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[1]王凯,唐亮,雷凡培,等.液液针栓多喷注单元喷雾场数值模拟[J].火箭推进,2023,49(02):15-26.
　WANG Kai,TANG Liang,LEI Fanpei,et al.Numerical simulation on spray field of liquid-liquid pintle multi-injector elements[J].Journal of Rocket Propulsion,2023,49(02):15-26.

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液液针栓多喷注单元喷雾场数值模拟

《火箭推进》[ISSN:1672-9374/CN:CN 61-1436/V] 卷: 49 期数: 2023年02期页码: 15-26 栏目: 目次出版日期: 2023-04-25

Title:: Numerical simulation on spray field of liquid-liquid pintle multi-injector elements

文章编号:: 1672-9374(2023)02-0015-12

作者:: 王凯¹; 唐亮¹; 雷凡培²; 杨岸龙¹; 周立新¹; (1.西安航天动力研究所液体火箭发动机技术重点实验室,陕西西安 710100; 2.中国船舶工业集团有限公司,北京 100044)

Author(s):: WANG Kai¹; TANG Liang¹; LEI Fanpei²; YANG Anlong¹; ZHOU Lixin¹; (1.Key Laboratory for Liquid Rocket Engine Technology, Xi'an Aerospace Propulsion Institute, Xi'an 710100, China; 2.China State Shipbuilding Corporation, Beijing 100044, China)

关键词:: 液液针栓喷注器; 相邻喷注单元; 相互影响; 雾场结构; 自适应网格加密

Keywords:: liquid-liquid pintle injector; adjacent injector elements; interaction; spray field structure; adaptive mesh refinement

分类号:: V434.3

文献标志码:: A

摘要:: 为了研究相邻喷注单元间相互影响对针栓式喷注器喷雾场的影响,以平面针栓多喷注单元为研究对象,采用基于AMR(adaptive mesh refinement)技术和分相识别的PLIC VOF(piecewise linear interface calculation VOF)新方法,实现了针栓式喷注器雾化过程的高保真数值模拟。给出了喷雾场典型的结构特征及液雾的分布特性,对比了多喷注单元与单喷注单元喷雾场的差异,揭示了相邻喷注单元间的相互影响机制。研究表明,新的仿真方法在精细研究针栓式喷注器喷雾场方面具有较好的准确性。与单喷注单元相比,多喷注单元喷雾场主要存在以下特殊结构:相邻两雾扇相撞背部呈脊状结构,使得雾化区域大于雾化角; 两雾扇相撞在中间对称面汇聚形成薄液膜,使整个雾化角范围内均有液滴分布; 相邻两孔之间形成一定下漏率和下漏液膜宽度; 液膜路和液束路的液滴粒径均显著增大了约35,流强和混合比沿径向分布更趋于均匀。相邻喷注单元间的相互影响机制为:相邻喷雾扇相撞后原先各自向外展开的雾扇被挤回中心对称面,其厚度是原雾扇的两倍,其他未发生撞击位置的液膜厚度保持不变,最终形成的喷雾扇结构呈扁平的多凹腔状。

Abstract:: In order to study the influence of the interaction between adjacent injector elements on the spray field in pintle injector, taking the plane pintle multi-injector element as the research object, based on a new method of AMR(adaptive mesh refinement)technology and PLIC VOF(piecewise linear interface calculation VOF)method in which each phase was individually identified, the spray process of pintle injector was simulated with high-fidelity.The typical structure characteristics and spatial distribution characteristics of the spray field were demonstrated quantitatively.The spray field were compared with that of the injector element, and the mechanism of interaction between adjacent injector elements was revealed. The results show that the new simulation method has good accuracy in studying the spray field of pintle injector.Compared with the injector element, the spray field of the multi-injector element mainly has the following special structures:two adjacent spray fans collide to form a ridge structure on the back, and causing the spray area to exceed the spray angle area.In addition, two spray fans collide and converge on the middle symmetry plane to form a thin liquid film, which makes the droplets distribute throughout the spray angle area.A certain leakage rate and leakage width of liquid sheet are formed between two adjacent radial orifices.The droplet diameters of liquid sheet path and liquid jet path increase significantly by about 35, and the distribution of flow intensity and mixing ratio tends to be more uniform along the radial direction.The interaction mechanism between adjacent elements is as follows:after the collision of adjacent spray fans, the original outward deployed spray fans are pushed back to the central symmetry plane, whose thickness is twice that of the original spray fan.However, the thickness of the liquid film at other nonimpact positions remains unchanged.Finally, the structure of the spray fan is a flat multi-cavity structure.

参考文献/References:

[1] 张雪松.猎鹰火箭的基础:不断升级的梅林发动机[J].卫星与网络,2017(6):40-41.
[2] 刘昌波.针栓式喷注器雾化特性的多尺度仿真研究[D].西安:西安航天动力研究所,2014.
[3] LEE K,NAM J,KOO J.Experimental research about combustion of multi-hole pintle injector using LOX/GCH₄[C]//27th International Colloquium on the Dynamics of Explosions and Reactive Systems.Beijing,China:IDERS,2019.
[4] RYU H,YU I,KIM W,et al.Experimental investigation on combustion performance of a pintle injector engine with double-row rectangular slot[J].Journal of the Korean Society of Propulsion Engineers,2017,21(3):25-33.
[5] LEE S,KIM D,KOO J,et al.Spray characteristics of a pintle injector based on annular orifice area[J].Acta Astronautica,2020,167:201-211.
[6] CHEN H Y,LI Q L,CHENG P.Experimental research on the spray characteristics of pintle injector[J].Acta Astronautica,2019,162:424-435.
[7] SAKAKI K,KAKUDO H,NAKAYA S,et al.Combustion characteristics of ethanol/liquid-oxygen rocket-engine combustor with planar pintle injector[J].Journal of Propulsion and Power,2017,33(2):514-521.
[8] SAKAKI K,KAKUDO H,NAKAYA S,et al.Performance evaluation of rocket engine combustors using ethanol/liquid oxygen pintle injector[C]//52nd AIAA/SAE/ASEE Joint Propulsion Conference.Reston,Virginia:AIAA,2016.
[9] KIM H,KANG H,KWON S.Liquid sheet-sheet impinging structure for pintle injector with nontoxic hypergolic bipropellant[J].Journal of Propulsion and Power,2020,36(2):302-307.
[10] 成鹏.变推力火箭发动机喷雾燃烧动态过程研究[D].长沙:国防科技大学,2018.
[11] 王凯,雷凡培,杨岸龙,等.针栓式喷注单元膜束撞击雾化混合过程数值模拟[J].航空学报,2020,41(9):123802.
[12] POPINET S.Gerris:A tree-based adaptive solver for the incompressible Euler equations in complex geometries[J].Journal of Computational Physics,2003,190(2):572-600.
[13] FUSTER D,POPINET S.Simulation of primary atomization with an octree adaptive mesh refinement and VOF method[J].International Journal of Multiphase Flow,2009,35(6):550-565.
[14] CHEN X D,XUE C D,ZHANG L,et al.Inertial migration of deformable droplets in a microchannel[J].Physics of Fluids,2014,26(11):112003.
[15] CHEN X D,SUN Y N,XUE C D,et al.Tunable structures of compound droplets formed by collision of immiscible microdroplets[J].Microfluidics and Nanofluidics,2017,21(6):1-14.
[16] 王凯,雷凡培,杨岸龙,等.针栓式喷注器液膜下漏率预估模型[J].航空动力学报,2020,35(10):2223-2234.
[17] 王凯,雷凡培,杨岸龙,等.径向孔形状对针栓式喷注器液膜下漏率的影响[J].航空学报,2021,42(6):124384.
[18] 王凯,雷凡培,张波涛,等.针栓式喷注单元雾化角模型分析[J].航空学报,2020,41(10):123622.
[19] FRANCOIS M,CUMMINS S.A balanced-force algorithm for continuous and sharp interfacial surface tension models within a volume tracking framework[J].Journal of Computational Physics,2006,213(1):141-173.
[20] 阎超,于剑,徐晶磊,等.CFD模拟方法的发展成就与展望[J].力学进展,2011,41(5):562-589.
[21] 王凯,杨国华,李鹏飞,等.离心式喷嘴内部流动过程数值仿真分析[J].火箭推进,2016,42(4):14-20.
WANG K,YANG G H,LI P F,et al.Numerical simulation of internal flow process in pressure swirl injector[J].Journal of Rocket Propulsion,2016,42(4):14-20.
[22] 杨国华,张波涛,周立新,等.液气动量比对内混式直流气液喷嘴雾化特性影响[J].火箭推进,2019,45(5):66-73.
YANG G H,ZHANG B T,ZHOU L X,et al.Effects of momentum ratio on atomization characteristics of internal mixing gas-liquid injector[J].Journal of Rocket Propulsion,2019,45(5):66-73.
[23] GUEYFFIER D, LI J, NADIM A,et al.Volume-of-fluid interface tracking with smoothed surface stress methods for three-dimensional flows[J].Journal of Computational Physics,1999,152(2):423-456.
[24] AULISA E,MANSERVISI S,SCARDOVELLI R,et al.Interface reconstruction with least-squares fit and split advection in three-dimensional Cartesian geometry[J].Journal of Computational Physics,2007,225(2):2301-2319.
[25] DEBAR R.Fundamentals of the KRAKEN code[R].Livermore,CA:Lawrence Livermore National Laboratory,1974.
[26] 王凯.针栓式喷注器液膜液束相互作用机制及喷雾场特性研究[D].西安:西安航天动力研究所,2021.

备注/Memo

收稿日期:2022-06-13; 修回日期:2022-07-12
基金项目:国家自然科学基金(11502186)
作者简介:王凯(1990—),男,博士,研究领域为液体火箭发动机喷雾燃烧技术。

更新日期/Last Update: 1900-01-01