Validation of a numerical strategy to simulate the expansion around a plug nozzle

Materials Research Society symposia proceedings. Materials Research Society Pub Date : 2023-11-01 DOI:10.21741/9781644902813-148

M.D. Gagliardi

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Abstract

Abstract. Rocket engines currently use traditional bell-shaped nozzles that have a fixed area ratio and can only operate at maximum efficiency at a given altitude. Plug nozzles have been proposed as an alternative solution to achieve higher performance over a larger altitude range. Unlike bell nozzles, the flow is free to expand along the plug, as it is no longer surrounded by solid boundaries. Therefore, plug nozzles can adapt to different altitudes by expanding the flow to ambient pressure, resulting in continuous altitude adaptation. Due to the high surface area that needs to be cooled, one of the main challenges of plug nozzle design is thermal management. However, the introduction of aerospike geometry, which is essentially a truncated plug nozzle, has helped mitigate this issue. Simulating an aerospike engine is challenging due to the interaction between the plume and the external flow, which is necessary to accurately predict thrust. In this work, a numerical strategy for predicting the performance of an aerospike engine, during a static fire, was developed and validated.

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一种模拟塞式喷嘴膨胀的数值策略的验证

摘要火箭发动机目前使用传统的钟形喷嘴，具有固定的面积比，只能在给定的高度以最大效率运行。为了在更大的海拔范围内获得更高的性能，塞式喷嘴被提出作为一种替代方案。与钟形喷嘴不同的是，流动可以自由地沿着塞扩展，因为它不再被固体边界包围。因此，塞式喷嘴可以通过将流量扩展到环境压力来适应不同的海拔高度，从而实现连续的海拔适应。由于需要冷却的表面积很大，塞式喷嘴设计的主要挑战之一是热管理。然而，aerospike的引入(本质上是一个截断的塞式喷嘴)有助于缓解这个问题。由于羽流和外部气流之间的相互作用，对喷气发动机的模拟具有挑战性，这对于准确预测推力是必要的。在这项工作中，开发并验证了一种用于预测静态火灾时喷气发动机性能的数值策略。

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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