[1] 房善想, 赵慧玲, 张勤俭. 超声加工技术的应用现状及其发展趋势[J]. 机械工程学报, 2017, 53(19):22-32. FANG S X, ZHAO H L, ZHANG Q J. The application status and development trends of ultrasonic machining technology[J]. Journal of Mechanical Engineering, 2017, 53(19):22-32.(in Chinese) [2] SHEN X H, XU G F. Study of milling force variation in ultrasonic vibration-assisted end milling[J]. Materials & Manufacturing Processes, 2017, 33(9): 644-650. [3] ZHAO B, JIA X F, CHEN F, et al. Control model and the experimental study on the ultrasonic vibration-assisted electrolytic in-process dressing internal grinding[J]. International Journal of Advanced Manufacturing Technology, 2017, 92(7/8):1-13. [4] ABBASI A, AMINI S, SHEIKHZADEH G A. Effect of ultrasonic peening technology on the thermal fatigue of rolling mill rolls[J]. International Journal of Advanced Manufacturing Technology, 2018,94(5/6/7/8):2499-2513. [5] 张园, 康仁科, 刘津廷, 等. 超声振动辅助钻削技术综述[J]. 机械工程学报,2017,53(19):33-34. ZHANG Y,KANG R K, LIU J T, et al. Review of ultrasonic vibration assisted drilling[J]. Journal of Mechanical Engineering,2017,53(19):33-34.(in Chinese) [6] 别文博,赵波,王晓博,等.超声加工在齿轮抗疲劳制造中的研究综述与展望[J].表面技术,2018,47(7):35-51. BIE W B, ZHAO B, WANG X B, et al. Overview and expectation on gear anti-fatigue manufacture by ultrasonic assisted machining[J]. Surface Technology,2018, 47(7): 35-51.(in Chinese) [7] 赵建, 王兵, 刘战强. 旋转超声滚压加工中的滚压力与滚压深度及表面形貌研究[J]. 兵工学报,2016,37(4):696-704. ZHAO J,WANG B, LIU Z Q. The investigation into burnishing force, burnishing depth and surface morphology in rotary ultrasonic burnishing [J]. Acta Armamentarii, 2016, 37(4):696-704. (in Chinese) [8] LIAO Y S, CHEN Y C, LIN H M. Feasibility study of the ultrasonic vibration assisted drilling of Inconel superalloy[J]. International Journal of Machine Tools & Manufacture, 2007, 47(12/13):1988-1996. [9] BAGHLANI V, MEHBUDI P, AKBARI J, et al. An optimization technique on ultrasonic and cutting parameters for drilling and deep drilling of nickel-based high-strength Inconel 738LC superalloy with deeper and higher hole quality[J]. International Journal of Advanced Manufacturing Technology,2016, 82(5/6/7/8):1877- 1888. [10] 赵波, 陈凡, 贾晓凤, 等. 非谐振大工具头变幅杆优化设计及声学特性测试[J]. 陕西师范大学学报(自然科学版), 2017, 45(1):45-51. ZHAO B, CHEN F, JIA X F, et al. Optimization design and characteristics test of non-resonant large tool head horn[J].Journal of Shaanxi Normal University (Natural Science Edition), 2017, 45(1):45-51.(in Chinese) [11] 付俊帆, 秦慧斌, 吕明. 基于Mindlin理论的功率超声纵弯谐振变幅器设计理论与实验研究[J]. 振动与冲击, 2018, 37(7): 259-266. FU J F, QIN H B, L M. Design and experiment of ultrasonic longitudinal-flexural resonance transducer based on Mindlin theory[J]. Journal of Vibration and Shock, 2018, 37(7):259-266.(in Chinese) [12] 梁欣, 吕明, 秦慧斌,等. 纵向谐振变幅器的非谐振设计理论研究与验证[J]. 机械设计与制造, 2016 ,3(3):5-9. LIANG X, L M, QIN H B, et al. Research and verification on the Nonnon-resonant design theory of longitudinal vibration transformer[J]. Machinery Design and Manufacture, 2016, 3(3): 5- 9.(in Chinese) [13] 范国良, 应崇福, 林忠茂, 等. 一种新型的超声加工深小孔的工具系统[J].应用声学, 1982 (1):2-7. FAN G L, YING C F, LIN Z M, et al. A new tool system for deep small holes machined by ultrasonic machining [J]. Applied Acoustics, 1982(1): 2-7.(in Chinese) [14] 赵波, 何定东. 超声珩磨局部共振问题研究[J]. 现代制造工程, 1998,6(6):4-5. ZHAO B, HE D D. Research on local resonance of ultrasonic honing[J]. Modern Manufacturing Engineering, 1998,6(6): 4-5.(in Chinese) [15] 徐可伟, 朱训生, 赵波. 用谐振来解释超声加工中的“局部共振”现象[J]. 应用声学, 2002, 21(5):30-33. X K W, ZHU X S, ZHAO B. Using resonance to explain the phenomenon of “local resonance” in ultrasonic machining[J]. Applied Acoustics, 2002, 21(5): 30-33. (in Chinese) [16] 应崇福, 范国良. 超声复合振动系统中的“ 局部共振” 现象——20 年来的应用和机理分析情况[J].应用声学, 2002, 21(1):19-25. YING C F, FAN G L. The phenomenon of“local resonance” in compound ultrasonic vibration systems—applications and mechanism analyses during the 20 years after its discovery [J]. Journal of Applied Acoustics, 2002, 21(1):19-25. (in Chinese) [17] 郑建新, 刘传绍, 高国富, 等. 超声振动钻削中局部共振现象的研究与应用[J]. 工具技术, 2003, 37(2):5-8. ZHENG J X, LIU C S, GAO G F, et al. Research and application of local resonance phenomenon in ultrasonic vibration drilling[J]. Chinese Tool Engineering, 2003,37(2):5-8.(in Chinese) [18] 周光平, 鲍善惠, 程存弟,等. “局部共振”现象的理论解释[J]. 应用声学,1994, 13(6):39-42. ZHOU G P, BAO S H, CHENG C D, et al. The theory explanation of the phenomenon of“local resonance” [J]. Applied Acoustics, 1994,13(6):39-42. (in Chinese) [19] 鲍善惠.超声耦合振动与“局部共振”现象[J].应用声学,1998, 17(4):6-10. BAO S H. Ultrasonic coupled vibration and “local resonance” phenomenon [J]. Applied Acoustics, 1998, 17(4):6-10.(in Chinese) [20] 赵福令, 冯冬菊, 郭东明, 等. 超声变幅杆的四端网络 法设计[J].声学学报,2002, 27(6): 554-558. ZHAO F L, FENG D J, GUO D M, et al. Design of four terminal network method for ultrasonic horn[J]. Journal of Acoustics, 2002, 27(6):554-558.(in Chinese) [21] 张宁宁.指数型复合变幅杆的设计及负载特性研究[J].机械制造,2014,52(10):24-46. ZHANG N N. Design and load characteristics of an exponential composite horn[J]. Machinery, 2014, 52(10):24-46.(in Chinese)
第40卷 第8期2019 年8月兵工学报ACTA ARMAMENTARIIVol.40No.8Aug.2019
|