Prediction of Aerothermal Environment and Heat Transfer for Hypersonic Vehicles with Different Aerodynamic Shapes Based on C++

Tian Huang, G. He, Qi Wang
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Abstract

This research paper discusses constructing a unified framework to develop a full-rate scheme for hypersonic heating calculations. The method uses a flow tracing technique with normal phase vector adjustment in a non-structured delineated grid combined with empirical formulations for convective heat transfer standing and non-standing heat flow engineering. This is done using dev-C++ programming in the C++ language environment. Comparisons of the aerodynamic thermal environment with wind tunnel experimental data for the Space Shuttle and Apollo return capsules and standing point heat transfer measurements for the Fire II return capsule was carried out in the hypersonic Mach number range of 6 - 35 Ma. The tests were carried out on an 11th Gen Intel(R) Core(TM) i5-1135G7 processor with a valuable test time of 45 mins. The agreement is good, but due to the complexity of the space shuttle tail, the measurements are still subject to large errors compared to wind tunnel experiments. A comparison of the measured Fire-II return capsule standing-point heat values with the theory for calculating standing-point heat fluxes simulated using Fay & Riddell and wind tunnel experiments is provided to verify the validity of this procedure for hypersonic vehicle heat transfer prediction. The heat fluxes assessed using this method for different aerodynamic profiles of hypersonic vehicles agree very well with the theoretical solution.
基于c++的不同气动外形高超声速飞行器气动热环境与传热预测
本文讨论了建立一个统一的框架来开发高超声速加热计算的全速率方案。该方法在非结构化圈定网格中采用法向相矢量调整的流动追踪技术,并结合对流换热立定和非立定热流工程的经验公式。这是在c++语言环境中使用dev- c++编程完成的。在6 ~ 35 Ma的高超声速马赫数范围内,对航天飞机和阿波罗返回舱的气动热环境与风洞实验数据以及火II返回舱的站点传热测量结果进行了比较。测试在第11代Intel(R) Core(TM) i5-1135G7处理器上进行,测试时间为45分钟。虽然一致性很好,但由于航天飞机尾部的复杂性,与风洞实验相比,测量结果仍然存在较大误差。将Fire-II返回舱的实测站点热值与Fay & Riddell和风洞实验模拟的站点热流计算理论进行了比较,验证了该方法对高超声速飞行器传热预测的有效性。用该方法计算的高超声速飞行器不同气动外形的热通量与理论解吻合较好。
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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