摘要
针对叶片型面抛光,在分析五轴联动数控砂带抛光可行性的基础上,设计并开发了五轴联动柔性数控砂带抛光机。提出了接触轮与叶片型面有效贴合的概念,并通过改善抛光工具、采用柔性抛光技术和控制抛光轴矢量来实现砂带与叶片型面的有效贴合。抛光轴矢量由抛光位点处法矢和接触轮进给矢量计算获得,既实现了砂带与叶片型面的有效贴合,而且满足抛光轮接触压力方向与柔性机构收缩方向基本一致的要求。抛光轨迹规划采用等参数线法,抛光行距根据抛光带宽确定。最后进行抛光实验,结果为精抛后粗糙度达到0.25-0.39μm,抛光前后叶型轮廓度变化0.007mm,抛光去除量在0.010-0.016mm之间,满足图纸要求。通过实验表明,五轴联动数控砂带抛光叶片型面可行,采用本文所述技术能够满足叶片型面抛光要求。
For the abrasive belt polishing of blade surface, the flexible polishing machine of five-axis NC abrasive belt is designed and developed based on the feasibility of five-axis NC abrasive belt polishing. The concept of effective matching of contacting wheel and blade surface is put forward. A new method through improving the polishing tool,using the flexible polishing technology and controlling the polishing axis vector is used to ensure the effective matching of contacting wheel and blade surface. The polishing axis vector is calculated by normal vector of polishing location point and feed direction vector of contacting wheel, so as to achieve the effective matching of contacting wheel and blade surface, and meet the basic consistency between polishing wheel contacting pressure direction and flexible polishing structure retractable direction. The isoparametric lines method is used to plan polishing path and polishing stepover length is determined by the polishing width. Finally, the polishing test result displays that the roughness of fine polishing can reach 0.25-0.39 μm, the profile about blade surface before and after polishing changes 0. 007 mm, and the polishing material removal is between 0. 010-0. 016 mm, meeting the requirements of the drawings. Experiments show that five-axis NO abrasive belt polishing for blade surface is feasible and the technology described in this paper can meet the requirements of the blade surface polishing.
出处
《航空学报》
EI
CAS
CSCD
北大核心
2015年第6期2074-2082,共9页
Acta Aeronautica et Astronautica Sinica
基金
国家科技重大专项(2013ZX04011031)~~
关键词
柔性
抛光机床
数控
叶片
路径规划
姿态控制
flexible
polishing machines
NO
blades
path formulation
attitude control
