Re‐entry safety: Analysis and plasma wind tunnel testing of spacecraft design solutions to reduce on‐ground casualty risk

IF 1 Q3 ENGINEERING, AEROSPACE Journal of Space Safety Engineering Pub Date : 2023-12-15 DOI:10.1016/j.jsse.2023.11.014

Lucia Suriani , Antonio Caiazzo , Britta Ganzer , Tobias Lips , Patrice Laurenti , Bradley Lockett , Thorn Schleutker , Tiago Soares , James Beck

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Abstract

In compliance with ISO 24,113 and ESA Space Debris Mitigation requirements, spacecrafts in Low Earth Orbit (LEO) must be removed from their operational orbit within 25 years and re-enter the Earth's atmosphere having an on-ground casualty risk lower than 1 in 10,000.

To maximize the number of uncontrolled re-entries, which have much less impact on system mass and costs, ESA's Clean Space initiative is investigating design for containment (D4C) techniques and collaborating with European industries and space agencies to assess, model, analyse, and test new concepts through re-entry tools and plasma wind tunnel experiments. The main objectives are to understand the survivability of materials and techniques suitable for different containment concepts, to improve re-entry modelling, and implement effective D4C measures.

This paper shows the results of these activities, that have been the first milestones in the knowledge of D4C, although further investigations are needed.

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重返大气层安全：航天器设计方案的分析和等离子风洞试验，以降低地面伤亡风险

根据 ISO 24,113 和欧空局空间碎片缓减要求，低地球轨道（LEO）上的航天器必须在 25 年内脱离运行轨道，重返地球大气层的地面伤亡风险低于万分之一。为了最大限度地增加对系统质量和成本影响较小的不受控制的重返次数，欧空局的 "清洁空间 "计划正在研究遏制设计（D4C）技术，并与欧洲工业界和空间机构合作，通过重返工具和等离子风洞实验对新概念进行评估、建模、分析和测试。主要目标是了解适用于不同安全壳概念的材料和技术的生存能力，改进重返模型，并实施有效的 D4C 措施。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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