首页 | 本学科首页   官方微博 | 高级检索  
相似文献
 共查询到10条相似文献,搜索用时 109 毫秒
1.
开发了用于数控机床空间误差测量的激光干涉仪自动瞄准系统。该系统实现了机床多轴联动、而激光束的方向发生连续改变时空间曲线轨迹定位误差的测量。提出了通过一次对光实现数控机床整个空间定位误差的直接测量方法。采用网格方法储存测量误差,用有限元法实现补偿误差的预报。在立式数控加工中心上进行了误差的测量和补偿试验,结果表明所提出的误差测量方法精度高、速度快,误差补偿效果明显。  相似文献   

2.
This paper shows a micro computer aided error calibration system for CMMs and machine tools, which is a fast and efficient error calibration system: A micro computer stores the error calibration data of a step gauge which were precalibrated with more precise equipments such as laser interferometer, then the step gauge is probed with the specific CMMs or machine tools. The probing data are compared with the stored precalibration data, in order to give the linear displacement accuracy of the machines. High degree of computer integration has been performed in the measurement path planning, measurement operation, and error evaluation. Thus a rigorous computer aided error calibration system has been implemented with full potential of practical application to most of commercial CMMs and machine tools of CNC type.  相似文献   

3.
Geometric error component identification is needed to realize the geometric error compensation which can significantly enhance the accuracy of multi-axis machine tools. Laser tracker has been applied to geometric error identification of machine tools increasingly due to its high capability in 3D metrology. A general method, based on point measurement using a laser tracker is developed for identifying the geometric error components of multi-axis machine tools in this study. By using this method, all the component errors and location errors of each axis (including the linear axis and rotary axis) of the multi-axis machine tools can be measured. Three pre-described targets are fixed on the stage of the under-test axis which moves step by step. The coordinates of the three targets at every step are determined by a laser tracker based on the sequential multilateration method. The volumetric errors of these three target points at each step can be obtained by comparing the measured values of the target points’ coordinates with the ideal values. Then, nine equations can be established by inversely applying the geometric error model of the axis under test, which can explicitly describe the relationship between the geometric error components and volumetric error components, and then the component errors of this axis can be obtained by solving these equations. The location errors of the axis under test can be determined through the curve fitting. In brief, all the geometric error components of a single axis of multi-axis machine tools can be measured by the proposed method. The validity of the proposed method is verified through a series of experiments, and the experimental results indicate that the proposed method is capable of identifying all the geometric error components of multi-axis machine tools of arbitrary configuration.  相似文献   

4.
The linear and rotary axes are fundamental parts of multi-axis machine tools. The geometric error components of the axes must be measured for motion error compensation to improve the accuracy of the machine tools. In this paper, a simple method named the three-point method is proposed to measure the geometric error of the linear and rotary axes of the machine tools using a laser tracker. A sequential multilateration method, where uncertainty is verified through simulation, is applied to measure the 3D coordinates. Three non-collinear points fixed on the stage of each axis are selected. The coordinates of these points are simultaneously measured using a laser tracker to obtain their volumetric errors by comparing these coordinates with ideal values. Numerous equations can be established using the geometric error models of each axis. The geometric error components can be obtained by solving these equations. The validity of the proposed method is verified through a series of experiments. The results indicate that the proposed method can measure the geometric error of the axes to compensate for the errors in multi-axis machine tools.  相似文献   

5.
基于激光干涉仪的数控机床运动误差识别与补偿   总被引:10,自引:0,他引:10  
提出了数控机床运动误差的软件补偿方法。采用刚体运动假设和齐次坐标变换建立了多轴机床空间运动误差的通用模型。该模型把刀具相对于工件的空间误差表示为机床各结构件之间运动误差的位置函数。给出了全部运动误差参数的激光干扰仪识别方法,提出了一种新的roll误差测量措施,在立式加工中心上进行了运动误差的补偿实验,结果证明所提出的运动误差软件联动补偿效果显著。  相似文献   

6.
本文在分析介绍了激光干涉仪测量位移原理的基础上,指出了标准振动台稳态正弦绝对校准法中,激光干涉仪测量的只是工作台面运动的路程而非矢量位移,因此对于测量含有谐波失真的正弦波形将引入测量原理性误差。文中利用波形加速度失真度系数详细推导并给出了谐波失真所引入的测量误差的估计式,对准确评价传感器校准精度具有重要意义,同样也有助于我们对激光干涉仪测量精度的认识。  相似文献   

7.
This paper performs a comprehensive analysis and calibration on the geometric error of the ultra-precision drum roll lathe with dual-spindle symmetrical structure and cross slider layout. Firstly, the volumetric error model which contains all geometric errors of the dual-spindle ultra-precision drum roll lathe (DSUPDRL) is developed based on the combination of the homogenous transfer matrix (HTM) and multi-body system (MBS) theory. Secondly, sensitivity analysis for the volumetric error model is conducted to identify the sensitive geometric error components of the DSUPDRL using an improved Sobol method based on the quasi-Monte Carlo algorithm. The result of sensitivity analysis laid the foundation for the subsequent geometric error calibration. Then, some sensitive error components along the X and Z directions are calibrated using a laser interferometer and a pair of inductance displacement probes. Besides the volumetric error model, the concentricity error caused by dual-spindle symmetrical structure is proposed and calibrated by the on-machine measurement using a classic reversal method. Finally, a large-scale roller mold with a diameter of 250 mm and a length of 600 mm is machined using the DSUPDRL after calibration. The experimental result shows that 1.4 μm/600 mm generatrix accuracy is obtained, which validate the effectiveness of the geometric error analysis and calibration.  相似文献   

8.
Rotary tables are widely used with multi-axis machine tools as a means for providing rotational motions for the cutting tools on the three-axis machine tools used for five-axis machining operations. In this paper, we present a comprehensive procedure for the calibration of the rotary table including: geometric error model; error compensation method for the CNC controller; error measurement method; and verification of the error model and compensation algorithm with experimental apparatus. The methods developed were verified by various experiments, showing the validity and effectiveness of the presented methods, indicating they can be used for multi-axis machine tools as a means of calibration and precision enhancement of the rotary table.  相似文献   

9.
非接触式缸盖平面度误差检测方法与测量系统研究   总被引:1,自引:0,他引:1  
为解决发动机缸盖生产铸造过程中缸盖底面平整度误差检测问题,设计一种激光非接触式发动机缸盖底面平整度在线检测系统,提出一种基于对角中线的平面度误差检测算法。根据现场平面度检测需求,设计利用激光臂纵轴和缸盖横轴传送的交互运动的发动机缸盖表面平面度误差检测系统;通过发动机缸盖表面检测四个顶角特征点对角线中线建立发动机缸盖平面度检测的数学模型,利用回归方程确定最小二乘法平面为理想平面,求出平面度误差;并对激光位移传感器进行精度标定,给出传感器误差标定回归方程,并应用该检测系统完成对不同型号的发动机缸盖检测。结果表明:该系统最大检测面积为400 mm×2 000 mm,测量范围为160~450 mm,测量精度为0.03 mm,而且结构简单,检测速度快,完全能够达到在线检测要求。  相似文献   

10.
实时误差补偿技术是近代机床技术的研究重点,多轴数控机床的误差补偿问题有很高的难度和研究价值。本文提出了基于多体系统的五轴数控机床几何误差建模技术,研究了误差补偿的关键,即表示几何误差的参数,同时为了评估建模的好坏,研究了基于多体系统的切削工件过程仿真。  相似文献   

设为首页 | 免责声明 | 关于勤云 | 加入收藏

Copyright©北京勤云科技发展有限公司  京ICP备09084417号