Study on Stability of Surface Turning Finishing Processes of Titanium Alloy Wires Based on Process Damping

doi:10.3969/j.issn.1004-132X.2023.16.007

Abstract

Abstract: In view of the slender structural characteristics of titanium alloy wire coil as raw materials for aviation fasteners and the machining difficulties, a centerless lathe was used to finish the surfaces of titanium alloy wire coil. Considering the requirements of high precision surface quality after turning, in order to improve the machining stability of centerless lathe, a multi-degree-of-freedom coupled flutter vibration mechanics model was established considering process damping effect. By solving the model and drawing the stability lobe diagram of the cutter head cutting system of centerless lathe for stability analysis, the stable machinable parameter group was obained. Further analysis of the influences of tool structure parameters shows that when the radius of the tool nose is as 0.1~0.3 mm, the rake angle of the tool is as 1°~2°, and the clearance angle of the tool is as 2°~5°, the stable machinable parameter set with the highest design safety may be obtained. The experimental platform was set up to verify the theoretical analysis results, and the obtained tool structure parameter selection domain and stable machinable parameter set may provide a reference for surface finishing of titanium alloy wire coils.

Key words: centerless lathe, turning finishing process, stable machinable parameter set, tool structure parameter selection domain

摘要： 针对航空紧固件原材料钛合金丝材盘圆细长结构特性和加工难度大的问题，采用无心车床进行钛合金丝材盘圆的表面车削精整加工。考虑车削后高精度表面质量的要求，为提高无心车床的加工稳定性，建立考虑过程阻尼效应的多自由度耦合颤振动力学模型。通过对模型求解，绘制无心车床刀盘切削系统稳定性叶瓣图进行稳定性分析,得到稳定可加工参数组。进一步分析刀具结构参数的影响，刀尖圆弧半径为0.1~0.3 mm、刀具前角为1°~2°和刀具后角为2°~5°时，可以获得设计安全性最高的稳定可加工参数组。通过搭建试验平台验证理论分析结论，所得到的刀具结构参数选择域和稳定可加工参数组可为钛合金丝材盘圆的表面精整加工提供参考。

关键词: 无心车床, 车削精整加工, 稳定可加工参数组, 刀具结构参数选择域

CLC Number:

TH69
TP23

SHI Lichen, ZHANG Qian, LIU Tengfei, LIU Yaxiong, LU Zhuqing. Study on Stability of Surface Turning Finishing Processes of Titanium Alloy Wires Based on Process Damping[J]. China Mechanical Engineering, 2023, 34(16): 1936-1945.

史丽晨, 张倩, 刘腾飞, 刘亚雄, 卢竹青. 基于过程阻尼的钛合金丝材表面车削精整加工稳定性研究[J]. 中国机械工程, 2023, 34(16): 1936-1945.

References

［1］KALPAKZIAN S，SCHMID S R. Manufacturing Engineering & Technology［M］. 4th ed. Upper Saddle River：Prentice-Hall lnc.，2001.
［2］KANG Y S，HASHIMOTO F，JOHNSON S P，et al. Discrete Element Modeling of 3D Media Motion in Vibratory Finishing Process［J］. CIRP Annals：Manufacturing Technology，2017，66(1):313-316.
［3］刘清,张广鹏,高智学,等.X-Y平面联动的平面研磨轨迹分析与研磨实验［J］.机械科学与技术,2018,37(6):903-909.
LIU Qing，ZHANG Guangpeng，GAO Zhixue,et al.Experimental Study of X-Y Linkage Plane Lapping Track［J］.Mechanical Science and Technology for Aerospace Engineering,2018,37(6):903-909.
［4］史丽晨,刘亚雄,史炜椿,等.基于灰色关联分析的GH2132丝材高精度切削参数优化［J］.表面技术,2022,51(11):373-384.
SHI Lichen, LIU Yaxiong,SHI Weichun,et al. Optimization of High-precision Cutting Parameters of GH2132 Wire Based on Grey Relational Analysis［J］. Surface Technology ,2022,51(11):373-384.
［5］史丽晨,杨帆,王海涛.高精度无心车床主轴系统动力学建模研究［J］.机械设计与制造,2021(4):23-28.
SHI Lichen, YANG Fan, WANG Haitao. Research on Dynamic Modeling of Spindle System of High Precision Centerless Lathe［J］. Mechanical Design and Manufacture, 2021(4):23-28.
［6］史丽晨,李进学,刘亚雄,等.TB9钛合金车削系统振动特性与表面粗糙度关系的试验研究［J］.表面技术,2022,51(6):354-363.
SHI Lichen, LI Jinxue, LIU Yaxiong,et al. Experimental Study on the Relationship between Vibration Characteristics and Surface Roughness of TB9 Titanium Alloy Turning System［J］.Surface Technology,2022,51(6):354-363.
［7］邱辉,李国平,孙涛.再生型车削颤振的动力学建模与稳定性分析［J］.宁波大学学报(理工版),2016,29(3):98-102.
QIU Hui, LI Guoping, SUN Tao.Dynamic Modeling and Stability Analysis of Regenerative Turning Chatter［J］.Journal of Ningbo University(Science and Technology Edition),2016,29(3):98-102.
［8］李勤良,汪博,赵斌,等.考虑非线性迟滞力的机床颤振系统稳定性研究［J］.机械工程学报,2013,49(11):43-49.
LI Qinliang, WANG Bo, ZHAO Bin,et al. Research on the Stability of Machine Tool Flutter System Considering Nonlinear Hysteresis［J］. Journal of Mechanical Engineering, 2013, 49(11):43-49.
［9］OZLU E,BUDAK E. Analytical Modeling of Chatter Stability in Turning and Boring Operations—Part Ⅱ:Experimental Verification［J］. Manufacturing Science and Engineering, 2007, 129:726-732.
［10］仇健.基于动态切削过程仿真的外圆车削稳定性判定［J］.机械工程学报,2019,55(3):208-218.
QIU Jian. Determination of Stability of Cylindrical Turning Based on Dynamic Cutting Process Simulation［J］. Journal of Mechanical Engineering, 2019,55(3):208-218.
［11］刘全明,张朝晖,刘世锋,等.钛合金在航空航天及武器装备领域的应用与发展［J］.钢铁研究学报,2015,27(3):1-4.
LIU Quanming, ZHANG Zhaohui, LIU Shifeng,et al. Application and Development of Titanium Alloys in Aerospace and Weaponry［J］. Journal of Iron and Steel Research,2015,27(3):1-4.
［12］汪海晋,尹宗宇,柯臻铮,等.基于一维卷积神经网络的螺旋铣刀具磨损监测［J］.浙江大学学报(工学版),2020,54(5):931-939.
WANG Haijin, YIN Zongyu, KE Zhenzheng, et al. Wear Monitoring of Spiral Milling Tools Based on One-dimensional Convolutional Neural Network［J］. Journal of Zhejiang University(Engineering Science), 2020,54(5):931-939.
［13］赵威,王盛璋,何宁,等.航空钛合金结构件铣削刀具性能模糊综合评判［J］.中国机械工程,2015,26(6):711-715.
ZHAO Wei, WANG Shengzhang, HE Ning,et al. Fuzzy Comprehensive Evaluation of Milling Tool Performance for Aerospace Titanium Alloy Structural Parts［J］. China Mechanical Engineering,2015,26(6):711-715
［14］李亮,赵威,何宁.过程阻尼效应在钛合金铣削加工中的应用［J］.振动·测试与诊断,2015,35(6):1165-1172.
LI Liang, ZHAO Wei, HE Ning.Application of Process Damping Effect in Titanium Alloy Milling［J］.Vibration·Testing and Diagnosis,2015,35(6):1165-1172.
［15］李忠群,董亚峰,夏磊,等.考虑过程阻尼的切削稳定性建模与仿真分析［J］.湖南工业大学学报,2014,28(6):23-26.
LI Zhongqun, DONG Yafeng, XIA Lei, et al. Cutting Stability Modeling and Simulation Analysis Considering Process Damping［J］. Journal of Hunan University of Technology, 2014, 28(6):23-26.
［16］秦国华,娄维达,吴竹溪,等.基于过程阻尼和结构模态耦合的铣削稳定性分析与实验验证［J］.中国科学:技术科学,2020,50(9):1211-1225.
QIN Guohua, LOU Weida, WU Zhuxi, et al. Milling Stability Analysis and Experimental Verification Based on Process Damping and Structural Modal Coupling［J］. Science in China:Technical Science, 2020, 50(9):1211-1225.
［17］于福航,李茂月,严复钢,等.一种基于多步回溯算法的铣削稳定性预测方法［J］.振动与冲击,2021,40(1):102-109.
YU Fuhang, LI Maoyue, YAN Fugang,et al. A Milling Stability Prediction Method Based on Multi-step Backtracking Algorithm［J］. Vibration and Shock, 2021,40(1):102-109.
［18］李欣,赵威,李亮,等.钛合金铣削加工中的过程阻尼效应［J］.振动工程学报,2015,28(2):255-261.
LI Xin, ZHAO Wei, LI Liang, et al. Process Damping Effect in Titanium Alloy Milling［J］. Chinese Journal of Vibration Engineering, 2015, 28(2):255-261.
［19］曹畅. 基于压入效应的切削过程阻尼建模与实验研究［D］.武汉:华中科技大学,2019.
CAO Chang. Modeling and Experimental Research on Cutting Process Damping Based on Indentation Effect［D］.Wuhan:Huazhong University of Science and Technology, 2019.
［20］侯峻峰. 过程阻尼对车削稳定性的影响［D］.沈阳:东北大学,2014.
HOU Junfeng. Effect of Process Damping on Turning Stability［D］.Shenyang:Northeastern University, 2014.
［21］AHMADI K, ALTINTAS Y. Identification of Machining Process Damping Using Output-only Modal Analysis［J］. Journal of Manufacturing Science and Engineering,2014,136(5)： 051017.
［22］梁君,赵登峰.模态分析方法综述［J］.现代制造工程,2006(8):139-141.
LIANG Jun, ZHAO Dengfeng. A Review of Modal Analysis Methods［J］.Modern Manufacturing Engineering,2006(8):139-141.
［23］史丽晨,贾永康,张军锋.车削去除钛合金棒材表面氧化皮工艺参数试验研究［J］.表面技术,2021,50(5):372-379.
SHI Lichen,JIA Yongkang,ZHANG Junfeng. Experimental Study on Process Parameters of Removing Oxide Scale from Titanium Alloy Bar Surface by Turning［J］.Surface Technology, 2021,50(5):372-379.
［24］刘宇,何凤霞.切削加工动力学现代分析方法［M］. 北京:科学出版社，2020：6-38.
LIU Yu, HE Fengxia. Modern Analysis Method of Machining Dynamics［M］. Beijing:Science Press, 2020:6-38.