基于振动台试验的加速度积分位移
Acceleration Integral Displacement Based on Shaking Table Test
-
摘要: 轨道不平顺是铁路车辆系统振动的主要激励源, 车体构架运行姿态的变化会对轨道几何不平顺检测精度造成影响. 理论上可通过位移传感器对车体构架的运行姿态进行测试, 但多数情况下测量困难且精度较低, 而采用加速度传感器测试, 又存在各种噪声干扰, 使积分位移中含有趋势项漂移误差. 针对此类问题, 提出了一种从加速度数据中获取位移时间序列的低频衰减频域积分方法. 该方法从测量加速度积分开始, 采用基于滑动平均的最小二乘法预处理方法, 去除积分过程中的噪声产生的误差, 还原实际由于轨道不平顺产生的振动响应. 结合滑动平均方法、高通滤波器和频域积分, 通过多次平滑、滤波和积分, 得到重构位移信号, 避免了信号的失真. 该方法的主要优点是重构位移不存在长周期漂移. 通过与振动台实测数据的对比分析, 验证了该方法的准确性和可靠性.Abstract: Track irregularity is the main excitation source of the vibration of railway vehicle system, and the change of the running posture of the car body frame will affect the detection accuracy of track geometric irregularity. In theory, the running posture of the car body frame can be measured by the displacement sensor, but in most cases, the measurement is difficult and the accuracy is low. When the acceleration sensor is used to test, there are various kinds of noise interference, so that the integral displacement contains the trend term drift error. To solve this problem, a low-frequency attenuation frequency-domain integration method was proposed in this paper to obtain displacement time series from acceleration data. The method started from the integration of acceleration measurement, and used the least square method based on moving average to remove the error caused by random noise in the integration process and restored the actual vibration response caused by track irregularity. Combined with the moving average method, high pass filter and frequency domain integration, the reconstructed displacement signal was obtained through multiple rounds of smoothing, filtering, and integration to avoid signal distortion. The main advantage of this method was that there was no long period drift in the reconstructed displacement. The accuracy and reliability of this method were verified by comparing with the measured data of shaking table.