On supersonic combustion and hypersonic propulsion

Q2 Mathematics Advances in Mechanics Pub Date : 2021-03-25 DOI:10.6052/1000-0992-21-008
Zonglin Jiang
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引用次数: 5

Abstract

After the long and strenuous efforts covering more than 50 years and the tortuous ex-periences, feasibility of the scramjet concept has finally been proven. In this paper, the main factors influencing the technical maturity of the scramjet engine are briefly analysed. A matter of utmost con-cern for this new type of air-breathing engine is the net thrust. The production of engine thrust using supersonic combustion encountered a number of practical requirements which were often found to contra-dict each other. Several flight tests showed that the net engine thrust was still not as good as expected. The acceleration capability and mode transition of scramjet with liquid hydrocarbon fuels (kerosene) operating at flight Mach numbers about 5 has become the bottleneck preventing scramjet engine from continuing development. Research showed that the use of endothermic hydrocarbon fuels is not only necessary for engine cooling but also a critical measure for improving engine thrust and performance. Changes of thermo-physical-chemical characteristics of endothermic fuels during heat absorption make additional contributions to the combustion performance which is essential to the scramjet net thrust. Currently, the technology of experimental simulation and measurement is still lagging behind the needs. The complete duplication or true similarity of atmospheric flight environment, engine size and test du-ration remains impossible. Therefore, computational fluid dynamics (CFD) has become an important tool besides experiment. However, numerical simulation of supersonic combustion encountered challenges which come from both turbulence and chemical kinetics as well as their interaction. It will inevitably af-fect the proper assessment of the engine performance. Several frontiers of research in this developing field are pointed out: mode transition in the dual-mode scramjet, active cooling by endothermic hydrocarbon fuel with catalytic cracking coupled with supersonic combustion, combustion stability, experimental simulation and development of test facilities, measurements of the inner flow-field characteristics and engine performance, turbulence modeling, kerosene surrogate fuels and reduced chemical kinetic mechanisms, and so on. Also, directions for future research efforts are proposed and suggestions for the next 5-10 years are given.
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论超音速燃烧与高超音速推进
经过50多年漫长而艰苦的工作和曲折的经历,超燃冲压发动机概念的可行性最终得到了证明。本文简要分析了影响超燃冲压发动机技术成熟度的主要因素。这种新型吸气式发动机最需要注意的是净推力。利用超音速燃烧产生发动机推力遇到了许多实际要求,这些要求往往相互矛盾。几次飞行试验表明,发动机的净推力仍然不如预期。使用液态烃燃料(煤油)的超燃冲压发动机在马赫数约为5的情况下运行,其加速能力和模式转换已成为阻碍超燃冲压喷气发动机继续发展的瓶颈。研究表明,使用吸热碳氢化合物燃料不仅是发动机冷却的必要条件,也是提高发动机推力和性能的关键措施。吸热燃料在吸热过程中的热物理化学特性的变化对燃烧性能做出了额外的贡献,这对超燃冲压发动机的净推力至关重要。目前,实验模拟和测量技术仍落后于需求。大气飞行环境、发动机尺寸和测试数据的完全复制或真正相似仍然是不可能的。因此,计算流体动力学(CFD)已成为实验之外的重要工具。然而,超音速燃烧的数值模拟遇到了来自湍流和化学动力学及其相互作用的挑战。这将不可避免地影响对发动机性能的正确评估。指出了这一发展领域的几个研究前沿:双模超燃冲压发动机的模式转换、吸热碳氢化合物燃料的主动冷却以及与超音速燃烧相结合的催化裂化、燃烧稳定性、实验模拟和测试设施的开发、内流场特性和发动机性能的测量,湍流模型、煤油替代燃料和还原化学动力学机制等。并提出了未来研究的方向和未来5-10年的建议。
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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来源期刊
Advances in Mechanics
Advances in Mechanics Mathematics-Mathematical Physics
CiteScore
3.40
自引率
0.00%
发文量
1074
期刊介绍: "Advances in Mechanics" is a comprehensive academic journal supervised by the Chinese Academy of Sciences and jointly sponsored by the Institute of Mechanics of the Chinese Academy of Sciences and the Chinese Society of Theoretical and Applied Mechanics, focusing on publishing high-level review articles in the field of mechanics, with special attention to the bidirection drive of mechanics and applications. Welcome articles facing the major national needs, from the perspective of engineering systems, summarize and analyze the research history and current situation of common or bottleneck mechanics issues, and have a foreseeable article about the future Welcome the forefront of mechanics, exploring new directions, new fields, and enlightening articles; Welcome in-depth summary of the mechanics results or lessons with important reference and reference value, so that the latecomers can better create and invented articles on the basis of the predecessors; Encourage creative ideas and suggestions for current important academic issues related to the development of mechanics.
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