Direct numerical simulation of a subcritical coaxial injection in fiber regime using sharp interface reconstruction

IF 3.6 2区 工程技术 Q1 MECHANICS International Journal of Multiphase Flow Pub Date : 2024-08-26 DOI:10.1016/j.ijmultiphaseflow.2024.104974
J.-C. Hoarau , L.-H. Dorey , D. Zuzio , F. Granger , J.-L. Estivalèzes
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Abstract

The numerical simulation of space launchers combustion chambers is a topic of increasing interest, as it may help the development of safer and more efficient designs. Understanding fuel injection is a particularly severe challenge. The liquid oxygen is injected by a round orifice surrounded by an annular gaseous stream of fuel, leading in subcritical conditions to a two-phase assisted atomization process. The result of this process is a very dense and polydisperse two-phase flow, which strongly influences the behavior of the chamber. Experimental investigation of this flow is difficult due to the axisymmetric geometry and the dense characteristic of the spray. Neither RANS nor Large Eddy Simulation (LES) possess reliable models able to reproduce the smallest scales of atomization, one of the reasons being the lack of relevant experimental data. Therefore, this work aims to provide detailed information on the atomization process using Direct Numerical Simulation. This paper presents a Direct Numerical Simulation (DNS) of a coaxial liquid–gas assisted atomization in the typical fiber regime encountered in cryogenic injectors. This study aims to better understand the evolution of liquid topology and extract relevant information that may help develop larger-scale models. The flow was first analyzed in terms of topology statistical data, using a dedicated detection and classification algorithm that could characterize the individual liquid structures. These include the central liquid core, the ligament created during primary atomization, and the spherical droplet obtained at the end of the atomization process. Subsequently, a more global statistical topology indicator was investigated, namely the interface area density distribution. This quantity is used in larger-scale RANS or LES models to predict the smallest scales of atomization. Therefore, understanding its behavior in a realistic case is of utmost importance. The interface area density distribution was correlated to the global jet behavior and the liquid topology data obtained by the detection algorithm. The results showed, in particular, a strong correlation between the initial increase of liquid–gas interface area density with the generation of ligaments and between the continuous decrease of the interface area density during droplet formation and stabilization.

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利用尖锐界面重构对光纤系统中的亚临界同轴注入进行直接数值模拟
航天发射器燃烧室的数值模拟是一个越来越受关注的课题,因为它有助于开发更安全、更高效的设计。了解燃料喷射是一项特别严峻的挑战。液氧由一个圆形喷口喷入,周围是环形的气态燃料流,在亚临界状态下形成两相辅助雾化过程。这一过程的结果是产生了非常密集和多分散的两相流,这对气室的行为产生了很大影响。由于喷雾的轴对称几何形状和致密特性,很难对这种流动进行实验研究。无论是 RANS 还是大涡流模拟(LES)都不具备能够再现最小尺度雾化的可靠模型,原因之一是缺乏相关的实验数据。因此,这项工作旨在利用直接数值模拟提供雾化过程的详细信息。本文介绍了在低温喷射器中遇到的典型纤维状态下同轴液气辅助雾化的直接数值模拟(DNS)。这项研究旨在更好地了解液体拓扑结构的演变,并提取有助于开发更大规模模型的相关信息。首先从拓扑统计数据的角度对流动进行了分析,使用了一种专门的检测和分类算法,该算法可以描述单个液体结构的特征。这些结构包括中心液核、初级雾化过程中产生的韧带以及雾化过程结束时获得的球形液滴。随后,我们研究了一种更全面的统计拓扑指标,即界面面积密度分布。在较大尺度的 RANS 或 LES 模型中,这个量被用来预测雾化的最小尺度。因此,了解其在实际情况中的行为至关重要。界面区域密度分布与全局射流行为和通过检测算法获得的液体拓扑数据相关联。结果特别表明,液气界面面积密度的初始增加与韧带的产生之间,以及界面面积密度在液滴形成和稳定过程中的持续降低之间存在着很强的相关性。
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来源期刊
CiteScore
7.30
自引率
10.50%
发文量
244
审稿时长
4 months
期刊介绍: The International Journal of Multiphase Flow publishes analytical, numerical and experimental articles of lasting interest. The scope of the journal includes all aspects of mass, momentum and energy exchange phenomena among different phases such as occur in disperse flows, gas–liquid and liquid–liquid flows, flows in porous media, boiling, granular flows and others. The journal publishes full papers, brief communications and conference announcements.
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