Global Nuclear Safety
National Research Nuclear University "MEPhI"
online version: ISSN 2499-9733
print version: ISSN 2305-414Х
2017-2(23)
Operation of nuclear industry facilities
| Article Name | Prospects of Nanoliquid Use in Heat Withdrawal Systems in the Beyond Design Basis Accidents Accompanied with Fissile Area Melting |
|---|---|
| Authors | A.L. Sirotkina, E.D. Fedorovich, V.V. Sergeev |
| Address | Peter the Great St.-Petersburg Polytechnic University, St.-Petersburg |
| Abstract | The article represents assessment results of prospects of nanodispersible liquids (nanoliquids) use in the NPP security systems, in particular, in emergency cooling system of the reactor vessel in the beyond design basis accidents accompanied with fissile area melting. The assessment is based on experiment and theoretical model operation results which short description is given at the beginning of article |
| Keywords | corium deduction, nanoliquid, security systems, burn-out, critical heat flux |
| Language | Russian |
| References | [1] Kutateladze S.S. Teploperedacha pri kondensatcii i kipenii [Heat Transfer at Condensation and Boiling]. M. Pub. Mashgiz [Mashgiz], 1952, 236 p. (in Russian) [2] Kim S.J. [et al] Surface wettability change during pool boiling of nanofluids and its effect on critical heat flux. International Journal of Heat and Mass Transfer, 2007, №50, pp. 4105–4116. (in English) [3] Jeong Y.H., Chang W.J., Chang S.H. Wettability of heated surfaces under pool boiling using surfactant solutions and nano-fluids. International Journal of Heat and Mass Transfer, 2008, №51, pp. 3025–3031. (in English) [4] Fokin B.S., Belenkii M.Ia., Almiashev V.I., Khabenskii V.B., Almiasheva O.V., Gusarov V.V. Kriticheskii teplovoi potok pri kipenii vodnoi dispersii nanochastitc [Critical Heat Flux when Boiling Aqueous Dispersion of Nanoparticles]. Pisma v Zhurnal tekhnicheskoi fiziki [Letters to Technical Physics Journal], 2009, Vol. 35(10), ISSN 0320-0116, pp. 1–5. (in Russian) [5] Vasilev N.V., Zeigarnik Iu.A., Kuzma-Kichta Iu.A. etc. Eksperimentalnye dannye po kipeniiu vody, nedogretoi do temperatury nasyshcheniia, na poverkhnostiakh s mezorelefom [The Experimental Datas on Boiling of Water Underheated to saturation temperature on Surfaces with Mesorelief]. Teplovye protcessy v tekhnike [Thermal Processes in Technique], 2016, №8(3), ISSN 2074-2649, pp. 98–102. (in Russian) [6] Coyle C., Buongiorno J., McKrell T. Synthesis of CRUD and its Effect On Pool and Subcooled Flow Boiling: CASL L3 Milestone Report. USA: US Department of Energy, 2015, 16 p. Available at: http://www.casl.gov/docs/CASL-U-2015-0068-000.pdf (in English) [7] Corradini, M. Marschman S., Goldner F. Improved LWR cladding performance by EPD surface modification technique: Final report of NEUP project 09-766. Madison: University of Wisconsin, 2012, 62 p. (in English) [8] Chupin A., Hu L.W., Buongiorno J. Applications of nanofluids to enhance LWR accidents management in in-vessel retention and emergency cooling systems. Proceedings of ICAPP’08: Paper 8043. Anaheim, CA USA, 2008, pp. 1707–1714. (in English) [9] Frittc V. Vychislenie maksimalnogo obema parovogo puzyria [Calculation of Maximal Volume of Steam Bubble]. Phyz Z, 1935, №36(11), pp. 379–384. (in Russian) [10] Labuntcov D.A., Iagov V.V. Mekhanika dvukhfaznykh sistem: uchebnoe posobie dlia vuzov [Mechanics of Two-Phase Systems: manual for higher education institutions]. M. Pub. MPEI, 2000, 374 p. (in Russian) [11] Theofanous T.G., Dinh T.N. High heat flux boiling and burnout as microphysical phenomena: mounting evidence and opportunities. Multiphase Science Tech, 2006, №18(1), pp. 361–364. (in English) |
| Papers | 81 - 88 |
| URL Article | URL Article |
| Open Article |