Inertia dominated flow and heat transfer in liquid drop spreading on a hot substrate

International Journal of Heat and Fluid Flow

Volumn 32, Issue 4, 2011, Pages 785-795

  Berberović, Edin ^a,b   Roisman, Ilia V ^a   Jakirlić, Suad ^a   Tropea, Cameron ^a  

^a DARMSTADT UNIVERSITY OF TECHNOLOGY   (Germany)

^b UNIVERSITY OF ZENICA   (Bosnia and Herzegovina)

Author keywords

Conjugate heat transfer; Drop impact; Volume of fluid method

Indexed keywords

AIR BUBBLES; AIR FLOW; ANALYTICAL SOLUTIONS; CHANDRA; COMPUTATIONAL MODEL; COMPUTATIONAL MODELING; CONJUGATE HEAT TRANSFER; COOLING EFFECTIVENESS; DROP IMPACT; DROP SPREADING; DROPLET IMPACT; FLOW AND HEAT TRANSFER; FREE SURFACES; HARTLEY; HEAT AND MASS TRANSFER; HEATED SUBSTRATES; HOT SURFACE; IMPACT POINT; INTERNATIONAL JOURNALS; LIQUID DROP; LIQUID-SOLID SYSTEM; MODEL PERFORMANCE; NUMERICAL INVESTIGATIONS; NUMERICAL STUDIES; PHASE CHANGE; REFERENCE DATABASE; SUBSTRATE TEMPERATURE; TEMPERATURE RANGE; THERMAL FIELD; VOLUME OF FLUID METHOD; WATER DROP; WEBER NUMBERS;

COMPUTATIONAL METHODS; CONTACTS (FLUID MECHANICS); DROPS; FLOW OF FLUIDS; HEAT FLUX; HEAT TRANSFER; LIQUID FILMS; MASS TRANSFER; PHASE TRANSITIONS; REYNOLDS NUMBER; SUBSTRATES; THERMODYNAMIC PROPERTIES;

FLUIDS;

EID: 79959567023     PISSN: 0142727X     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.ijheatfluidflow.2011.05.001     Document Type: Article

References (35)

1. Basinger B., Aguilar G., Nelson J.S. Effect of skin indentation on heat transfer during cryogen spray cooling. Lasers in Surgery and Medicine 2004, 34:155-163.
2. Hirt C.W., Nichols B.D. Volume of fluid (VOF) method for the dynamics of free boundaries. Journal of Computational Physics 1981, 39(1):201-225.
3. DiMarzo M., Tartarini P., Liao Y., Evans D., Baum H. Evaporative cooling due to a gently deposited droplet. International Journal of Heat and Mass Transfer 1993, 36:4133-4139.
4. Pasandideh-Fard M., Aziz S., Chandra S., Mostaghimi J. Cooling effectivness of a water drop impinging on a hot surface. International Journal of Heat and Fluid Flow 2001, 22:201-210.
5. Healy W., Hartley J., Abdel-Khalik S. On the validity of the adiabatic spreading assumption in droplet impact cooling. International Journal of Heat and Mass Transfer 2001, 44:3869-3881.
6. Mehdi-Nejad V., Mostaghimi J., Chandra S. Modelling heat transfer in two-fluid interfacial flows. International Journal for Numerical Methods in Engineering 2004, 61:1028-1048.
7. Mehdi-Nejad V., Mostaghimi J., Chandra S. Modeling interfacial heat transfer from single or multiple deforming droplets. International Journal of Computational Fluid Dynamics 2005, 19(2):105-113.
8. Bhardwej R., Attinger D. Non-isothermal wetting during impact of milimeter-size water drop on a flat substrate: numerical investigation and comparison with high-speed visualization experiments. International Journal of Heat and Fluid Flow 2008, 29:1422-1435.
9. Selvam R.P., Lin L., Ponnappan R. Direct simulation of spray cooling: effect of vapor bubble growth and liquid droplet impact on heat transfer. International Journal of Heat and Mass Transfer 2006, 49:4265-4278.
10. Lee J., Kim J., Kiger K.T. Time- and space-resolved heat transfer characteristics of single droplet cooling using, icroscale heater arrays. International Journal of Heat and Fluid Flow 2001, 22:188-200.
11. Hase M., Weigland B. Transient heat transfer of deforming droplets at high reynolds numbers. International Journal of Numerical Methods for Heat and Fluid Flow 2004, 14(1):85-97.
12. Vu, H., Aguilar, G., Jepsen, R., 2009. Single droplet heat transfer through shallow liquid pools. In: ICLASS 2009, 11th Triennial International Conference on Liquid Atomization and Spray Systems, Vail, Colorado USA, 2009.
13. Roisman I. Fast forced liquid film spreading on a substrate: flow, heat transfer and phase transition. Journal of Fluid Mechanics 2010, 656:189-204.
14. Berberović E., van Hinsberg N.P., Jakirlić S., Roisman I.V., Tropea C. Drop impact onto a liquid layer of finite thickness: Dynamics of the cavity evolution. Physical Review E 2009, 79(3):036306.
15. Brackbill J.U., Kothe D.B., Zemach C. A continuum method for modeling surface tension. Journal of Computational Physics 1992, 100(2):335-354.
16. Batchelor F. An Introduction to Fluid Mechanics 1970, Cambridge University Press, Cambridge.
17. Incropera F.P., DeWitt D.P. Fundamentals of Heat and Mass Transfer 2002, John Wiley and Sons. 5th ed.
18. OpenCFD Ltd., 2008. OpenFOAM, The Open Source CFD Toolbox, User Guide. http://www.opencfd.co.uk/openfoam/.
19. Weller H.G., Tabor G., Jasak H., Fureby C. A tensorial approach to computational continuum mechanics using object-oriented techniques. Computers in Physics 1998, 12(6):620-631.
20. Weller, H.G., 2008. A New Approach to VOF-based Interface Capturing Methods for Incompressible and Compressible Flow. Technical Report TR/HGW/04, OpenCFD Ltd.
21. Patankar S.V. Numerical Heat Transfer and Fluid Flow 1980, Hemisphere Publishing Corporation, Washington, DC.
22. Leer B.V. Towards the ultimate conservative difference scheme. II. Monotonicity and conservation combined in a second order scheme. Journal of Computational Physics 1974, 14:361-370.
23. Issa R.I. Solution of the implicitly discretised fluid flow equations by operator-splitting. Journal of Computational Physics 1986, 62(1):40-65.
24. Pasandideh-Fard M., Qiao Y.M., Chandra S., Mostaghimi J. Capillary effects during droplet impact on a solid surface. Physics of Fluids 1996, 8:650.
25. Strotos G., Gavaises M., Theodorakakos A., Bergeles G. Numerical investigation of the cooling effectiveness of a droplet impinging on a heated surface. International Journal of Heat and Mass Transfer 2008, 51:4728-4742.
26. Chandra S., Avedisian C.T. On the collision of a droplet with a solid surface. Proceedings of the Royal Society London A 1991, 423:13-41.
27. Qiao Y.M., Chandra S. Experiments on adding a surfactant to water drop boiling on a hot surface. Proceedings of the Royal Society London A 1997, 453:673-689.
28. Bartolo D., Josserand C., Bonn D. Singular jets and bubbles in drop impact. Physical Review Letters 2006, 96:124501.
29. Prosperetti A., Oguz H.N. Air entrainment upon liquid impact. Philosophical Transactions of the Royal Society London A 1997, 355:491-506.
30. Elmore P.A., Chahine G.L., Oguz H.N. Cavity and flow measurements of reproducible bubble entrainment following drop impacts. Experiments in Fluids 2001, 31:664-673.
31. Oguz H.N., Prosperetti A. Bubble entrainment by the impact of drops on liquid surfaces. Journal of Fluid Mechanics 1990, 219:143-179.
32. Mehdi-Nejad V., Mostaghimi J., Chandra S. Air bubble entrapment under an impacting droplet. Physics of Fluids 2003, 15:173-183.
33. Nikolopoulos N., Nikas K.S.S., Bergeles G. A numerical investigation of central binary collision of droplets. Computers and Fluids 2009, 38:1191-1202.
34. Roisman I.V., Berberović E., Tropea C. Inertia dominated drop collisions. I. On the universal flow in the lamella. Physics of Fluids 2009, 21:052103.
35. Roisman I.V. Inertia dominated drop collisions. II. Viscous boundary layer. Physics of Fluids 2009, 21:052104.