Collaborative Research: A new understanding of droplet breakup: hydrodynamic instability under complex acceleration

合作研究：对液滴破碎的新认识：复杂加速下的流体动力学不稳定性

• 批准号: 2332916
• 负责人: Jacob McFarland
• 金额: $ 30.64万
• 依托单位: Texas A&M Engineering Experiment Station
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2024
• 资助国家: 美国
• 起止时间: 2024-01-01 至 2026-12-31
• 项目状态: 未结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=2332916&HistoricalAwards=false
• 关键词: Collaborative; Research; new; understanding; droplet

The breakup of droplets is important in many engineering applications such as agricultural sprays, combustion of liquid fuels, and the impact of rain droplets on aircraft. The breakup of droplets in a gas occurs due to a difference in the gas and droplet velocities, acting on the droplet surface like waves on the ocean. At low speeds, droplet breakup occurs under relatively constant conditions. However, at high speeds droplet breakup is more complex, involving sudden changes in the gas velocity. In many high-speed applications, such as the impact of rain droplets on hypersonic aircraft, droplets will first experience a sudden increase in gas velocity driving rapid breakup, followed by rapid decrease in velocity, slowing and modifying the breakup process. In order to design advanced hypersonic vehicles, accurate and efficient models for these complex breakup processes are needed. This project will use a unique combination of experiments and simulations to examine droplet breakup under these complex conditions and develop a simple model for use in computer simulations. The project will also engage both graduate and undergraduate students in research and experimental design, training them in skills vital to our national security. The overall goal of this project is to significantly improve our understanding of droplet breakup under complex, variable accelerations by developing a general hydrodynamic instability-based model for droplet breakup. The project will test the central hypothesis: droplet breakup is dominated by a variable acceleration, three-layer Rayleigh Taylor instability. Simulations will fully resolve interfacial dynamics and study the growth rate of instabilities under varying acceleration histories. Experiments will image droplet breakup and child droplet sizes with high-speed fluorescence techniques under different acceleration histories. These measurements will be used to test a new breakup model incorporating variable acceleration hydrodynamic instability models, large-scale droplet deformation, and dynamic gas-droplet conditions. The breakup model will be useful in a predictive capacity in a wide range of applications such as blast mitigation in industrial processes, hypersonic weather impacts, and advanced detonation-based propulsion cycles. The model will make it possible to perform system-level simulations in these applications, enabling accurate and efficient modeling of droplet events. The broader impact of this work lies in enabling efficient simulation of high-speed multiphase problems of particular importance to energy efficiency and national defense and in engaging students of diverse backgrounds in multiphase studies and research.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

液滴的分解在许多工程应用中非常重要，例如农业喷雾、液体燃料的燃烧以及雨滴对飞机的影响。气体中液滴的破碎是由于气体和液滴速度的差异而发生的，作用在液滴表面上，就像海洋上的波浪一样。在低速时，液滴破碎是在相对恒定的条件下发生的。然而，在高速下，液滴破碎更加复杂，涉及气体速度的突然变化。在许多高速应用中，例如雨滴对高超音速飞机的撞击，液滴首先会经历气体速度的突然增加，导致快速破碎，然后速度迅速降低，从而减慢和改变破碎过程。为了设计先进的高超音速飞行器，需要针对这些复杂的分解过程提供准确且高效的模型。该项目将采用实验和模拟的独特组合来检查这些复杂条件下的液滴破裂，并开发一个用于计算机模拟的简单模型。该项目还将吸引研究生和本科生参与研究和实验设计，培训他们对我们国家安全至关重要的技能。该项目的总体目标是通过开发基于通用流体动力学不稳定性的液滴破碎模型，显着提高我们对复杂、可变加速度下液滴破碎的理解。该项目将测试中心假设：液滴破裂由可变加速度、三层瑞利泰勒不稳定性主导。模拟将完全解决界面动力学问题并研究不同加速度历史下不稳定性的增长率。实验将在不同的加速历史下使用高速荧光技术对液滴破裂和子液滴尺寸进行成像。这些测量结果将用于测试新的破碎模型，该模型结合了可变加速度流体动力学不稳定性模型、大规模液滴变形和动态气体液滴条件。该分解模型将在各种应用中具有预测能力，例如工业过程中的爆炸缓解、高超音速天气影响和先进的基于爆炸的推进循环。该模型将使在这些应用中执行系统级模拟成为可能，从而实现对液滴事件的准确和高效的建模。这项工作的更广泛影响在于能够有效模拟对能源效率和国防特别重要的高速多相问题，并让不同背景的学生参与多相研究。该奖项反映了 NSF 的法定使命，并被认为是值得的通过使用基金会的智力优势和更广泛的影响审查标准进行评估来获得支持。