FEM-based Frequency Reliability Analysis of Spindle System of CNC Lathes

doi:10.12068/j.issn.1005-3026.2015.08.020

Abstract

Abstract: Based on the finite element method， we created a parametric three-dimension finite element model for spindle system and simplified the bearing as elastic support. Taken pulley and chuck into consideration， modal analysis of the entire system was conducted， thus the natural frequencies of the first eight vibrations and the corresponding spindle vibration modes were acquired. Critical speed of rotation was analyzed. We compared the working speed with rotation speed of the lowest non-zero set of frequency， hereby the rationality of design was verified. The ISIGHT integrated with ANSYS was used in designing orthogonal experiment and in calculating the lowest non-zero set of frequency. Diameters and length with tolerance requirements， and basic physical parameters considered as random variables， the BP neural network fitting method was used to get the relationship between the lowest non-zero set of frequency and random variables. The first order second moment (FOSM) method was used to calculate the spindle system reliability with specific rotation speed and reliability sensitivity of random variables.

Key words: spindle system, finite element method, neural network, reliability, reliability sensitivity

CLC Number:

TB122

ZHANG Yi-min， WANG Hao， CAO Hui， YANG Zhou. FEM-based Frequency Reliability Analysis of Spindle System of CNC Lathes[J]. Journal of Northeastern University Natural Science, 2015, 36(8): 1155-1159.

References

[1]Vafaei S，Rahnejat H，Aini R.Vibration monitoring of high speed spindles using spectral analysis techniques［J］.International Journal of Machine Tools and Manufacture，2002，42(11):1223-1234.
[2]Lin C W，Tu J F.Model-based design of motorized spindle systems to improve dynamic performance at high speeds［J］.Journal of Manufacturing Processes，2007，9(2):94-108.
[3]Gong L Q，Jia Y Q，Cheng J J，et al.Analysis of thermal characteristics for a high speed motorized spindle based on the ANSYS workbench［J］.International Journal of Plant Engineering and Management，2013，18(2):96-104.
[4]Shan W T，Chen X A，He Y，et al .A novel experimental research on vibration characteristics of the running high-speed motorized spindles［J］.Journal of Mechanical Science and Technology，2013，27(8):2245-2252.
[5]胡仁喜，康士廷.Ansys14.0机械与结构有限元分析:从入门到精通［M］.北京:机械工业出版社，2013:66-150.(Hu Ren-xi，Kang Shi-ting.ANSYS 14.0 mechanical and structural finite element analysis from entry to mastery［M］.Beijing:China Machine Press，2013:66-150.)
[6]赖宇阳.Isight参数优化理论与实例讲解［M］.北京:北京航空航天大学出版社，2012:1-187.(Lai Yu-yang.Isight parameter optimization theory and examples with details［M］.Beijing:Beihang University Press，2012:1-187.)
[7]Guo C G，Bai L G，Zheng B L，et al.Spindle static and dynamic characteristics analysis of precision CNC turning center ［J］.Advanced Materials Research，2013，619:47-50.
[8]Hou X，Yang C C，Wang S Z.Dynamic modeling and modal analysis of the high-speed winder spindle［J］.Applied Mechanics and Materials，2013，281:263-267.
[9]Wang Z，Wang Z Q，Zhuang L，et al.Time-dependent vibration frequency reliability analysis of blade vibration of compressor wheel of turbocharger for vehicle application［J］.Chinese Journal of Mechanical Engineering，2014，27(1):205-210.
[10]Martin T H，Howard B D，Mark B.Neural network design［M］.Beijing:China Machine Press，2002:12-156.
[11]Gertsbakh I.Reliability theory ［M］.Berlin:Springer，2005:2-80.
[12]吕震宙，宋述芳，李洪双，等.结构机构可靠性及可靠性灵敏度分析［M］.北京:科学出版社，2009:36-89.(Lyu Zhen-zhou，Song Shu-fang，Li Hong-shuang，et al.Reliability and reliability sensitivity analysis of structures and mechanisms［M］.Beijing:Science Press，2009:36-89.)
[13]张义民.机械可靠性设计的内涵与递进［J］.机械工程学报，2010，46(14):167-188.(Zhang Yi-min.Connotation and development of mechanical reliability-based design［J］.Journal of Mechanical Engineering，2010，46(14):167-188.)
[14]Su C Q，Zhang Y M，Zhao Q C.Vibration reliability sensitivity analysis of general system with correlation failure modes［J］.Journal of Mechanical Science and Technology，2011，25(12):3123-3133.

[1]	QIAO Li-ping， LU Wei-li， MIN Zhong-shun， WANG Zhe-chao. Reliability Analysis of Rock Block Stability and Support for Underground Water-Sealed Storage Caverns [J]. Journal of Northeastern University(Natural Science), 2023, 44(4): 544-550.
[2]	LIU Yang， YAN Dong-mei， MENG Fan-wei. Improved Two-Branch Person Re-identification Algorithm Based on Transformer [J]. Journal of Northeastern University(Natural Science), 2023, 44(1): 26-32.
[3]	ZHA Cong-yi， SUN Zhi-li， PAN Chen-rong， WANG Jian. Parallel Adaptive Sampling Strategy for Structural Reliability Analysis [J]. Journal of Northeastern University(Natural Science), 2023, 44(1): 76-82.
[4]	ZHANG Chun-lei， LI He， DONG Mao-lin， ZHANG Sheng-jie. Adaptive Neural Network Sliding Mode Control for the Fuel Cell Air Supply System [J]. Journal of Northeastern University(Natural Science), 2022, 43(9): 1270-1276.
[5]	MA Yuan-yuan， LIU Yan-ze， LIU Cheng-long， ZHANG Tian-jie. Chinese Investors’ Multi-perspective Sentiment Analysis and Its Role in Stock Market Forecasting [J]. Journal of Northeastern University(Natural Science), 2022, 43(8): 1201-1209.
[6]	ZHANG Yu， HE Kai-wen， LI Qing-shu， GONG Ya-dong. Intelligent Decision-Making of Machining Operation Method for STEP-NC-Compliant Freeform Surface Features [J]. Journal of Northeastern University(Natural Science), 2022, 43(7): 981-987.
[7]	JI Ce， ZHANG Xiao. Channel Estimation Algorithm of OFDM System Based on GSA-BP Neural Network [J]. Journal of Northeastern University(Natural Science), 2022, 43(6): 769-775.
[8]	SUN Yao， SUN Zhi-li， ZHOU Jie， WANG Jian. Theoretical Calculation Method of Reliability for Multi-state Phased-Mission Systems [J]. Journal of Northeastern University(Natural Science), 2022, 43(5): 689-695.
[9]	HUANG Xian-zhen， SUN Liang-shi， DING Peng-fei， ZHU Hui-bin. Optimization of Turning Parameters of GH4169 Based on Reliability [J]. Journal of Northeastern University(Natural Science), 2022, 43(5): 696-702.
[10]	YANG Bo-wen， HUO Jun-zhou， ZHANG Wei， ZHANG Zhan-ge. Research on Real-Time Overload Prediction Method of in-Service Structures [J]. Journal of Northeastern University(Natural Science), 2022, 43(4): 541-550.
[11]	FAN Chun-long， LI Yan-da， XIA Xiu-feng， QIAO Jian-zhong. A General Adversarial Attack Method Based on Random Gradient Ascent and Spherical Projection [J]. Journal of Northeastern University(Natural Science), 2022, 43(2): 168-175.
[12]	CHEN Bing， HAN Jin-yang， TANG Xiao-lei， XIA Bo-ran. Prediction Model for Elongation of Tension Leveling Based on Machine Learning Algorithm and Numerical Analysis [J]. Journal of Northeastern University(Natural Science), 2022, 43(2): 236-242.
[13]	JING Yuan-wei， XIE Hai-xiu， BAI Yun. Adaptive Finite-Time Funnel Congestion Control of TCP/AWM Network Systems [J]. Journal of Northeastern University(Natural Science), 2022, 43(10): 1369-1375.
[14]	YANG Zhou， PAK Un-song， KWON Chol-u. Gradual Reliability Sensitivity Analysis of Thermal-Mechanical Coupling of Disc Brakes [J]. Journal of Northeastern University(Natural Science), 2022, 43(1): 48-56.
[15]	WANG Lu， WANG Shuai， ZHANG Guo-feng， XU Li-sheng. Pedestrian Detection Based on Semantic Segmentation Attention and Visible Region Prediction [J]. Journal of Northeastern University(Natural Science), 2021, 42(9): 1261-1267.