化学推进系统高压燃烧室中推进剂的跨临界扩散界面流体力学

IF 32 1区 工程技术 Q1 ENERGY & FUELS
Lluís Jofre, Javier Urzay
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引用次数: 39

摘要

火箭发动机、大功率新一代燃气涡轮喷气发动机和柴油发动机通常涉及在亚临界温度下向高压燃烧室环境中喷射一种或多种反应物,特别是在高于混合物中单个成分临界点对应的压力下,大多数推进剂的临界点通常在13到50巴之间。这类在热力学空间中的轨迹传统上被称为跨临界的。然而,在如此高的压力下,对燃料雾化、汽化、混合和燃烧过程的基本理解仍然是难以捉摸的。特别是,尽管在常压下燃料喷雾的特征相对较好,但高压燃烧室中燃料分散的分析受到有限的实验诊断和可用的理论公式的阻碍。化学推进系统中使用的碳氢化合物燃料混合物的热力学描述是复杂的,并且涉及混合引起的现象,包括临界点的升高,从而混合物的共存区域扩展到比单个组分的临界压力大得多的压力。因此,在多组分系统中,受表面张力作用的界面可能会在高压下持续存在,并可能产生意想不到的喷雾状雾化动力学,而单组分系统在其临界点以上是不存在的。在这篇文章中,目前对这一现象的理解是在重碳氢化合物为燃料的推进系统的背景下进行回顾。重点是在计算流体动力学感兴趣的介观尺度上的分析描述。特别地,在范德华扩散界面理论的扩展版本的基础上,引入了一组对多组分流动的Navier-Stokes方程中的本构律的修正,补充了高压状态方程和对热力学势的适当重新定义。由此产生的公式涉及重新审视应力张量和热和物质输运通量的形式,并且能够描述由跨临界界面引起的介观体积效应,与高压下混合物的热力学相图一致。应用该理论说明了典型问题,包括十二烷/氮在非等温系统的跨临界界面。结果表明,推进剂流之间形成了一个跨临界界面,该界面在喷射孔下游持续存在,其距离与燃料流的特征热入口长度相同。跨临界界面在产生完全超临界混合层的边缘处消失。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Transcritical diffuse-interface hydrodynamics of propellants in high-pressure combustors of chemical propulsion systems

Rocket engines and high-power new generations of gas-turbine jet engines and diesel engines oftentimes involve the injection of one or more reactants at subcritical temperatures into combustor environments at high pressures, and more particularly at pressures higher than those corresponding to the critical points of the individual components of the mixture, which typically range from 13 to 50 bars for most propellants. This class of trajectories in the thermodynamic space has been traditionally referred to as transcritical. However, the fundamental understanding of fuel atomization, vaporization, mixing, and combustion processes at such high pressures remains elusive. In particular, whereas fuel sprays are relatively well characterized at normal pressures, analyses of dispersion of fuel in high-pressure combustors are hindered by the limited experimental diagnostics and theoretical formulations available. The description of the thermodynamics of hydrocarbon-fueled mixtures employed in chemical propulsion systems is complex and involves mixing-induced phenomena, including an elevation of the critical point whereby the coexistence region of the mixture extends up to pressures much larger than the critical pressures of the individual components. As a result, interfaces subject to surface-tension forces may persist in multicomponent systems despite the high pressures, and may give rise to unexpected spray-like atomization dynamics that are otherwise absent in monocomponent systems above their critical point. In this article, the current understanding of this phenomenon is reviewed within the context of propulsion systems fueled by heavy hydrocarbons. Emphasis is made on analytical descriptions at mesoscopic scales of interest for computational fluid dynamics. In particular, a set of modifications of the constitutive laws in the Navier–Stokes equations for multicomponent flows, supplemented with a high-pressure equation of state and appropriate redefinitions of the thermodynamic potentials, are introduced in this work based on an extended version of the diffuse-interface theory of van der Waals. The resulting formulation involves revisited forms of the stress tensor and transport fluxes of heat and species, and enables a description of the mesoscopic volumetric effects induced by transcritical interfaces consistently with the thermodynamic phase diagram of the mixture at high pressures. Applications of the theory are illustrated in canonical problems, including dodecane/nitrogen transcritical interfaces in non-isothermal systems. The results indicate that a transcritical interface is formed between the propellant streams that persists downstream of the injection orifice over distances of the same order as the characteristic thermal-entrance length of the fuel stream. The transcritical interface vanishes at an edge that gives rise to a fully supercritical mixing layer.

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来源期刊
Progress in Energy and Combustion Science
Progress in Energy and Combustion Science 工程技术-工程:化工
CiteScore
59.30
自引率
0.70%
发文量
44
审稿时长
3 months
期刊介绍: Progress in Energy and Combustion Science (PECS) publishes review articles covering all aspects of energy and combustion science. These articles offer a comprehensive, in-depth overview, evaluation, and discussion of specific topics. Given the importance of climate change and energy conservation, efficient combustion of fossil fuels and the development of sustainable energy systems are emphasized. Environmental protection requires limiting pollutants, including greenhouse gases, emitted from combustion and other energy-intensive systems. Additionally, combustion plays a vital role in process technology and materials science. PECS features articles authored by internationally recognized experts in combustion, flames, fuel science and technology, and sustainable energy solutions. Each volume includes specially commissioned review articles providing orderly and concise surveys and scientific discussions on various aspects of combustion and energy. While not overly lengthy, these articles allow authors to thoroughly and comprehensively explore their subjects. They serve as valuable resources for researchers seeking knowledge beyond their own fields and for students and engineers in government and industrial research seeking comprehensive reviews and practical solutions.
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