Authors: Amaraja Taur, Pankaj Doshi, Hak Koon Yeoh

Abstract:

The dripping modes for a Newtonian liquid of viscosity µ emanating from an inclined nozzle at flow rate Q is investigated experimentally. As the liquid flow rate Q increases, starting with period-1 with satellite drops, the system transitions to period-1 dripping without satellite, then to limit cycle before showing chaotic responses. Phase diagrams showing the changes in the transitions between the different dripping modes for different nozzle inclination angle q is constructed in the dimensionless (Q, µ) space.

Keywords: Dripping, inclined nozzle, phase diagram.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1089367

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References:

[1] H. P. Le, "Progress and trends in ink-jet printing technology," Journal of Imaging Science and Technology 42, 49-62 (1998).
[2] T. Laurell, J. Nilsson and G. Marko-Varga, "Silicon microstructures for high-speed and high-sensitivity protein identifications," Journal of Chromatography B: Biomedical Sciences and Applications 752, 217-232 (2001).
[3] S. Freitas, H. P. Merkle and B. Gander, "Microencapsulation by solvent extraction/evaporation: reviewing the state of the art of microsphere preparation process technology," Journal of Controlled Release 102, 313-332 (2005).
[4] E. M. Sachs, J. S. Haggerty, M. J. Cima and P. A. Williams, ''Three dimentional printing techniques'', (US Patent 5,340,656, 1994).
[5] J. Eggers, "Nonlinear dynamics and breakup of free-surface flows," Reviews of modern physics 69, 865 (1997).
[6] J. Eggers, "Theory of drop formation," Physics of Fluids 7, 941-953 (1995).
[7] R. Schulkes, "The evolution and bifurcation of a pendant drop," Journal of Fluid Mechanics 278, 83-100 (1994).
[8] X. Zhang and O. A. Basaran, "An experimental study of dynamics of drop formation," Physics of fluids 7, 1184 (1995).
[9] X. Zhang, "Dynamics of growth and breakup of viscous pendant drops into air," Journal of colloid and interface science 212, 107-122 (1999).
[10] L. Rayleigh, "On the capillary phenomena of jets," Proceedings of the Royal Society of London 29, 71-97 (1879).
[11] L. Rayleigh and J. W. Strutt, "On the instability of jets," Proceedings of the Royal Mathematical Society London 4-13 (1879).
[12] A. M. Worthington, "On pendent drops," Proceedings of the Royal Society of London 32, 362-377 (1881).
[13] B. Ambravaneswaran, H. J. Subramani, S. D. Phillips and O. A. Basaran," Dripping-jetting transitions in a dripping faucet," Physical review letters 93, 034501 (2004).
[14] B. Ambravaneswaran, S. D. Phillips and O. A. Basaran, "Theoretical analysis of a dripping faucet," Physical review letters 85, 5332 (2000).
[15] H. J. Subramani, H. K. Yeoh, R. Suryo, Q. Xu, B. Ambravaneswaran and O. A. Basaran, "Simplicity and complexity in a dripping faucet," Physics of fluids 18, 032106 (2006).
[16] X. Shi, M. P. Brenner and S. R. Nagel, "A cascade of structure in a drop falling from a faucet," Science-New York then Washington 219-219 (1994).
[17] C. Clanet and J. C. Lasheras, "Transition from dripping to jetting," Journal of Fluid Mechanics 383, 307-326 (1999).
[18] M. Reyes, R. Pinto, A. Tufaile and J. Sartorelli, "Heteroclinic behavior in a dripping faucet experiment," Physics Letters A 300, 192-198 (2002).
[19] A. D’Innocenzo, F. Paladini and L. Renna, "Experimental study of dripping dynamics," Physical Review E 65, 056208 (2002).
[20] www.aciscience.org,''Physical properties of glycerine and its solutions'', (1967).
[21] E. D. Wilkes, S. D. Phillips and O. A. Basaran, "Computational and experimental analysis of dynamics of drop formation," Physics of fluids 11, 3577 (1999).