Computational Fluid Dynamic Simulation of Single Bubble Growth under High-Pressure Pool Boiling Conditions |
Murallidharan, Janani
(Department of Mechanical Engineering, Imperial College London)
Giustini, Giovanni (Department of Mechanical Engineering, Imperial College London) Sato, Yohei (Nuclear Energy and Safety Research Department, Paul Scherrer Institute) Niceno, Bojan (Nuclear Energy and Safety Research Department, Paul Scherrer Institute) Badalassi, Vittorio (Department of Mechanical Engineering, Imperial College London) Walker, Simon P. (Department of Mechanical Engineering, Imperial College London) |
1 | Y. Sato, B. Niceno, A sharp-interface phase change model for a mass-conservative interface tracking method, J. Comput. Phys 249 (2013) 127-161. DOI |
2 | Y. Sato, B. Niceno, A depletable micro-layer for nucleate pool boiling, J. Comput. Phys 300 (2015) 20-52. DOI |
3 | T. Nakamura, R. Tanaka, T. Yabe, K. Takizawa, Exactly conservative semi-Lagrangian scheme for multidimensional hyperbolic equations with directional splitting technique, J. Comput. Phys 174 (2001) 171-207. DOI |
4 | J.U. Brackbill, D.B. Kothe, C. Zemach, A continuum method for modeling surface tension, J. Comput. Phys 100 (1992) 335-354. DOI |
5 | K. Yokoi, A practical numerical framework for free surface flows based on CLSVOF method, multi-moment methods and density-scaled CSF model: numerical simulations of droplet splashing, J. Comput. Phys 232 (2013) 252-271. DOI |
6 | B. Niceno, F. Reiterer, A. Ylonen, H.M. Prasser, Simulation of single-phase mixing in fuel rod bundles, using an immersed boundary method, Phys. Scr 88 (2013) 1-13. |
7 | Y. Utaka, Y. Kashiwabara, M. Ozaki, Microlayer structure in nucleate boiling of water and ethanol at atmospheric pressure, Int. J. Heat Mass Transf 57 (2013) 222-230. DOI |
8 | P.C. Stephan, C.A. Busse, Analysis of the heat transfer coefficient of grooved heat pipe evaporator walls, Int. J. Heat Mass Transf 35 (1992) 383-391. DOI |
9 | L.E. Scriven, On the dynamics of phase growth, Chem. Eng. Sci. 10 (1959) 1-13. DOI |
10 | J.H. Lay, V.K. Dhir, Shape of a vapor stem during nucleate boiling of saturated liquids, J. Heat Transf 117 (1995) 394-401. DOI |
11 | Y. Lee, G. Park, TAPINS: a thermalehydraulic system code for transient analysis of a fully-passive integral PWR, Nucl. Eng. Technol 45 (2013) 439-458. DOI |
12 | H. Sakashita, Bubble growth rates and nucleation site densities in saturated pool boiling of water at high pressures, J. Nucl. Sci. Technol 48 (2011) 734-743. DOI |
13 | C.H. Han, P. Griffith, The mechanism of heat transfer in nucleate pool boiling-Part I. Bubble initiation, growth and departure, Int. J. Heat Mass Transf 8 (1965) 887-904. DOI |
14 | H.K. Forster, N. Zuber, Growth of a vapor bubble in a superheated liquid, J. Appl. Phys 25 (1954) 474-478. DOI |
15 | R. Cole, H.L. Shulman, Bubble growth rate at high Jakob numbers, Int. J. Heat Mass Transf 9 (1966) 1377-1390. DOI |
16 | H.C. Lee, B.D. Oh, S.W. Bae, M.H. Kim, Single bubble growth in saturated pool boiling on a constant wall temperature surface, Int. J. Multiphase Flow 29 (2003) 1857-1874. DOI |
17 | M.S. Plesset, S.A. Zwick, The growth of vapor bubbles in superheated fluids, J. Appl. Phys 25 (1954) 493-500. DOI |
18 | M. Akiyama, H. Tachibana, N. Ogawa, Effects of system pressure on bubble growth rate, Trans, JSME 35 (1969) 117-126 [In Japanese]. DOI |
19 | D.A. Labuntsov, B.A. Kol'chugin, V.S. Golovin, E.A. Zakharova, L.N. Vladimirova, Study of the growth of bubbles during boiling of saturated water within a wide range of pressures by means of high-speed moving pictures, UCS 536.423 1 (1964) 404-409 [translated from Teplofizika Vysokikh Temperatur 2(1964) 446-453]. |