture 2003; 43(7):687-697.
7Ko J H,Yun W S,Cho D W,et al.Development of a virtual machining system,part 1:approximation of the size effect for cutting force prediction.International Journal of Machine Tools and Manufacture 2002; 42(15):1595-1605.
8Budak E,Altintas Y.Modeling and avoidance of static form errors in peripheral milling of plates.International Journal of Machine Tools and Manufacture 1995; 35(3):459-476.
9Wan M,Zhang W H,Qiu K P,et al.Numerical prediction of static form errors in peripheral milling of thin-walled workpieces with irregular meshes.Transactions of the ASME Journal of Manufacturing Science and Engineering 2005; 127(1):13-22.
10Sarhan A,Sayed R,Nassr A A,et al.Interrelationships between cutting force variation and tool wear in end-milling.Journal of Materials Processing Technology 2001; 109(3):229-235.

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1李玉炜,孙友松.顺逆铣对表面粗糙度影响的轨迹包络几何分析和实验验证[J].制造技术与机床,2014(6):110-113. 被引量：5
2刘璨,吴敬权,李广慧,谭光宇.基于单刃铣削力峰值的铣刀偏心辨识[J].机械工程学报,2013,49(1):185-190. 被引量：4
3吴世雄,钟文斌,栾陆杰,李开柱.拐角高速铣削切削力正交试验研究[J].现代制造工程,2013(2):6-8.
4吴世雄,栾陆杰,钟文斌,李开柱.拐角高速加工铣削力预测[J].现代制造工程,2013(5):7-10. 被引量：6
5Investigation of Cutting Force by End Milling Operation[J].Journal of Mechanics Engineering and Automation,2014,4(1):91-95.
6高鑫,李迎光,张臣,刘长青,郝小忠.飞机结构件内型转角一体加工刀轨生成方法[J].航空学报,2014,35(9):2660-2671. 被引量：7
7刘守法,周兆峰,吴松林.端铣加工面尺寸误差预测[J].机床与液压,2015,43(7):89-91. 被引量：1
8罗智文,赵文祥,焦黎,王西彬,谭方浩,刘志兵,梁志强.平面曲线端铣加工过程铣削力的建模与预测[J].兵工学报,2015,36(9):1727-1735. 被引量：5
9曲胜,赵吉宾,田凤杰,齐根想.平头铣刀圆形铣削的切削力预测[J].机械设计与制造,2015(12):48-50. 被引量：5
10罗智文,赵文祥,焦黎,高守锋,刘志兵,颜培,王西彬.基于斜角切削的曲线端铣切削力建模[J].机械工程学报,2016,52(9):184-192. 被引量：14

同被引文献49

1郑金兴,张铭钧,孟庆鑫.铣削加工过程监测和优化智能系统开发[J].仪器仪表学报,2007,28(S1):74-78. 被引量：1
2柳万珠,刘强.切削加工过程的在线监测与自适应控制[J].航空制造技术,2012,55(14):86-90. 被引量：7
3BI QingZhen,WANG YuHan,ZHU LiMin,DING Han.Wholly smoothing cutter orientations for five-axis NC machining based on cutter contact point mesh[J].Science China(Technological Sciences),2010,53(5):1294-1303. 被引量：14
4孙玉文,束长林,刘健.基于矢量分析的数控加工轨迹设计方法研究[J].机械工程学报,2005,41(3):160-164. 被引量：5
5赖兴余,叶邦彦,鄢春艳,李伟光.基于现场总线的铣削加工过程自适应模糊控制[J].华南理工大学学报（自然科学版）,2005,33(5):7-10. 被引量：5
6李曦,曹为.基于RBF神经网络的恒铣削功率控制的研究[J].机械,2006,33(12):22-24. 被引量：4
7林献坤,李爱平,张为民.应用基于学习的模糊逻辑智能选择铣削加工参数[J].中国机械工程,2007,18(9):1076-1080. 被引量：3
8唐普洪,王忠伟.CNC数控加工OMAT优控系统综述[J].CAD/CAM与制造业信息化,2007(5):108-111. 被引量：1
9雷萍.基于现场总线的恒功率约束切削加工自适应控制[J].现代制造工程,2007(7):40-42. 被引量：3
10黄华,李爱平,林献坤.基于恒功率约束的自适应加工控制系统开发[J].同济大学学报（自然科学版）,2008,36(7):956-961. 被引量：12

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2徐金亭,牛金波,陈满森,孙玉文.精密复杂曲面零件多轴数控加工技术研究进展[J].航空学报,2021,42(10):24-47. 被引量：43
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4王志学,陈强,宫丽,李敏,刘万村.切削加工参数优化及自适应控制技术综述[J].电子技术（上海）,2022,51(3):67-69. 被引量：1
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6Yuwen SUN,Jinjie JIA,Jinting XU,Mansen CHEN,Jinbo NIU.Path,feedrate and trajectory planning for free-form surface machining:A state-of-the-art review[J].Chinese Journal of Aeronautics,2022,35(8):12-29. 被引量：15
7王清辉,王金强,丁雪松,廖昭洋.型腔恒负载加工的组合轨迹设计与进给速度优化[J].华南理工大学学报(自然科学版),2025,53(5):1-10. 被引量：1
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1朱奕纯,杨科文.解决数控铣削冰墩墩和叶轮加工难点的实践研究[J].工程机械文摘,2023(2):21-25. 被引量：1
2郑绍芸.数控多轴正逆向制造实训基地建设探索[J].内燃机与配件,2021(4):221-222. 被引量：1
3李泽亚,罗敏,孙国浩,柴进平,廖骏,张瑞杰.基于边缘控制器的恒功率切削控制[J].湖北汽车工业学院学报,2022,36(1):66-69. 被引量：2
4卢耀安,陈守峰,王成勇.鼓形铣刀侧铣加工叶盘叶片曲面的光顺刀具路径生成方法[J].机械工程学报,2022,58(1):256-266. 被引量：12
5陶广福,张宝磊,赵靖,王斌武,赵灿,孟祥林.基于模糊层次分析法的颤振稳定极限区域工程优化选择[J].机床与液压,2022,50(9):112-118.
6李婷.机械数控加工技术水平提升策略[J].造纸装备及材料,2022,51(2):121-123. 被引量：4
7武鑫磊,刘永红,亓梁,赵莅龙,纪仁杰.镍基高温合金电火花辅助电弧高效铣削技术[J].航空学报,2022,43(4):366-375. 被引量：9
8金鑫,刘其广,吕杰,徐飞飞,孙晓楠.基于三角网格曲面的机器人磨削工具姿态光顺优化[J].制造技术与机床,2022(9):47-51. 被引量：3
9金鑫,刘其广,吕杰,徐飞飞.考虑最优方向匹配的高效走刀轨迹生成方法[J].机械科学与技术,2022,41(8):1211-1215.
10张江兆,汤辉亮,王楚,吴晓暄,龙雨.复杂结构的多轴无支撑3D打印的工艺规划算法研究最新进展和展望[J].中国激光,2022,49(14):202-222. 被引量：5

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2Yang Miao,Xiang Guo,Xiao-Jun Zhang.Visualization of Fiber Moving in Air Tunnel with Velocity Gradient[J].Chinese Physics Letters,2020,37(3):13-16.
3Xiaojun Hu,Xian Li,Ronald Rousseau.Describing Citations as a Function of Time[J].Journal of Data and Information Science,2020,5(2):1-12.
4Qi-Sen Chen,Li Dai,Yu Liu,Qiu-Xiang Shi.A cortical bone milling force model based on orthogonal cutting distribution method[J].Advances in Manufacturing,2020,8(2):204-215. 被引量：7
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Chinese Journal of Aeronautics

2020年第7期

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