High-fidelity simulation of the interaction between the wake of a descent capsule and a supersonic parachute

Materials Research Society symposia proceedings. Materials Research Society Pub Date : 2023-11-01 DOI:10.21741/9781644902813-42

L. Placco

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Abstract

Abstract. The objective of the project is to analyze the unsteady dynamics of the parachute-capsule system in a supersonic airflow while descending during planetary entry. Currently, a combination of Large-Eddy Simulation and an Immersed-Boundary Method is being utilized to examine the evolving flow of a rigid supersonic parachute trailing behind a reentry capsule as it descends through the atmosphere of Mars. The flow is simulated at 𝑀𝑎 = 2 and 𝑅𝑒 = 106. A massive GPU parallelization is employed to allow a very high fidelity solution of the multiscale turbulent structures present in the flow that characterize its dynamics. We show how strong unsteady dynamics are induced by the interaction of the wake turbulent structures and the bow shock which forms in front of the supersonic decelerator. This unsteady phenomenon called ‘breathing instability’ is strictly related to the ingestion of turbulence by the parachute’s canopy and is responsible of drag variations and structure oscillations observed during previous missions and experimental campaigns. A tentative one-dimensional model of the flow time-evolving dynamics inside the canopy is proposed.

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降落舱尾迹与超音速降落伞相互作用的高保真仿真

摘要本项目的目的是分析降落伞-太空舱系统在超音速气流下进入行星时的非定常动力学。目前，一种结合大涡模拟和浸入边界法的方法被用来研究一个刚性超音速降落伞在再入太空舱后随着它在火星大气中下降而不断变化的气流。在𝑀𝑎= 2和𝑅𝑒= 106处进行流场模拟。采用大规模的GPU并行化，以允许一个非常高保真的解决方案，多尺度湍流结构存在于流动表征其动力学。我们展示了尾流湍流结构与超音速减速度前方形成的弓形激波的相互作用是如何引起强的非定常动力学的。这种被称为“呼吸不稳定”的不稳定现象与降落伞罩吸入的湍流密切相关，并且在以前的任务和实验活动中观察到阻力变化和结构振荡。提出了冠层内部流动随时间变化的一维模型。

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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Materials Research Society symposia proceedings. Materials Research Society

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