基于六自由度运动轨迹的晃车仪测试技术

doi:10.3969/j.issn.1000-1158.2023.11.11

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摘要针对现有晃车仪测试方法单一,难以满足实际工况要求,以及晃车仪内部单一加速度传感器在线角复合振动下解算不确定度大的问题,基于六自由度平台,利用其复合运动的轨迹,采用与陀螺仪传感器数据融合的方法测量复合振动角度幅值。通过量化处理线角复合振动,利用陀螺仪测量振动角度幅值,校正复合振动下单一加速度传感器受到的倾角影响,以提高晃车仪解算精度,并对融合解算后的参考频率点进行扩展不确定度评定。结果表明陀螺仪与晃车仪二者数据融合后整个测试系统线振动和角振动相对扩展不确定度分别为0.36%、0.08%,拓宽了晃车仪标准测试工况。

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	韩志
	陈春雷
	程朝阳
	赵紫珅
	刘凯

关键词 ：计量学, 晃车仪, 六自由度, 复合振动, 传感器, 数据融合

Abstract：The test method of the existing swing vehicle was single, which was difficult to meet the requirements of actual working conditions. Based on the 6 degree of freedom platform, the trajectory of its composite motion is used to measure the amplitude of the composite vibration angle through data fusion with the gyroscope sensor. In order to improve the solution accuracy of the wobble vehicle, the linear angular compound vibration was quantified and the amplitude of vibration angle was measured by gyroscope, and the inclination effect of the single acceleration sensor was corrected under the compound vibration, and the expanded uncertainty evaluation was conducted on the reference frequency points after the fusion solution. The results showed that the relative expanded uncertainties of the linear and angular vibrations of the entire testing system after the fusion of the data of the gyroscope and the wobble instrument were 0.36% and 0.08%, respectively, expanding the standard testing conditions of the wobble instrument.

Key words： metrology swing vehicle instrument 6 degree of freedom compound vibration sensor data fusion

收稿日期: 2022-08-19 发布日期: 2023-11-17

PACS:

TB936

基金资助:中国铁道科学研究院集团有限公司基金项目(2020YJ219)

通讯作者: 程朝阳(1994-),男,安徽合肥人,中国铁道科学研究院集团有限公司基础设施检测研究所助理研究员,主要从事轨道检测技术研究。Email:1608285436@qq.com E-mail: 1608285436@qq.com

作者简介: 韩志(1993-),男,黑龙江黑河人,中国铁道科学研究院集团有限公司基础设施检测研究所助理研究员,主要从事铁路基础设施评定与校准技术研究。Email:15210234687@163.com

引用本文:

韩志,陈春雷,程朝阳,赵紫珅,刘凯. 基于六自由度运动轨迹的晃车仪测试技术[J]. 计量学报, 2023, 44(11): 1706-1712.
HAN Zhi,CHEN Chun-Lei,CHENG Zhao-Yang,ZHAO Zi-Shen,LIU Kai. Testing Technology of Swing Vehicle Instrument Based on 6 Degree of Freedom Trajectory. Acta Metrologica Sinica, 2023, 44(11): 1706-1712.

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