BTA深孔钻削刀具系统刚性差,加工过程极易发生多个方向的颤振,而刀具颤振对孔的加工精度和刀具的使用寿命具有重要影响。根据错齿BTA内排屑深孔钻刀具系统的特点,构建了深孔钻削过程刀具系统径向动力学模型,通过其特征方程研究了径向动力学特性。为了获得普通钻削与振动钻削条件下刀具系统径向振动的行为特征,将切削加工过程离散为满足状态方程连续条件的多个微小切削单元,并采用差分方程求解方法给出了普通钻削与振动钻削过程刀具径向振动位移的数值解。仿真和实验结果表明,所建立径向动力学模型的求解结果与实验结果相吻合,振动钻削对刀具系统径向振动具有较强的抑制效果,与普通钻削相比,孔加工圆度和表面粗糙度都有了明显改善。
Abstract
Because of the poor rigidity of a tool system of boring and trepanning association(BTA) deep hole drilling, machining processes are prone to chatter occuring in several directions, which has a significant impact on the machining accuracy of the hole and the service life of the tool.According to the tool system characteristics, the radial dynamic model for the BTA deep-hole drilling system in drilling process was established and its dynamic characteristics were further studied by using the characteristic equation.In order to obtain the behavior characteristics of the radial vibration of the tool system in condition of common drilling and vibration drilling, the cutting process was discretized into multiple tiny cutting units which meet the continuous condition of the state equation, and the radial vibration displacements of the cutting tool system were solved by the numerical method for difference equations.The simulation and experimental results show that the solutions of the established radial dynamics model are consistent with the experimental results.Vibration drilling has a strong restraining effect on the radial vibration of the tool system.Compared with the conventional drilling, the hole machining roundness and surface roughness are significantly improved.
关键词
深孔加工 /
颤振 /
振动钻削 /
切削单元 /
数值仿真
{{custom_keyword}} /
Key words
deep-hole drilling /
vibrating drilling /
chatter /
cutting unit /
numerical simulation
{{custom_keyword}} /
{{custom_sec.title}}
{{custom_sec.title}}
{{custom_sec.content}}
参考文献
[1] Weinert K, Webber O, Peters C. On the influence of drilling depth dependent modal damping on chatter vibration in BTA deep hole drilling[J]. CIRP Annals-Manufacturing Technology, 2005, 54(1): 363-366.
[2] 孔令飞,李言,吕延军,等. 深孔加工刀具系统的动态稳定域研究[J]. 兵工学报,2013, 34(5): 611-619.
KONG Ling-fei, LI Yan, LYU Yan-jun, et al.The dynamic stable region of drilling tools system in deep hole driling[J]. Acta Armamentarii, 2013, 34(5): 611-619.
[3] 孔令飞,李言,吕延军. BTA深孔加工钻杆系统的稳定性及分岔[J]. 兵工学报, 2009, 30(12): 1684-1690.
KONG Ling-fei, LI Yan, LYU Yan-jun.Stability and bifurcation of the drilling shaft system in processing deep hole based on boring and trepanning association[J]. Acta Armamentarii, 2009, 30(12): 1684-1690.
[4] Bayly P V, Lamar M T, Calvert S G. Low-Frequency Regenerative Vibration and the Formation of Lobed Holes in Drilling[J]. Journal of Manufacturing Science & Engineering, 2002, 124(2):163-171.
[5] Biermann D, Sacharow A, Wohlgemuth K. Simulation of the BTA deep-hole drilling process[J]. Production Engineering, 2009, 3(4-5):339-346.
[6] Chin D H, Yoon M C, Sim S B. Roundness modeling in BTA deep hole drilling[J]. Precision Engineering, 2005, 29(2):176-188.
[7] Matsuzaki K, Ryu T, Sueoka A, et al. Theoretical and experimental study on rifling mark generating phenomena in BTA deep hole drilling process (generating mechanism and countermeasure)[J]. International Journal of Machine Tools & Manufacture, 2015, 88:194-205.
[8] Mehrabadi I M, Nouri M, Madoliat R. Investigating chatter vibration in deep drilling, including process damping and the gyroscopic effect[J]. International Journal of Machine Tools & Manufacture, 2009, 49(12):939-946.
[9] Roukema J C, Altintas Y. Generalized modeling of drilling vibrations. Part I: Time domain model of drilling kinematics, dynamics and hole formation[J]. International Journal of Machine Tools & Manufacture, 2007, 47(9):1455-1473.
[10] Chyn-Shu Deng, Jih-Hua Chin. Roundness Errors in BTA Drilling and a Model of Waviness and Lobing Caused by Resonant Forced Vibrations of Its Long Drill Shaft[J]. Journal of Manufacturing Science and Engineering, 2004, 126( 3) : 524-534.
[11] 郑建明,肖继明,李言,等. 振动攻丝切削力及加工精度的研究[J]. 西安理工大学学报, 2000, 16(4): 339-343.
ZHENG Jian-ming, XIAO Ji-ming, LI Yan, et al. Study on cutting force and machining precision of vibratory tapping[J]. Journal of Xi'an University of Technology, 2000, 16(4): 339-343.
[12] Jin X, Koya N G. Prediction of Coupled Torsional-Axial Vibrations of Drilling Tool With Clamping Boundary Conditions[C]// ASME 2016, International Manufacturing Science and Engineering Conference. 2016:V002T04A043.
[13] 孔繁森,刘鹏,王晓明. 切削振动加速度时间历程演化过程的动力学特征[J]. 振动与冲击, 2011, 30(7): 10-15.
KONG Fan-sen, LIU Peng, WANG Xiao-ming. Dynamic characteristics of evolution process of the cutting vibration acceleration time history[J]. Journal of Vibration and Shock, 2011, 30(7): 10-15.
[14] 佟富强, 张勇, 张飞虎,等. 振动切削中应力波对裂纹及成屑机理影响研究[J]. 振动与冲击, 2008, 27(6):136-139.
TONG Fu-qiang, ZHANG Yong, ZHANG Fei-hu, et al. Study on the effect of stress wave on crack and chip mechanism in vibration cutting[J]. Journal of Vibration and Shock, 2008,27 (6): 136-139.
[15] 师毓华,郑建明,侯晓莉,等. BTA深孔钻削切屑变形与刀齿切削力分布规律仿真[J]. 宇航材料工艺, 2014, 44(5): 36-40.
SHI Yu-hua, ZHENG Jian-ming, HOU Xiao-li, et al. Simulation of chip deformation and cutting force distribution of BTA deep hole drilling[J]. Aerospace Materials & Technology. 2014, 44(5): 36-40.
[16] Weinert K, Weihs C, Webber O, et al. Varying bending eigenfrequencies in BTA deep hole drilling: mechanical modeling using statistical parameter estimation[J]. Production Engineering, 2007, 1(2):127-134.
[17] Griffiths B J. Modelling Complex Force Systems, Part 1: The Cutting and Pad Forces in Deep Drilling[J]. Journal of Engineering for Industry, 1993, 115(2):169-176.
[18] 孔令飞,李言,郑建明,等. 基于剪力模式的深孔钻杆制振器设计与试验研究[J]. 机械工程学报,2014, 50(5): 201-207.
[19] Bayly P V, Lamar M T, Calvert S G. Low-frequency regenerative vibration and the formation of lobed holes in drilling [J]. Journal of Manufacturing Science and Engineering, 2002, 124( 2): 275-285.
[20] Tlusty J. Dynamics of high-speed milling [J]. Journal of Manufacturing Science and Engineering, 1986, 108(2): 59-67.
{{custom_fnGroup.title_cn}}
脚注
{{custom_fn.content}}
PDF(2126 KB)
