Aerodynamic breakup of emulsion droplets in airflow

Zhikun Xu; Jinzhao Liu; Houpeng Zhang; Tianyou Wang; Zhizhao Che

doi:10.1002/dro2.146

Droplet ›› 2024, Vol. 3 ›› Issue (4) : e146 DOI: 10.1002/dro2.146

RESEARCH ARTICLE

Aerodynamic breakup of emulsion droplets in airflow

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Abstract

Aerodynamic breakup refers to the process where large droplets are fragmented into small droplets by the aerodynamic force in airflow, which plays a vital role in fluid atomization and spray applications. Previous research has primarily concentrated on the aerodynamic breakup of single-component droplets, but investigations into the breakup of emulsion droplets are limited. This study experimentally investigated the aerodynamic breakup of water-in-oil emulsions in airflow, utilizing high-speed photography to observe the breakup process and digital in-line holography to measure fragment sizes. Comparative analyses between emulsion droplets and single-component droplets are conducted to examine the breakup morphology, breakup regime, deformation characteristics, and fragment size distributions. The emulsion droplets exhibit higher apparent viscosity and shorter stretching lengths of the bag film and peripheral rim due to the presence of a dispersed phase. The breakup regime transitions of emulsions are modeled by integrating the viscosity model of emulsions and the transition model of the pure fluid. The fragment sizes of emulsion droplets are larger due to the shorter lengths of the bag film and peripheral rim.

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Zhikun Xu, Jinzhao Liu, Houpeng Zhang, Tianyou Wang, Zhizhao Che. Aerodynamic breakup of emulsion droplets in airflow. Droplet, 2024, 3(4): e146 DOI:10.1002/dro2.146

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References

Publishing order | Descend order by publishing year | Descend order by cited within

[1]	Debnath BK, Saha UK, Sahoo N. A comprehensive review on the application of emulsions as an alternative fuel for diesel engines. Renew Sust Energ Rev. 2015;42:196-211.

[2]	Mukhtar MNA, Hagos FY, Noor MM, Mamat R, Abdullah AA, Abd Aziz AR. Tri-fuel emulsion with secondary atomization attributes for greener diesel engine—a critical review. Renew Sust Energ Rev. 2019;111:490-506.

[3]	Melo-Espinosa EA, Piloto-Rodríguez R, Goyos-Pérez L, Sierens R, Verhelst S. Emulsification of animal fats and vegetable oils for their use as a diesel engine fuel: an overview. Renew Sust Energ Rev. 2015;47:623-633.

[4]	Hamid MF, Teoh YH, Idroas MY, et al. A review of the emulsification method for alternative fuels used in diesel engines. Energies. 2022;15:9429.

[5]	Lefebvre AH, McDonell VG. Atomization and Sprays. CRC Press;2017.

[6]	Wang Z, Yuan B, Huang Y, Cao J, Wang Y, Cheng X. Progress in experimental investigations on evaporation characteristics of a fuel droplet. Fuel Process Technol. 2022;231:107243.

[7]	Shen S, Sun K, Che Z, Wang T, Jia M, Cai J. An experimental investigation of the heating behaviors of droplets of emulsified fuels at high temperature. Appl Therm Eng. 2019;161:114059.

[8]	Zhang H, Lu Z, Wang T, Che Z. Micro-explosion of emulsion droplets with nanoparticles at high temperature. Int J Heat Mass Transf. 2024;219:124851.

[9]	Antonov DV, Strizhak PA. Heating, evaporation, fragmentation, and breakup of multi-component liquid droplets when heated in air flow. Chem Eng Res Des. 2019;146:22-35.

[10]	Sharma S, Chandra NK, Basu S, Kumar A. Advances in droplet aerobreakup. Eur Phys J Spec Top. 2022;232:719-733.

[11]	Guildenbecher DR, López-Rivera C, Sojka PE. Secondary atomization. Exp Fluids. 2009;46:371-402.

[12]	Xu Z, Wang T, Che Z. Transitions of breakup regimes for viscous droplets in airflow. Fuel. 2023;339:127355.

[13]	Zhao H, Liu H-F, Xu J-L, Li W-F. Secondary breakup of coal water slurry drops. Phys Fluids. 2011;23:113101.

[14]	Tavangar S, Hashemabadi SH, Saberimoghadam A. CFD simulation for secondary breakup of coal-water slurry drops using OpenFOAM. Fuel Process Technol. 2015;132:153-163.

[15]	Wang Z-Y, Zhao H, Li W-F, Xu J-L, Liu H-F. Secondary breakup of shear thickening suspension drop. Phys Fluids. 2021;33:093103.

[16]	Xu Z, Wang T, Che Z. Breakup of particle-laden droplets in airflow. J Fluid Mech. 2023;974: A42.

[17]	Lv C, Ji Z, Yang T, Zhao H, Zhang H. Numerical simulation of deformation and breakage of compound droplet in air flow. Phys Fluids. 2024;36:023306.

[18]	Liang Y, Jiang Y, Wen C-Y, Liu Y. Interaction of a planar shock wave and a water droplet embedded with a vapour cavity. J Fluid Mech. 2020;885: R6.

[19]	Xu Z, Zhang Y, Wang T, Che Z. Deformation and breakup of compound droplets in airflow. J Colloid Interf Sci. 2024;653:517-527.

[20]	Fostiropoulos S, Strotos G, Nikolopoulos N, Gavaises M. Numerical investigation of heavy fuel oil droplet breakup enhancement with water emulsions. Fuel. 2020;278:118381.

[21]	Jackiw IM, Ashgriz N. Prediction of the droplet size distribution in aerodynamic droplet breakup. J Fluid Mech. 2022;940: A17.

[22]	Tropea C. Optical particle characterization in flows. Annu Rev Fluid Mech. 2011;43:399-426.

[23]	Guildenbecher DR. Recent developments in experimental methods for quantification of high-speed, aerodynamically driven liquid breakup. ILASS Americans 28th Annual Conference on Liquid Atomization and Spray Systems, Springfield, VA, Dearborn, MI, USA, 2016.

[24]	Erinin MA, Néel B, Mazzatenta MT, Duncan JH, Deike L. Comparison between shadow imaging and in-line holography for measuring droplet size distributions. Exp Fluids. 2023;64:96.

[25]	Guildenbecher DR, Gao J, Chen J, Sojka PE. Characterization of drop aerodynamic fragmentation in the bag and sheet-thinning regimes by crossed-beam, two-view, digital in-line holography. Int J Multiphas Flow. 2017;94:107-122.

[26]	Ade SS, Chandrala LD, Sahu KC. Size distribution of a drop undergoing breakup at moderate Weber numbers. J Fluid Mech. 2023;959: A38.

[27]	Li J, Shen S, Liu J, Zhao Y, Li S, Tang C. Secondary droplet size distribution upon breakup of a sub-milimeter droplet in high speed cross flow. Int J Multiphas Flow. 2022;148:103943.

[28]	Ade SS, Kirar PK, Chandrala LD, Sahu KC. Droplet size distribution in a swirl airstream using in-line holography technique. J Fluid Mech. 2023;954: A39.

[29]	Radhakrishna V, Shang W, Yao L, Chen J, Sojka PE. Experimental characterization of secondary atomization at high Ohnesorge numbers. Int J Multiphas Flow. 2021;138:103591.

[30]	Gao J, Guildenbecher DR, Reu PL, Kulkarni V, Sojka PE, Chen J. Quantitative, three-dimensional diagnostics of multiphase drop fragmentation via digital in-line holography. Opt Lett. 2013;38:1893-1895.

[31]	Prak DJL, Trulove PC, Cowart JS. Density, viscosity, speed of sound, surface tension, and flash point of binary mixtures of n-hexadecane and 2, 2, 4, 4, 6, 8, 8-heptamethylnonane and of algal-based hydrotreated renewable diesel. J Chem Eng Data. 2013;58:920-926.

[32]	Duana Y, Deshiikanb SR, Papadopoulos KD. Effect of Span-80 in n-hexadecane on surface tensions at high temperatures. NIP &Digital Fabrication Conference, Springfield, VA, USA, 2013:398-404.

[33]	Jang GM, Kim NI. Surface tension, light absorbance, and effective viscosity of single droplets of water-emulsified n-decane, n-dodecane, and n-hexadecane. Fuel. 2019;240:1-9.

[34]	Zhao H, Liu H-F, Cao X, Li W-F, Xu J. Breakup characteristics of liquid drops in bag regime by a continuous and uniform air jet flow. Int J Multiphas Flow. 2011;37:530-534.

[35]	Ushikubo FY, Cunha RL. Stability mechanisms of liquid water-in-oil emulsions. Food Hydrocolloids. 2014;34:145-153.

[36]	Jang GM, Kim NI. Relationships between dynamic behavior and properties of a single droplet of water-emulsified n-dodecane. Fuel. 2018;220:130-139.