Analysis of Vortex Dynamics of  Gas-liquid Two-phase Crossflows around a Porous  Plate

doi:10.3969/j.issn.1000-1093.2017.07.016

Abstract

Abstract: In order to investigate the vortex structures of multiphase flows around a porous plate, the flow characteristics of gas-liquid two-phase crossflows were numerically simulated by using the RNG k-ε turbulence modeland the Level Set model. The simulated results are compared with the experimental results. The research results show that the separation point and the horseshoe vortex are formed since the crossflow is blocked by gas jet, which can be observed at the upstream of the jet hole. With the increases in the distance away from the wall, the separation point gradually gets close to the jet exit hole. The crossflow detours the jet and forms two counter-rotating vortices on the lateral edges of jet, and the vortex evolution depends upon the distance away from the wall. The counter-rotating vortex pairs (CVP) are formed in the jet region. The development process of the vortex pairs can be devided into 3 stages: in the near wake-region (i.e., close to the edge of the jet exit hole), the counter-rotating vortex pairs gradually form on the wall, and the increases in the heights of the vortex cores ae well as the distance between the cores lead to the expansion of vortex area. As the flow develops toward downstream, the area of CVP shrinks and even disappears entirely. Further downstream, the CVP appears again on the top of the jet corresponding to the formation of secondary vortex pairs in the near-wall region. Key

Key words: fluidmechanics, gas-liquidtwo-phaseflow, crossflowjet, numericalsimulation, vortexstructure

CLC Number:

TV131.3⁺2

LIU Tao-tao, WANG Guo-yu, ZHANG Nai-min, HUANG Biao. Analysis of Vortex Dynamics of Gas-liquid Two-phase Crossflows around a Porous Plate[J]. Acta Armamentarii, 2017, 38(7): 1375-1384.

References

［1］ Brennen C E. Fundamentals of multiphase flow[M]. Cambridge, UK:Cambridge University Press, 2005.
[2］ Cantro F, Crespo A, Manuel F, et al. Equlibrium of ventilated cavities in tip vortices[J]. Journal of Fluids Engineering, 1997, 119(4):759-767.
[3］ Semenenko V N. Artificial supercavitation physics and calculation, ADP012080[R]. Kiev, Ukraine: Institute of Hydeomechanics of Ukrainian Academy of Science, 2001.
[4］ Kunz R F, Boger D A, Chyczewski T S, et al. Multiphase CFD analysis of natural and ventilated cavitation about submerged bodies[C]∥3th ASME/JSME Joint Fluids Engineering Conference. San Francisco, CA, US: ASME, 1999.
[5］ Wosnik M, Schauer T J, Arndt R E A. Experimental study of ventilated supercavitating vehicle[C]∥5th International Symposium on Cavitation. Osaka, Japan: Osaka University, 2003.
[6］ Schauer T. An experimental study of a ventilated supercavity vehicle[D]. Minneapolis, MN, US: University of Minnesota, 2003.
[7］ Wosnik M, Schauer T, Arndt R E A. Measurements in high void-fraction bubbly wakes created by ventilated supercavitation［J］. Journal of Fluids Engineering, 2013,135(1):531-538.
[8］ Mkiharju S A. The dynamics of ventilated partial cavities over a wide range of Reynolds numbers and quantitative 2D X-ray densitometry for multiphase flow[D]. MI, US: University of Michigan, 2012.
[9］ Ji B, Luo X W, Zhang Y, et al. A three-component model suitable for natural and ventilated cavitation[J]. Chinese Physics Letter, 2010, 27(9): 38-43.

[10］ Ji B, Luo X W, Peng X X, et al. Numerical investigation of the ventilated cavitating flow around an underwater vehicle based on a three-component cavitation model[J]. Journal of Hydrodynamics, 2010, 22(6): 753-759.
[11］ Wang Y W, Huang C G, Wei Y P, et al. Ventilated partial cavitation shedding caused by the interaction of re-entry and air injection[C]∥Proceedings of the 8th International Symposium on Cavitation. Singapore: Nanyang Technological University, 2012.
[12］于娴娴, 王一伟, 黄晨光, 等. 轴对称航行体通气云状空化非定常特征研究[J]. 船舶力学, 2014, 18(5): 499-506.
YU Xian-xian, WANG Yi-wei, HUANG Chen-guang, et al. Unsteady characteristics of ventilated cloud cavity around symmetrical bodies[J]. Journal of Ship Mechanics, 2014, 18(5):499-506. (in Chinese)
[13］时素果, 王国玉, 余志毅, 等. FBM湍流模型在非定常通气超空化流动计算中的评价与应用[J]. 船舶力学, 2012, 16(10): 1100-1106.
SHI Su-guo, WANG Guo-yu, YU Zhi-yi, et al. Evaluation of the filter based turbulence model for computation of unsteady ventilated supercavitating flows[J]. Journal of Ship Mechanics, 2012, 16(10):1100-1106. (in Chinese)
[14］段磊, 王国玉, 付细能. 涡环泄气方式下通气空化的非定常流动特性研究[J]. 兵工学报, 2014, 35(5):712-718.
DUAN Lei, WANG Guo-yu, FU Xi-neng. Research of the unsteady characteristics of ventilated cavitating flows in the form of gas leakage by toroidal vortex[J]. Acta Armamentarii, 2014, 35(5): 712-718. (in Chinese)
[15］胡晓, 郜冶, 彭辉. 湍流模型对空泡形态影响的数值研究[J]. 计算力学学报, 2015，32(1): 129-135.
HU Xiao, GAO Ye, PENG Hui. Numerical investigation on influence of turbulence model on cavity shape[J]. Chinese Journal of Computational Mechanics, 2015,32(1): 129-135. (in Chinese)
[16］王复峰, 王国玉, 张敏弟, 等. 带空化器回转体空化流场研究[J]. 哈尔滨工程大学学报, 2015, 36(7):959-964.
WANG Fu-feng, WANG Guo-yu, ZHANG Min-di, et al. Study of cavitating flows around an axisymmetric body with cavitators[J]. Journal of Harbin Engineering University, 2015, 36(7):959-964. (in Chinese)
[17］刘涛涛, 王国玉, 段磊. 基于实验观测的分域湍流模型在通气超空化中的评价[J]. 北京理工大学学报, 2016, 36(3): 247-251.
LIU Tao-tao, WANG Guo-yu, DUAN Lei. Assessment of a modified turbulence model based experiment results for ventilated supercavity[J]. Transactions of Beijing Institute of Technology, 2016, 36(3): 247-251. (in Chinese)
[18］ Margason R J. Fifty years of jet in cross flow research[C]∥Proceedings of the AGARD Symposium on Computational & Experimental Assessment of Jets in Cross Flow. London, UK: Advisory Group for Aerospace Research and Development, 1993.
[19］ Fric T F. Structure in the near field of the transverse jet[D]. Pasadena, CA, US: California Institute of Technology, 1990.
[20］ Fric T F, Roshko A. Vortical structure in the wake of a transverse jet[J]. Journal of Fluid Mechanics, 1994, 279:1-47.
[21］ Andreopoulos J, Rodi W. Experimental investigation of jets in a cross flow[J]. Journal of Fluid Mechanics, 1984, 138:93-127.
[22］ Morton B R, Ibberson A. Jets deflected across flow[J]. Experimental Thermal and Fluid Science, 1996, 12(2):112-133.
[23］ Yuan L L, Street R L, Ferziger J H. Large eddy simulation of a round jet in cross-flow[J]. Journal of Fluid Mechanics, 1999, 379:71-104.
[24］ Hale C A, Plesniak M W, Ramadhyani S. Structural features and surface heat transfer associated with a row of short hole jets in cross flow[J]. International Journal of Heat and Fluid Flow, 2000, 21:542-553.
[25］ Yao Y, Maidi M. Direct numerical simulation of single and multiple square jets in cross flow[J]. Journal of Fluids Engineering, 2011, 133(3):1201.
[26］ Roger F, Gourara A, Most J M, et al. Numerical investigation on the reactive gas mixing through interaction between twin square jets side-by-side and a cross flow[J]. Journal of Chemical Engineering, 2004, 238:45-55.
[27］吴海玲, 陈听宽, 罗毓珊. 应用不同紊流模型的二维横向射流传热数值模拟研究[J]. 西安交通大学学报, 2001, 35(9): 903-907.
WU Hai-ling, CHEN Ting-kuan, LUO Yu-shan. Numerical simulation of 2D jet to cross flow heat transfer with different turbulence models[J]. Journal of Xi'an Jiaotong University, 2001, 35(9):903-907. (in Chinese)
[28］赵马杰, 曹长敏, 张宏达, 等. 高雷诺数湍流横侧射流的大涡模拟[J]. 推进技术, 2016, 37(5): 834-843.
ZHAO Ma-jie, CAO Chang-min, ZHANG Hong-da, et al. Large eddy simulation of a high Reynolds number turbulent jet in cross flow[J]. Journal of Propulsion Technology,2016, 37(5): 834-843. (in Chinese)
[29］ Launder B E, Spalding D B. The numerical computation of turbulent flows[J]. Computational Methods in Applied Mechanics and Engineering, 1974, 3(2): 269-289.
[30］ Yakhot V, Orszag S A. Renormalization group analysis of turbulence[J]. Journal of Scientific Computing, 1986, 1(1): 3-5.
[31］ Speziale C G, Thangam S. Analysis of RNG based turbulence model for separated flows[J]. Journal of Engineering Science, 1992, 30(10): 1379-1388.
[32］ Huang B, Wang G Y, Zhang M D, et al. Level set model for simulation of cavitation flows[J]. Journal of Ship Mechanics, 2011, 15(3):207-216.
[33］吴钦, 王国玉, 付细能, 等. 绕平板气液两相流数值计算方法[J]. 北京理工大学学报, 2014, 34(5):475-500.
WU Qin, WANG Guo-yu, FU Xi-neng, et al. Numerical study on multiphase flows around a plane[J]. Transactions of Beijing Institute of Technology, 2014, 34(5):475-500. (in Chinese)
[34］ Kelso R M, Lim T T, Perry A E. An experimental study of rounds jets in cross flow[J]. Journal of Fluid Mechanics, 1996, 306:111-144.
[35］ Andreopoulos J, Rodi W. Experimental investigation of jets in a cross flow[J]. Experimental Thermal and Fluid Science, 1996, 12(2):112-133.

第38卷
第7期2017 年7月兵工学报ACTA
ARMAMENTARIIVol.38No.7Jul.2017

[1]	YAN Zechen, YUE Songlin, QIU Yanyu, WANG Jianping, ZHAO Yuetang, SHI Jie, LI Xu. Improvement on the Calculation Method for Reflected Pressure of Shock Wave in Underwater Explosion [J]. Acta Armamentarii, 2024, 45(4): 1196-1207.
[2]	HE Jiawei, ZHAI Junyi, GAO Weipeng, LI Ye. Numerical Simulation of Flow Characteristics of the Underwater Vehicle with a Cylindrical Structure Based onDifferent Turbulence Models [J]. Acta Armamentarii, 2022, 43(S2): 53-63.
[3]	WANG Ge， ZHANG Chun， LIN Zhiwei， WANG Baohua， TAN Hu， CHEN Chen. Research on's Opening Distance of AHEAD Ammunition [J]. Acta Armamentarii, 2022, 43(S1): 115-120.
[4]	XU Hui, HUANG Chenlei, WANG Xikuo, LIU Kun, LI Zhongxin, WU Zhilin. Theoretical and Experimental Study of Projectile Dynamic Engraving Resistance [J]. Acta Armamentarii, 2022, 43(9): 2263-2273.
[5]	WANG Xiaodong, XU Yongjie, DONG Fangdong, WANG Hao, ZHENG Nana. Numerical Simulation of Penetration Resistance of Kevlar and Ceramic Composite Structures [J]. Acta Armamentarii, 2022, 43(9): 2360-2366.
[6]	GUAN Dian， GUO Yawen， LI Shipeng， TANG Jianing， WANG Ningfei. Influence of Gas-particle Two-phase Flow on Ignition of the Solid Rocket Motor under Lateral Acceleration [J]. Acta Armamentarii, 2022, 43(8): 1792-1807.
[7]	JIA Qiming， JIANG Yi， YANG Ying， ZHAO Zixi， WANG Zhihao. A New Type of Controllable Thrust Vertical Launcher and its Interior Ballistic Law [J]. Acta Armamentarii, 2022, 43(7): 1596-1605.
[8]	GAO Yueguang, FENG Shunshan, LIU Yunhui, HUANG Qi. Initial Velocity Distribution of Fragments from Cylindrical Charge Shells with Different Thick End Caps [J]. Acta Armamentarii, 2022, 43(7): 1527-1536.
[9]	L Dailong， CHEN Shaosong， XU Yihang， QIU Jiawei. Aerodynamic Characteristics of Close-coupled Canard Missile [J]. Acta Armamentarii, 2022, 43(6): 1316-1325.
[10]	WANG Danyu, NAN Fengqiang, LIAO Xin, XIAO Zhongliang, DU Ping, WANG Binbin. Effect of Flame Inhibitor of the Muzzle Flame of Large Caliber Gun [J]. Acta Armamentarii, 2022, 43(2): 273-278.
[11]	XU Gancheng, YUAN Weize, CHEN Linheng, LI Chengxue, XIE Xuhu, NIE Mengqi. Seismic Collapse Resitance of NFB700 High-strength Steel Plate [J]. Acta Armamentarii, 2022, 43(2): 391-400.
[12]	LU Kuan， RAO Xiang， WANG Huamei， ZHANG Qian. The Influences of Different Mooring Systems on the Hydrodynamic Performance of Buoy [J]. Acta Armamentarii, 2022, 43(1): 120-130.
[13]	CHENG Shenshen, TAO Ruyi, WANG Hao, XUE Shao, LIN Qingyu. Dampling Characteristics of Projectile in Engraving Process of Nylon Sealing Band [J]. Acta Armamentarii, 2021, 42(9): 1847-1857.
[14]	GUAN Dian, LI Shipeng, LIU Zhu, WANG Ningfei. Influence of Lateral Acceleration on Ignition Transients of Solid Rocket Motor [J]. Acta Armamentarii, 2021, 42(9): 1877-1887.
[15]	WANG Danyu, NAN Fengqiang, LIAO Xin, XIAO Zhongliang, DU Ping, WANG Binbin. Characteristics of Muzzle Flow Field of Large Caliber Gun Considering Chemical Reaction [J]. Acta Armamentarii, 2021, 42(8): 1624-1630.

Analysis of Vortex Dynamics of Gas-liquid Two-phase Crossflows around a Porous Plate

PDF (PC)

Knowledge

Cited

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments