References

1. W. Nusselt, Die Oberfl¨achenkondensation des Wasserdampfes, Zeitschr. Ver. Deut. Ing., 60 (1916) 541–546.
2. J.T. Rogers, S.S. Goindi, Experimental laminar falling film heat transfer coefficient on a large diameter horizontal tube, Can. J. Chem. Eng., 67 (1989) 560–568.
3. X. Hu, A.M. Jacobi, The inter tube falling film: Part 1-flow characteristics, mode transitions, and hysteresis, T. ASME, 118 (1996) 616–625.
4. V. Slesarenko, Hydrodynamics and heat exchange during film evaporation of sea water in a vapor water up flow, Desalination, 33 (1980) 25l–257.
5. G. Ribatski, A.M. Jacobi, Falling-film evaporation on horizontal tubes—a critical review, Int. J. Refrig., 28 (2005) 635–653.
6. L. Xu, W. Shichang, Flowing state of liquid films over horizontal tubes and its influences on heat-transfer characteristics, J. Chem. Ind. Eng., 53 (2002) 555–559.
7. L. Xu, Heat-transfer film coefficients of falling film horizontal tube evaporators, Desalination, 166 (2004) 223–230.
8. L. Harikrishnan, M.P. Maiya, Investigations on heat and mass transfer characteristics of falling film horizontal tubular absorber, Int. J. Heat Mass Tran., 54 (2011) 2609–2617.
9. L. Harikrishnan, S. Tiwari, Numerical study of heat and mass transfer characteristics on a falling film horizontal tubular absorber for R-134a-DMAC, Int. J. Therm. Sci., 50 (2011) 149– 159.
10. H. Hou, Q.C. Bi, Distribution characteristics of falling film thickness around a horizontal tube, Desalination, 285 (2012) 393–398.
11. X.S. Mu, S.S. Shen, Experimental study of falling film evaporation heat transfer coefficient on horizontal tube, Desal. Water Treat., 50 (2012) 310–316.
12. X. Chen, S.Q. Shen, Measurement on falling film thickness distribution around horizontal tube with laser-induced fluorescence technology, Int. J. Heat Mass Tran., 89 (2015) 707–713.
13. Q.G. Qiu, X.J. Zhu, L. Mu, S.S. Shen, Numerical study of falling film thickness over fully wetted horizontal round tube, Int. J. Heat Mass Tran., 84 (2015) 893–897.
14. V. Subramaniam, Numerical study of heat and mass transfer in lithium bromide-water falling films and droplets, Int. J. Refrig., 40 (2014) 211–226.
15. E.W. Zavaleta-Aguilar, Horizontal tube bundle falling film distiller for ammonia–water mixtures, Int. J. Refrig., 59 (2015) 304–316.
16. J.G. Bustamante, S. Garimella, Dominant flow mechanisms in falling-film and droplet-mode evaporation over horizontal rectangular tube banks, Int. J. Refrig., 43 (2014) 80–89.
17. C.H. Qi, H.J. Feng, H.Q. Lv, C. Miao, Numerical and experimental research on the heat transfer of seawater desalination with liquid film outside elliptical tube, Int. J. Heat Mass Tran., 93 (2016) 207–216.
18. E.A. Saleh, S.J. Ormiston, An elliptic two-phase numerical model of laminar film condensation from a steam-air mixture flowing over a horizontal tube, Int. J. Heat Mass Tran., 112 (2017) 676–688.
19. C.Y. Zhao, W.T. Ji, Y.L. He, Y.J. Zhong, W.Q. Tao, A comprehensive numerical study on the sub-cooled falling film heat transfer on a horizontal smooth tube, Int. J. Heat Mass Tran., 119 (2018) 259–270.
20. D. Gstoehl, J.F. Roques, P. Crisinel, J.R. Thome, Measurement of falling film thickness around a horizontal tube using a laser measurement technique, Heat Transfer. Eng., 25 (2004) 28–34.
21. M. Xuehu, G. Dazhi, A. Jiaming, Experimental study on the heat transfer characteristics of the surface of the functional surface, J. Therm. Sci. Tech-Jpn., 2 (2003) 119–123.