Optimized design of high-efficiency lunar soil sampling tube structure based on stress–strain law

Understanding the influence of the sampling apparatus on in-situ lunar soil lamination information during the sampling process of the direct push-through lunar weathering layer is of great importance. This paper develops a discrete element model for direct push-through lunar weathering layer sampling using the CUG-1A simulated lunar soil developed by the China University of Geosciences as a simulation object and determines the stress–strain law of the inner wall of a sampling tube. A method for optimizing the inner wall structure of a sampling tube based on the stress–strain law is proposed. The structural disturbance of the marker layer and the lunar soil disturbance rate evaluation function are used to assess the degree of disturbance of the laminar information during the sampling process. The results show that the proposed method can effectively reduce the structural disturbance of the lunar soil in-situ laminar information. In addition, it can also optimize the structural information disturbance of the marker layer. The proposed method can decrease the simulated lunar soil disturbance rate from 0.31 to 0.251 and effectively reduce the penetration force load by 15–20% in the direct push-through sampling process.     

车载惯导系统抗扰动自对准方法对比研究

自对准技术是陆基机动平台及装备用惯导系统的一项关键技术,其核心在于惯导系统如何在风扰、发动机振动、人员走动等各种干扰下实现快速、高精度对准.针对目前常用的惯性系解析自对准、Kalman滤波估计自对准和惯性系奇异值分解(SVD)自对准等三种方法进行了研究和对比分析,根据三种对准方法各自的实现原理,提出了一种有针对性的抗扰动优化方法,并通过了数学仿真分析和车载试验验证.结果 表明,在车载使用环境下,后两种方法都能获得较为准确的姿态信息,惯性系SVD方法可以达到与Kalman滤波方法相当的对准精度和收敛速度,且无需先验信息即可获得最优解,表现出了较好的工程应用优势.