Study on dynamic characteristics of gas-liquid internal mixing injector under backpressure
-
摘要:
通过数值模拟方法研究了气液内混喷嘴在反压条件下的动态雾化特性,重点分析了不同频率振荡对雾化场的影响。研究采用VOF转DPM(volume of fluid to discrete particle method)耦合模型,结合网格自适应加密(AMR)技术,模拟了喷嘴内气液两相流的雾化过程。结果表明:在一定反压条件下,对入口施加激励能够显著改善雾化效果,但频率过高会导致部分液滴直径增大,整体雾化效果优于稳态工况。此外,喷雾锥角在频率变化时会有一定升高,而液滴的索太尔平均直径(SMD)呈现周期性波动,频率越高,平均SMD值越大;频率增加会让喷嘴出口流量振荡增强,相位滞后。研究为液体火箭发动机内混喷嘴的动态特性优化提供了参考。
Abstract:The dynamic atomization characteristics of gas-liquid internally mixed injectors under backpressure conditions was investigated through numerical simulations, with a focus on the influences of different frequencies on the atomization field. A volume of fluid to discrete particle method (VOF-to-DPM) model combined with adaptive mesh refinement (AMR) was employed to simulate the atomization process of gas-liquid two-phase flow inside the injector. The results indicated that under certain backpressure conditions, excitations at the inlet can significantly improve the atomization performance. However, excessively high frequencies led to an increase in the diameter of some droplets, though the overall atomization effect remained superior to steady-state operation. Additionally, the spray cone angle increased with frequency variation, while the average Sauter mean diameter (SMD) exhibited periodic fluctuations-higher frequencies result in larger overall SMD values. Furthermore, increasing the frequency enhanced flow oscillation at the injector exit and introduced phase lag. This study could provide valuable insights for optimizing the dynamic characteristics of internally mixed injectors in liquid rocket engines.
-
图 11 不同轴向位置的索太尔平均直径沿z方向分布曲线
Figure 11. Sauter mean diameter distribution along z-direction at various axial positions
图 12 未转化成液滴的液相占比沿轴线时均曲线
Figure 12. Time-averaged axial profile of liquid phase fraction (unatomized)
图 15 不同振荡频率下液滴大小及空间分布
Figure 15. Droplet size and spatial distribution of droplets at different oscillation frequencies
图 16 不同轴向位置的索太尔平均直径沿z方向时均分布曲线
Figure 16. Time-averaged Sauter mean diameter distribution along z-direction at various axial positions
图 18 雾化场动态SMD变化曲线
Figure 18. Temporal evolution of Sauter mean diameter in the spray field
图 22 内混喷嘴幅频、相频曲线
Figure 22. Amplitude-phase characteristics of internal mixing injectors
表 1 仿真工况与实验结果对比
Table 1. Comparison between simulation and experimental results
工况 SMD/μm 喷雾锥角/(°) SMD误差/% 喷雾锥角误差/% 工况1 仿真 192.15 40 6.67 4.76 实验 180.57 42 工况5 仿真 195.55 44 5.84 2.22 实验 207.68 45 
下载: 导出CSV
-
[1] SUTTON G P. History of liquid-propellant rocket engines in Russia, formerly the Soviet Union[J]. Journal of Propulsion and Power, 2003, 19(6): 1008-1037. doi: 10.2514/2.6943 [2] LEFEBVRE A H, BALLAL D R. Gas turbine combustion[M]. London: CRC (Chemical and Rubber Company) Press, 2010. [3] BRONIARZ-PRESS L, OCHOWIAK M, ROZANSKI J, et al. The atomization of water-oil emulsions[J]. Experimental Thermal and Fluid Science, 2009, 33(6): 955-962. doi: 10.1016/j.expthermflusci.2009.04.002 [4] FERREIRA G, GARCÍA J A, BARRERAS F, et al. Design optimization of twin-fluid atomizers with an internal mixing chamber for heavy fuel oils[J]. Fuel Processing Technology, 2009, 90(2): 270-278. doi: 10.1016/j.fuproc.2008.09.013 [5] BABINSKY E, SOJKA P E. Modeling drop size distributions[J]. Progress in Energy and Combustion Science, 2002, 28(4): 303-329. doi: 10.1016/S0360-1285(02)00004-7 [6] LIU Haifeng, GONG Xin, LI Weifeng, et al. Prediction of droplet size distribution in sprays of prefilming air-blast atomizers[J]. Chemical Engineering Science, 2006, 61(6): 1741-1747. doi: 10.1016/j.ces.2005.10.012 [7] URBÁN A, ZAREMBA M, MALÝ M, et al. Droplet dynamics and size characterization of high-velocity airblast atomization[J]. International Journal of Multiphase Flow, 2017, 95: 1-11. doi: 10.1016/j.ijmultiphaseflow.2017.02.001 [8] ZHOU Weixing, YU Zunhong. Multifractality of drop breakup in the air-blast nozzle atomization process[J]. Physical Review E, 2000, 63: 016302. doi: 10.1103/PhysRevE.63.016302 [9] 曹建明, 朱辉, 郭广祥, 等. 空气助力改善液滴雾化质量的研究[J]. 试验流体力学, 2013, 27(1): 56-60, 87. CAO Jianming, ZHU Hui, GUO Guangxiang, et al. Study on assistant to improve quality of droplet atomization[J]. Journal of Experiments in Fluid Mechanics, 2013, 27(1): 56-60, 87. (in ChineseCAO Jianming, ZHU Hui, GUO Guangxiang, et al. Study on assistant to improve quality of droplet atomization[J]. Journal of Experiments in Fluid Mechanics, 2013, 27(1): 56-60, 87. (in Chinese) [10] 白鹏博, 邢玉明, 王泽, 等. 内混式喷嘴雾化特性的试验与仿真研究[J]. 流体机械, 2015, 43(2): 1-6. BAI Pengbo, XING Yuming, WANG Ze, et al. Experimental and simulation study on atomization characteristics of Internal mixing nozzles[J]. Fluid Machinery, 2015, 43(2): 1-6. (in Chinese doi: 10.3969/j.issn.1005-0329.2015.02.001BAI Pengbo, XING Yuming, WANG Ze, et al. Experimental and simulation study on atomization characteristics of Internal mixing nozzles[J]. Fluid Machinery, 2015, 43(2): 1-6. (in Chinese) doi: 10.3969/j.issn.1005-0329.2015.02.001 [11] MA Rui, DONG Bo, YU Zhongqiang, et al. An experimental study on the spray characteristics of the air-blast atomizer[J]. Applied Thermal Engineering, 2015, 88: 149-156. doi: 10.1016/j.applthermaleng.2014.11.068 [12] 刘丽艳, 杨静, 孔庆森, 等. 空气雾化喷嘴的液滴雾化性能试验研究[J]. 化学工业与工程, 2013, 30(3): 60-65. LIU Liyan, YANG Jing, KONG Qingsen, et al. Experimental study on atomization performance of droplets in air atomizing nozzle[J]. Chemical Industry and Engineering, 2013, 30(3): 60-65. (in ChineseLIU Liyan, YANG Jing, KONG Qingsen, et al. Experimental study on atomization performance of droplets in air atomizing nozzle[J]. Chemical Industry and Engineering, 2013, 30(3): 60-65. (in Chinese) [13] YANG L J, FU Q F. Genuine new liquid rocket engine thrust chamber design[M]. Beijing University of Aeronautics and Astronautics Press, Beijing, 2013. [14] WANG Hetang, WU Jinlong, DU Yunhe, et al. Investigation on the atomization characteristics of a solid-cone spray for dust reduction at low and medium pressures[J]. Advanced Powder Technology, 2019, 30(5): 903-910. doi: 10.1016/j.apt.2019.02.004 [15] QIAO Wentong, WANG Shaoyan, YANG Xiaocong, et al. Experimental study on the spray characteristics of an internal-mixing gas-liquid injector[J]. Acta Astronautica, 2024, 221: 46-65. doi: 10.1016/j.actaastro.2024.05.006 [16] CULICK F. Combustion instabilities in propulsion systems[M]// CULICK F, HEITOR M V, WHITELAW J H. Unsteady combustion. Dordrecht, Holland: Springer, 1996: 173-241. [17] BAZAROV V G. Fluid injectors dynamics[M]. Moscow: Mashinostroenie Publication, 1979. [18] BAZAROV V G. Influence of propellant injector stationary and dynamic parameters on high frequency combustion stability: AIAA1996-3119 [R]. Lake Buena Vista, US. AIAA, 1996. [19] CASIANO M J, HULKA J R, YANG V. Liquid-propellant rocket engine throttling: a comprehensive review[J]. Journal of Propulsion and Power, 2010, 26(5): 897-923. doi: 10.2514/1.49791 [20] SON M, RADHAKRISHNAN K, KOO J, et al. Design procedure of a movable pintle injector for liquid rocket engines[J]. Journal of Propulsion and Power, 2017, 33(4): 858-869. doi: 10.2514/1.B36301 [21] LEE Suji, KIM D, KOO J, et al. Spray characteristics of a pintle injector based on annular orifice area[J]. Acta Astronautica, 2020, 167: 201-211. doi: 10.1016/j.actaastro.2019.11.008 [22] 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. CHENG Peng. The dynamics of spray combustion in variable thrust rocket engines. [D]. Changsha: National University of Defense Technology, 2018. (in ChineseCHENG Peng. The dynamics of spray combustion in variable thrust rocket engines. [D]. Changsha: National University of Defense Technology, 2018. (in Chinese) [23] NATARAJAN V, UNNIKRISHNAN U, CHOI J Y, et al. Flow dynamics of a liquid-liquid bi-swirl injector[J]. Physics of Fluids, 2024, 36(3): 032122. doi: 10.1063/5.0191490 [24] XIE Yuan, NIE Wansheng, GAO Yuchao, et al. Numerical investigation on spray characteristics with upstream flow pulsation of a pintle injector[J]. Frontiers in Aerospace Engineering, 2022, 1: 876191. doi: 10.3389/fpace.2022.876191 [25] SHEN L, FANG G, WANG S, et al. Numerical study of the secondary atomization characteristics and droplet distribution of pressure swirl atomizers[J]. Fuel, 2022, 324: 124643. doi: 10.1016/j.fuel.2022.124643 [26] RIDER W J, KOTHE D B. Reconstructing volume tracking[J]. Journal of Computational Physics, 1998, 141(2): 112-152. doi: 10.1006/jcph.1998.5906 [27] ZHANG Meng, LV Xiang, DONG Fangmian, et al. High-fidelity atomization simulation of kerosene swirl injector using multi-resolution framework[J]. Physics of Fluids, 2025, 37(3): 033338. doi: 10.1063/5.0258236 [28] SHIH T H, LIOU W W, SHABBIR A, et al. A new k-ε eddy viscosity model for high Reynolds number turbulent flows[J]. Computers and Fluids, 1995, 24(3): 227-238. doi: 10.1016/0045-7930(94)00032-T [29] 谢远, 聂万胜, 高玉超, 等. 流量脉动对针栓式喷嘴雾化特性影响的仿真分析[J]. 火箭推进, 2023, 49(1): 54-64. XIE Yuan, NIE Wansheng, GAO Yuchao, et al. Simulation analysis on the influence of flow pulsation on the atomization characteristics of a pintle injector[J] Journal of Rocket Propulsion, 2023, 49(1): 54-64. (in ChineseXIE Yuan, NIE Wansheng, GAO Yuchao, et al. Simulation analysis on the influence of flow pulsation on the atomization characteristics of a pintle injector[J] Journal of Rocket Propulsion, 2023, 49(1): 54-64. (in Chinese) [30] ASHGRIZ N, POO J Y. Coalescence and separation in binary collisions of liquid drops[J]. Journal of Fluid Mechanics, 1990, 221: 183-204. doi: 10.1017/S0022112090003536 [31] LI Tianwen, YU Nanjia, ZHAO Zeng, et al. Experimental investigation on a throttleable pintle-centrifugal injector[J]. Applied Sciences, 2025, 15(5): 2696. doi: 10.3390/app15052696 -
点击查看大图
计量
- 文章访问数: 328
- HTML浏览量: 226
- PDF量: 56
- 被引次数: 0