Liquid Jet Breakup and Penetration in a Gas Cross-Flow -An Experimental Study
Springer Science and Business Media LLC - Trang 1-11 - 2023
Tóm tắt
In the present study, an experimental platform is developed to study the behavior of the injected jet in a gas cross-flow applicable to different categories of fluid mechanics such as combustion. In all tests, water and air are used as jet and cross-flow gas, respectively. The main target of this work is to cover the higher range of momentum ratios and Weber numbers for the presentation of a more accurate equation for jet trajectory. To achieve a desirable scale of experiments, the range of momentum ratio is considered from 5 to 211 and the Weber number of gasses in all tests is between 1.1–19.1. For data mining and measurements, the shadowgraph method is used. It is shown that by increasing the momentum ratio (about 84%), the breakup point height is increased (about 94%). Three different types of breakups were observed in the tests. It observed that as the Weber number increases, the type of jet column mechanism changes. It also revealed that the type of breakup mechanism would not have a significant effect on the jet trajectory. In addition, it demonstrated that the momentum ratio parameter would have a decisive role in the direction of jet motion, and as the momentum ratio increases, the jet column height increases. Finally, an equation for the trajectory of jet flight under all test conditions is presented.
Tài liệu tham khảo
Deemyad T, Hassanzadeh N, Perez-Gracia A (2018) Coupling mechanisms for multi-fingered robotichands with skew axes. InIFToMM Symposium on Mech-anism Design for Robotics, pages 344–352. Springer
Deemyad T, Heidari O, Perez-Gracia A (2020) Singularity design for rrss mechanisms. InUSCToMMSymposium on Mechanical Systems and Robotics, pages 287–297. Springer
Moeller R, Deemyad T, Sebastian A (2020) Autonomous Navigation of an Agricultural Robot Using RTK GPS and Pixhawk. In Intermountain Engineering, Technology, and Computing Conference (i-ETC). IEEE
Xiao F, Dianat M, McGuirk JJ (2014) Large eddy simulation of single droplet and liquid jet primary breakup using a coupled level set/volume of fluid method. Atomiz Spr 24:281–302
Zhou Y-z, Xiao F, Li Q-l, Li C-y (2020) Simulation of elliptical liquid jet primary breakup in supersonic crossflow. Int Aerosp Eng 2020:1–12. https://doi.org/10.1155/2020/6783038
Huang L, El-Genk MS (1994) Heat transfer of an impinging jet on a flat surface. Int J Heat Mass Transf 37–13:1915–1923
Karagozian AR (2014) The jet in crossflow. Phys Fluids 26:101303
Cavar D, Erik Meyer K (2012) LES of the turbulent jet in cross-flow: Part 1 – A numerical validation study. Int J Heat Fluid Flow 36:18–34
Li X, Soteriou MC (2016) High fidelity simulation of liquid jet in crossflow under dynamic excitation. 54th AIAA Aerospace Sciences Meeting
Getsinger DR, Gevorkyan L, Smith OI, Karagozian AR (2014) Structural and stability characteristics of jets in crossflow. J Fluid Mech 760:342–367
Zargarabadi MR, Rezaei E, Yousefi-Lafouraki B (2018) Numerical analysis of turbulent flow and heat transfer of sinusoidal pulsed jet impinging on an asymmetrical concave surface. Appl Therm Eng 128:578–585
Yousefi-Lafouraki B, Ramiar A, Ranjbar AA (2018) Modeling of two-phase particulate flow in a confined jet with a focus on two-way coupling. Particuology 39:78–87
Becker J, Hassa C (2002) Breakup and atomization of a Kerosene Jet in crossflow at elevated pressure. Atomization Sprays 12(1–3):49
Lubarsky E, Reichel JR, Zinn BR, McAmis R (2010) Spray in crossflow: dependence on weber number. J Eng Gas Turbines Power 132(2):501
Zhou Y, Cai Z, Li Q, Li C, Sun M, Li P, Wang H (2023) Review of the atomization mechanism and spray characteristics of liquid jet in supersonic crossflow. Chin J Aeronaut. https://doi.org/10.1016/j.cja.2023.03.010
Broumand M, Birouk M (2016) Liquid jet in a subsonic gaseous crossflow: Recent progress and remaining challenges. Progress Energy Combust Sci 57:1–29
Gopalan S, Abraham BM, Katz JH (2004) The structure of a jet in cross flow at low velocity ratios. Phys Fluids 16:2067
Wang Q, Mondragon UM, Brown CT, McDonell VG (2011) Characterization of trajectory, break point, and break point dynamics of a plain liquid jet in a crossflow. Atomization Sprays 21(3):203
Reinecke WG (1978) Drop breakup and liquid jet penetration. AIAA J 16(6):618
Li C, Zhou Y, Chen H, Li Q (2021) Cross-sectional droplets distribution of a liquid jet in supersonic crossflow. Acta Astronautica 186:109–117
Wang Y-Q, Xiao F, Lin S, Zhou Y-Z (2021) Numerical investigation of droplet properties of a liquid jet in supersonic crossflow. Int Aerospace Eng 2021:1–17. https://doi.org/10.1155/2021/8828015
Zheng Y, Marshall AW (2011) Characterization of the initial spray from low-weber-number jets in crossflow. Atomization and Sprays 21(7):575–589. https://doi.org/10.1615/AtomizSpr.2011003714
Yao-Zhi Z, Chun Li, Chen-Yang Li, Qing-Lian Li (2020) Prediction of liquid jet trajectory in supersonic crossflow and continuous liquid column model. Acta Phys Sin 69(23):234702
Elshamy O, Tamb S, Cai J, eng S-M (2006 Structure of liquid jets in subsonic crossflow at elevated ambient pressures. In: 44th AIAA Aerospace Sciences Meeting and Exhibit 09 January 2006 - 12 January 2006. Reno, Nevada. https://doi.org/10.2514/6.2006-1224
Tambe S, Jeng S, Mongia H, Hsiao G (2005) Liquid jets in subsonic cross flow. In: 43rd AIAA aerospace sciences meeting and exhibit – meeting papers, Reno (NV)
Brown C, McDonell V (2006) Near field behavior of a liquid jet in a cross flow. In: ILASS-Americas, Toronto, Ontario, Canada
Surya Prakash R, Sinha A, Tomar G, Ravikrishna RV (2018) Liquid jet in cross flow – Effect of liquid entry conditions. Exp Thermal Fluid Sci 93:45
Jadidi M, Dolatabadi A (2018) On the trajectory of non-turbulent liquid jets in subsonic cross flows at different density ratios. Theor Appl Mech Lett 8(4):277–283
Li X, Soteriou MC (2018) Detailed numerical simulation of liquid jet atomization in cross flow of increasing density. Int J Multiph Flow 104(1):214
Li C, Li C, Xiao F, Li Q, Zhua Y (2019) Experimental study of spray characteristics of liquid jets in supersonic cross flow. Aerosp Sci Technol 95:105456
Hu R, Li Q, Li C, Li C (2019) Effects of an accompanied gas jet on transverse liquid injection in a supersonic cross flow. Acta Astronaut 159:440
Broumand M, Ahmed MA, Birouk M (2019) Experimental investigation of spray characteristics of a liquid jet in a turbulent subsonic gaseous cross flow. Proc Combust Inst 37(3):3237
Broumand M, Rigby G, Birouk M (2017) Effect of nozzle exit turbulence on the column trajectory and breakup location of a transverse liquid jet in a gaseous flow. Flow Turbul Combust 99:153–171
Salewski M (2006) Les of jets and sprays injected into crossflow. Ph.D. thesis, Lund Institute of Technology
Wang J, Xu S, Cheng H, Ji B, Zhang J, Long X (2018) Experimental investigation of cavity length pulsation characteristics of jet pumps during limited operation stage. Energy 163(C):61–73 (Elsevier)
Wang J, Wang L, Xu S, Ji B, Long X (2019) Experimental investigation on the cavitation performance in a venturi reactor with special emphasis on the choking flow. Exp Thermal Fluid Sci 106:215–225
Tambe S (2004) Liquid Jets in Subsonic Crossflow. Master’s thesis, University of Cincinnati. https://doi.org/10.13140/2.1.2860.5763
Sallam KA, Aalburg C, Faeth GM (2004) Breakup of round nonturbulent liquid jets in gaseous crossflow. AIAA J 42(12):2529–2540
Zhang L, Yang V, Sung HG (2010) Large Eddy Simulation of a Turbulent Gaseous Jet in Oscillating Crossflow. 48th AIAA Aerospace Sciences Meeting Including the New Horizons Forum and Aerospace Exposition. https://doi.org/10.2514/6.2010-1142
Stenzler JN, Lee JG, Santavicca DA, Lee W (2006) Penetration of liquid jets in cross-flow. Atomization Sprays 16(8):887
Iyogun CO, Birouk M, Popplewell N (2006) Trajectory of water jet exposed to low subsonic cross-flow. Atomization Sprays 16(8):963
Mashayek A (2006) Experimental and numerical study of liquid jets in crossflow. Master’s thesis, University of Toronto