Gel propellants

IF 32 1区 工程技术 Q1 ENERGY & FUELS Progress in Energy and Combustion Science Pub Date : 2021-03-01 DOI:10.1016/j.pecs.2020.100885
Manisha B. Padwal , Benveniste Natan , D.P. Mishra
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The current definition of the gel propellants emphasizes their ability to flow under shear and gel propellants are almost exclusively intended to function like liquid propellants. Gel propellants have a considerable history; and research and development is continuously expanding across the world. Different research groups are working on the relevant areas of this field and research has gathered momentum in the first two decades of the present century. Hundreds of studies on all the aspects of gel propulsion including formulation, </span>rheological behavior<span>, atomization<span>, combustion, and applications, have appeared. Gel propellants have been applied in rocket motors<span>, ramjets, furnace combustion, and afterburners of jet engines. On this background, compilation and organization of the accumulated knowledge in this field, identification of relevant issues, unraveling of the links among the different areas of study, and identification of the open gaps for future study have become essential and these are the chief objectives in organizing the present review. This review encompasses the formulation, flow characterization, atomization, and combustion of gel propellants. We begin with a perspective on gel propellants and discuss the relevant aspects of conventional liquid propellants and previous efforts to improve their energetic performance. Inherent advantages of gel propellants and the challenges faced in their realization are considered. Formulation of gel propellants and their simulants is covered with emphasis on the description of different types of gelling agents and methods of their incorporation into the liquid propellants. Our emphasis is on the connection between formulation parameters and flow properties of gels. Of special significance are the recent attempts at formulating hypergolic gel propellants other than the hydrazine class. Flow properties of gels are of critical importance in tailoring their behaviors. Therefore, non-Newtonian flow properties of the gel propellants are discussed. Gels are 'complex fluids' and a number of rheological functions and measurement methods are necessary for comprehensively characterizing the complexity. Hence, we describe the rheological properties of many gel propellants and focus on their interpretation. Rheological matching of gels to develop gel propellant simulants is considered. Simulants provide a useful strategy to conduct flow and atomization experiments for hazardous or expensive propellants. Atomization of gel propellants is discussed with the aid of results in which various aspects of atomization of gel propellants using conventional and specially designed atomizers have been addressed. We also discuss the role of rheological properties in determining the behavior of gel fragments, ligaments, and droplets. A large amount of quantitative data on the spray properties are compiled and discussed in this review. Theoretical analyses of gel propellant breakup are reviewed. Discussion on combustion is divided into </span></span></span></span>droplet combustion<span> and spray combustion<span>. In droplet combustion, we include the studies on hypergolic and non-hypergolic gel propellants and consider the processes during heating, vaporization, and combustion of tethered and freely falling droplets of gel propellants. Attempts at theoretical analysis of these processes are considered. In case of hypergolic gels, current understanding of their ignition is reviewed using modeling studies. Spray combustion of gel propellants is considered with reference to the modeling studies on canonical spray diffusion and premixed flames and experimental observations corroborating their findings are discussed. A majority of spray combustion studies reported to date have been carried out on small-scale rocket motors. These studies are reviewed here and the reported performance parameters are compiled. In each of the sections, we also review the status of metalized gel propellants with consideration to choice of metals and experience with metal slurries. A roadmap for future progress is proposed and recommendations are made based on the discussion in the preceding sections. We have given particular attention to the linkages among the four areas of gel propellant combustion. Selected data have been extensively tabulated for many of the specific topics considered in this review and it is supplemented by a separate comprehensive table.</span></span></p></div>","PeriodicalId":410,"journal":{"name":"Progress in Energy and Combustion Science","volume":"83 ","pages":"Article 100885"},"PeriodicalIF":32.0000,"publicationDate":"2021-03-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1016/j.pecs.2020.100885","citationCount":"49","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Progress in Energy and Combustion Science","FirstCategoryId":"5","ListUrlMain":"https://www.sciencedirect.com/science/article/pii/S0360128520300952","RegionNum":1,"RegionCategory":"工程技术","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"ENERGY & FUELS","Score":null,"Total":0}
引用次数: 49

Abstract

The transformation of a liquid propellant into a semi-solid gel state paves way for energetically improved, reliable, safer, and possibly green futuristic propellant for rocket and ramjet propulsion. A review of the progress achieved on gel propellants so far is essential to expand the capabilities of gel propellants by adopting new avenues for research and development towards actual space flights. In keeping with this objective, we comprehensively present various aspects of gel propellants in this review. Physically, gel propellants are the fluids whose rheological properties are altered by gelling agents so that they behave as solids at rest and can be atomized and combusted like conventional liquid propellants. The current definition of the gel propellants emphasizes their ability to flow under shear and gel propellants are almost exclusively intended to function like liquid propellants. Gel propellants have a considerable history; and research and development is continuously expanding across the world. Different research groups are working on the relevant areas of this field and research has gathered momentum in the first two decades of the present century. Hundreds of studies on all the aspects of gel propulsion including formulation, rheological behavior, atomization, combustion, and applications, have appeared. Gel propellants have been applied in rocket motors, ramjets, furnace combustion, and afterburners of jet engines. On this background, compilation and organization of the accumulated knowledge in this field, identification of relevant issues, unraveling of the links among the different areas of study, and identification of the open gaps for future study have become essential and these are the chief objectives in organizing the present review. This review encompasses the formulation, flow characterization, atomization, and combustion of gel propellants. We begin with a perspective on gel propellants and discuss the relevant aspects of conventional liquid propellants and previous efforts to improve their energetic performance. Inherent advantages of gel propellants and the challenges faced in their realization are considered. Formulation of gel propellants and their simulants is covered with emphasis on the description of different types of gelling agents and methods of their incorporation into the liquid propellants. Our emphasis is on the connection between formulation parameters and flow properties of gels. Of special significance are the recent attempts at formulating hypergolic gel propellants other than the hydrazine class. Flow properties of gels are of critical importance in tailoring their behaviors. Therefore, non-Newtonian flow properties of the gel propellants are discussed. Gels are 'complex fluids' and a number of rheological functions and measurement methods are necessary for comprehensively characterizing the complexity. Hence, we describe the rheological properties of many gel propellants and focus on their interpretation. Rheological matching of gels to develop gel propellant simulants is considered. Simulants provide a useful strategy to conduct flow and atomization experiments for hazardous or expensive propellants. Atomization of gel propellants is discussed with the aid of results in which various aspects of atomization of gel propellants using conventional and specially designed atomizers have been addressed. We also discuss the role of rheological properties in determining the behavior of gel fragments, ligaments, and droplets. A large amount of quantitative data on the spray properties are compiled and discussed in this review. Theoretical analyses of gel propellant breakup are reviewed. Discussion on combustion is divided into droplet combustion and spray combustion. In droplet combustion, we include the studies on hypergolic and non-hypergolic gel propellants and consider the processes during heating, vaporization, and combustion of tethered and freely falling droplets of gel propellants. Attempts at theoretical analysis of these processes are considered. In case of hypergolic gels, current understanding of their ignition is reviewed using modeling studies. Spray combustion of gel propellants is considered with reference to the modeling studies on canonical spray diffusion and premixed flames and experimental observations corroborating their findings are discussed. A majority of spray combustion studies reported to date have been carried out on small-scale rocket motors. These studies are reviewed here and the reported performance parameters are compiled. In each of the sections, we also review the status of metalized gel propellants with consideration to choice of metals and experience with metal slurries. A roadmap for future progress is proposed and recommendations are made based on the discussion in the preceding sections. We have given particular attention to the linkages among the four areas of gel propellant combustion. Selected data have been extensively tabulated for many of the specific topics considered in this review and it is supplemented by a separate comprehensive table.

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凝胶推进剂
将液体推进剂转变为半固体凝胶状态,为大力改进、可靠、更安全、可能是绿色的未来火箭和冲压发动机推进剂铺平了道路。必须审查凝胶推进剂迄今取得的进展,以便通过采用新的研究和开发途径来扩大凝胶推进剂的能力,以实现实际的空间飞行。为了达到这个目的,我们在本文中全面介绍了凝胶推进剂的各个方面。从物理上讲,凝胶推进剂是一种流体,其流变性能被胶凝剂改变,因此它们在静止状态下表现为固体,可以像传统的液体推进剂一样雾化和燃烧。目前凝胶推进剂的定义强调它们在剪切下流动的能力,凝胶推进剂几乎完全像液体推进剂一样发挥作用。凝胶推进剂有相当长的历史;研发在全球范围内不断扩大。不同的研究小组正在对这一领域的有关领域进行研究,在本世纪头二十年中,研究取得了势头。已经出现了数百项关于凝胶推进的各个方面的研究,包括配方、流变行为、雾化、燃烧和应用。凝胶推进剂已应用于火箭发动机、冲压发动机、炉膛燃烧和喷气发动机的加力燃烧室。在此背景下,汇编和组织本领域积累的知识,确定有关问题,揭示不同研究领域之间的联系,以及确定未来研究的空白已变得至关重要,这些是组织本审查的主要目标。本文综述了凝胶推进剂的配方、流动特性、雾化和燃烧。我们首先从凝胶推进剂的角度出发,讨论常规液体推进剂的相关方面以及以前为提高其能量性能所做的努力。分析了凝胶推进剂的固有优势及其实现过程中面临的挑战。凝胶推进剂及其模拟物的配方包括重点描述不同类型的胶凝剂及其掺入液体推进剂的方法。我们的重点是配方参数和凝胶流动特性之间的联系。特别重要的是最近在配制自燃凝胶推进剂方面的尝试,而不是肼类。凝胶的流动特性对调整其行为至关重要。因此,本文讨论了凝胶推进剂的非牛顿流动特性。凝胶是一种“复杂流体”,要全面表征其复杂性,需要多种流变函数和测量方法。因此,我们描述了许多凝胶推进剂的流变特性,并着重于它们的解释。考虑凝胶的流变匹配,开发凝胶推进剂模拟剂。模拟为进行危险或昂贵推进剂的流动和雾化实验提供了有用的策略。通过对常规雾化器和特殊设计雾化器雾化凝胶推进剂各方面的研究结果,讨论了凝胶推进剂的雾化问题。我们还讨论了流变特性在确定凝胶碎片、韧带和液滴行为中的作用。本文收集和讨论了大量有关喷雾性能的定量数据。综述了凝胶推进剂破碎的理论分析。对燃烧的讨论分为液滴燃烧和喷雾燃烧。在液滴燃烧中,我们包括了自燃和非自燃凝胶推进剂的研究,并考虑了束缚和自由下落的凝胶推进剂液滴的加热、蒸发和燃烧过程。考虑对这些过程进行理论分析的尝试。在自燃凝胶的情况下,目前对其点火的理解是使用模型研究进行了回顾。结合典型喷雾扩散和预混火焰的模型研究,讨论了凝胶推进剂的喷雾燃烧问题,并对实验结果进行了讨论。迄今为止报告的大多数喷雾燃烧研究都是在小型火箭发动机上进行的。这里回顾了这些研究,并汇编了报告的性能参数。在每一节中,我们还回顾了金属化凝胶推进剂的现状,考虑到金属的选择和金属浆料的经验。提出了未来进展的路线图,并根据前几节的讨论提出了建议。我们特别注意了凝胶推进剂燃烧的四个领域之间的联系。 本综述中所考虑的许多具体主题的选定数据已广泛制成表格,并由单独的综合表格补充。
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
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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