零重力实验室:模拟太空操作的多用途设施

IF 1 Q3 ENGINEERING, AEROSPACE Journal of Space Safety Engineering Pub Date : 2023-10-06 DOI:10.1016/j.jsse.2023.09.003
Miguel Olivares-Mendez , Mohatashem Reyaz Makhdoomi , Barış Can Yalçın , Zhanna Bokal , Vivek Muralidharan , Miguel Ortiz Del Castillo , Vincent Gaudilliere , Leo Pauly , Olivia Borgue , Mohammadamin Alandihallaj , Jan Thoemel , Ernest Skrzypczyk , Arunkumar Rathinam , Kuldeep Rambhai Barad , Abd El Rahman Shabayek , Andreas M. Hein , Djamila Aouada , Carol Martinez
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引用次数: 2

摘要

在轨道交会期间,航天器通常在同一轨道平面上接近,并且轨道的相位最终对齐。在满足恶劣的空间环境条件之前,潜在的交会对接任务需要在微重力研究的地面设施中进行模拟和测试。轨道对接时,两个航天器的速度剖面必须匹配。追逐者被放置在比目标稍低的轨道上。由于所有这些任务都相当复杂,并且空间任务的实现非常昂贵,任何与空间相关的硬件或软件的性能都必须在提供零重力模拟的地面设施中进行测试,然后才能开始在空间中运行。该设备将使仿真条件能够模拟伪零重力。配备所有必要的“仪器和基础设施”来测试使用机器人操纵器和/或浮动平台的接触动力学、制导、导航和控制是至关重要的。卢森堡大学的零重力实验室的设计和建造是为了模拟不同航天器之间的交会、对接、捕获和其他交互场景。它配备了相关的基础设施,包括几乎具有空间代表性的闪电条件、运动捕捉系统、环氧树脂地板、安装有机器人的轨道、集成机载计算机和安装大型模型的能力。这些能力使研究人员能够针对独特的轨道情况进行各种各样的实验。它提供了一种可能性,可以与集成硬件的机器人进行混合仿真,并添加预建模的软件组件。整个设施可以实时指挥和操作,确保空间接触动力学的真实性质。零重力实验室还为航天行业的公司/初创公司提供了在发射太空任务之前测试其产品的绝佳机会。本文提供了在构建该设施时学到的最佳实践、专有技术和建议的汇编。它是向研究界提出的,作为建设类似设施的指导方针。
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Zero-G Lab: A multi-purpose facility for emulating space operations

During orbital rendezvous, the spacecraft typically approach in the same orbital plane, and the phase of the orbit eventually aligns. Potential rendezvous and docking missions need to be emulated and tested in an on-ground facility for micro-gravity research prior to meeting the harsh conditions of space environment. For orbital docking, the velocity profile of the two spacecraft must be matched. The chaser is placed in a slightly lower orbit than the target. Since all these tasks are quite complex and the realization of space missions are very expensive, any space-related hardware or software’s performance must be tested in an on-ground facility providing zero gravity emulation before initiating its operation in space. This facility shall enable emulation conditions to mimic pseudo zero gravity. It is of critical importance to be equipped with all the necessary ”instruments and infrastructure” to test contact dynamics, guidance, navigation and control using robotic manipulators and/or floating platforms. The Zero-G Laboratory at the University of Luxembourg has been designed and built to emulate scenarios such as rendezvous, docking, capture and other interaction scenarios between separate spacecraft. It is equipped with relevant infrastructure including nearly space-representative lightning conditions, motion capture system, epoxy floor, mounted rails with robots, capability to integrate on-board computers and mount large mock-ups. These capabilities allow researchers to perform a wide variety of experiments for unique orbital scenarios. It gives a possibility to perform hybrid emulations with robots with integrated hardware adding pre-modeled software components. The entire facility can be commanded and operated in real-time and ensures the true nature of contact dynamics in space. The Zero-G Lab also brings great opportunities for companies/startups in the space industry to test their products before launching the space missions. The article provides a compilation of best practices, know-how and recommendations learned while constructing the facility. It is addressed to the research community to act as a guideline to construct a similar facility.

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来源期刊
Journal of Space Safety Engineering
Journal of Space Safety Engineering Engineering-Safety, Risk, Reliability and Quality
CiteScore
2.50
自引率
0.00%
发文量
80
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