[1]UPADHYAY V, JAIN P K, MEHTA N K.In-process Prediction of Surface Roughness in Turning of Ti-6Al-4V Alloy Using Cutting Parameters and Vibration Signals[J]. Measurement, 2013,46(1):154-160.
[2]XIAO X Z, ZHENG K, LIAO W H, et al. Study on Cutting Force Model in Ultrasonic Vibration Assisted Side Grinding of Zirconia Ceramics[J]. International Journal of Machine Tools & Manufacture Design Research & Application, 2016,104:58-67.
[3]SHAO Yamin, LI Beizhi, LIANG S Y.Predictive Modeling of Surface Roughness in Grinding of Ceramics[J]. Machining Science and Technology, 2015,19(2):325-338.
[4]BOUGHARRIOU A, BOUZID W, SAI K.Analytical Modeling of Surface Profile in Turning and Burnishing[J]. International Journal of Advanced Manufacturing Technology, 2014,75(1/4):547-558.
[5]马付建, 栾诗宇, 罗奇超, 等. 磁性磨料光整加工工艺对钛合金表面完整性的影响[J].中国表面工程, 2019, 32(2):128-136.
MA Fujian, LUAN Shiyu, LUO Qichao, et al. Effect of Magnetic Abrasive Finishing Technology on Surface Integrity of Titanium Alloy[J]. China Surface Engineering, 2019, 32(2):128-136.
[6]刘伟,商圆圆,邓朝晖,等.砂轮表面形貌定量评价及修整效果研究[J].中国机械工程,2018,29(19):2277-2283.
LIU Wei, SHANG Yuanyuan, DENG Zhaohui, et al. Quantitative Evaluation and Dressing Effect of Grinding Wheel Surface Morphology[J].China Mechanical Engineering,2018,29(19):2277-2283.
[7]MA L J, CAI C Y, TAN Y Q, et al. Theoretical Model of Transverse and Longitudinal Surface Roughness and Study on Brittle-ductile Transition Mechanism for Turning Fluorophlogopite Ceramic[J]. International Journal of Mechanical Sciences, 2019, 150: 715-726.
[8]LIU T, MA L J, WANG Y, et al. Removal Mechanism of Machinable Ceramics and Theoretical Model of Cutting Force in Turning Operation[J]. Mechanical Sciences, 2019, 10(2): 429-436.
[9]NICOLODI J H W, CONSALTER L A, et al. Effect of Wear Progression in an ‘S’-type Mixed Ceramic Tool on Machining Forces and Surface Roughness in the Turning of Hardened AISI 4140 Steel[J]. International Journal of Machining and Machinability of Materials, 2019, 21(3): 228-243.
[10]ARCONA C, DOW T A. An Empirical Tool Force Model for Precision Machining[J].Journal of Manufacturing Science and Engineering,1998,120(4):700-707.
[11]马廉洁, 蔡重延, 毕长波, 等. 车削氟金云母陶瓷脆性破碎机理及表面粗糙度模型[J]. 东北大学学报(自然科学版), 2019, 40(2):239-243.
MA Lianjie, CAI Zhongyan, BI Changbo, et al. Brittle Fracture Mechanism and Surface Roughness Model of Fluoropolymica Ceramics in Turning[J]. Journal of Northeastern University(Science Edition), 2019,40(2):239-243.
[12]YANG Zhichao, ZHU Lida, NI Chenbing, et al. Investigation of Surface Topography Formation Mechanism Based on Abrasive-workpiece Contact Rate Model in Tangential Ultrasonic Vibration-assisted CBN Grinding of ZrO2 Ceramics[J]. International Journal of Mechanical Sciences,2019,155:66-82.
[13]马廉洁, 巩亚东, 顾立晨, 等. 可加工微晶玻璃陶瓷磨削表面成形机制[J]. 机械工程学报, 2017, 53(15):201-207.
MA Lianjie, GONG Yadong, GU Lichen, et al. The Grinding Surface Forming Mechanism of Glass-ceramics Can Be Machined[J]. Journal of Mechanical Engineering, 2017, 53(15):201-207. |