[1] ZHI S,ZAREMBSKI A M,LI J Y,et al. Towards a better understanding of the rail grinding mechanism[C]//ASME 2013 Rail Transportation Division Fall Technical Conference,Altoona:American Society of Mechanical Engineers,Rail Transportation Division RTD,2013:15-17. [2] 刘月明,李建勇,蔡永林,等. 钢轨打磨技术现状和发展趋势[J]. 中国铁道科学,2014,35(4):29-37. LIU Yueming,LI Jianyong,CAI Yonglin,et al. Current state and development trend of rail grinding technology[J]. China Railway Science,2014,35(4):29-37. [3] 智少丹,李建勇,樊文刚,等. 钢轨打磨接触线模型研究[J]. 铁道学报,2013,35(10):94-99. ZHI Shaodan,LI Jianyong,FAN Wengang,et al. Research on contact line model for rail grinding[J]. Journal of the China Railway Society,2013,35(10):94-99. [4] 郭战伟. 基于轮轨蠕滑最小化的钢轨打磨研究[J]. 中国铁道科学,2011,32(6):9-15. GUO Zhanwei. Study of rail grinding based on wheel rail creep minimization[J]. China Railway Science,2011,32(6):9-15. [5] 王荣全. 面向钢轨打磨的砂带磨削过程建模与实验研究[D]. 北京:北京交通大学,2016. WANG Rongquan. The modeling and experimental research of belt-grinding process in rail[D]. Beijing:Beijing Jiaotong University,2016. [6] KHELLOUKI A,RECH J,ZAHOUANI H. The effect of abrasive grain's wear and contact conditions on surface texture in belt finishing[J]. Wear,2007,263(1-6):81-87. [7] KHELLOUKI A,RECH J,ZAHOUANI H. Influence of the belt-finishing process on the surface texture obtained by hard turning[J]. Proceedings of the Institution of Mechanical Engineers Part B:Journal of Engineering Manufacture,2007,221(7):1129-1137. [8] REN X,KUHLENKOTTER B,MULLER H. Simulation and verification of belt grinding with industrial robots[J]. International Journal of Machine Tools & Manufacture,2006,46(7-8):708-716. [9] REN X,CABARAVDIC M,ZHANG X,et al. A local process model for simulation of robotic belt grinding[J]. International Journal of Machine Tools & Manufacture,2007,47(6):962-970. [10] ZHANG X,KUHLENKOTTER B,KNEUPNER K. An efficient method for solving the Signorini problem in the simulation of free-form surfaces produced by belt grinding[J]. International Journal of Machine Tools & Manufacture,2005,45(6):641-648. [11] ZHANG X,KNEUPNER K,KUHLENKOTTER B. A new force distribution calculation model for high-quality production processes[J]. International Journal of Advanced Manufacturing Technology,2005,27(7):726-732. [12] 黄云,黄智. 现代砂带磨削技术及工程应用[M]. 重庆:重庆大学出版社,2009. HUANG Yun,HUANG Zhi. Modern abrasive belt grinding technology and engineering application[M]. Chongqing:Chongqing University Press,2009. [13] 吴昌林,丁和艳,陈义. 材料去除深度与磨粒的关系建模方法研究[J]. 中国机械工程,2011,22(3):300-304. WU Changlin,DING Heyan,CHEN Yi. Research on modeling method of relation between abrasive grain and material removal depth[J]. China Mechanical Engineering,2011,22(3):300-304. [14] 赵燕涛. 自由曲面变压力砂带磨削相关技术的研究[D]. 沈阳:东北大学,2014. ZHAO Yantao. Research on the related technology of variable pressure belt grinding on free——form surface[D]. Shenyang:Northeastern University,2014. [15] 张雷,袁楚明,周祖德,等. 模具曲面抛光时表面去除的建模与试验研究[J]. 机械工程学报,2002,38(12):98-102. ZHANG Lei,YUAN Chuming,ZHOU Zude,et al. Modeling and experiment of material removal in polishing on mold curved surfaces[J]. Journal of Mechanical Engineering,2002,38(12):98-102. [16] WANG Y J,HUANG Y,CHEN Y X,et al. Model of an abrasive belt grinding surface removal contour and its application[J]. International Journal of Advanced Manufacturing Technology,2016,82(9-12):2113-2122. |