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http://dx.doi.org/10.5139/IJASS.2013.14.4.356

Landing Stability Simulation of a 1/6 Lunar Module with Aluminum Honeycomb Dampers  

Pham, Van Lai (Department of Advanced Technology Fusion, Division of Interdisciplinary studies, Konkuk University)
Zhao, Jun (Department of Advanced Technology Fusion, Division of Interdisciplinary studies, Konkuk University)
Goo, Nam Seo (Department of Advanced Technology Fusion, Division of Interdisciplinary studies, Konkuk University)
Lim, Jae Hyuk (Korea Aerospace Research Institute)
Hwang, Do-Soon (Korea Aerospace Research Institute)
Park, Jung Sun (Aerospace and Mechanical Engineering, Korea Aerospace University)
Publication Information
International Journal of Aeronautical and Space Sciences / v.14, no.4, 2013 , pp. 356-368 More about this Journal
Abstract
The Korea Aerospace Research Institute plans to launch a lunar module by 2025, and so is carrying out a preliminary study. Landing stability on the lunar surface is a key design factor of a lunar module. In this paper, a 1/6 scale model of a lunar module is investigated, for its landing stability on non-level surfaces. The lunar module has four tripod legs, with aluminum honeycomb shock absorbers in each leg strut. ADAMS$^{TM}$, the most widely used multi-body dynamics and motion analysis software, is used to simulate the module's lunar landing. Three types of dampers in the struts (rigid, viscous, and aluminum honeycomb dampers), and two types of lunar surfaces (rigid and elastic) are considered. The Sforce function is adopted, to model the aluminum honeycomb dampers. Details on the modeling and analysis of the landing stability of the 1/6 scale lunar module and the simulation results are provided in this paper.
Keywords
Lunar module; ADAMS; Landing stability; Aluminum honeycomb damper;
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