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2019 | OriginalPaper | Buchkapitel

13. Direct Contact Condensation of Steam in Subcooled Water

verfasst von : Priyankan Datta, Aranyak Chakravarty, Koushik Ghosh, Achintya Mukhopadhyay, Swarnendu Sen

Erschienen in: Two-Phase Flow for Automotive and Power Generation Sectors

Verlag: Springer Singapore

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Abstract

Direct contact condensation (DCC) of steam in subcooled water is a phenomenon which is experienced in many applications such as thermal, chemical and nuclear engineering, particularly in energy generation devices since it enables immense energy transfer via the two-phase interface. However, under certain situations, steam water direct contact can lead to rapid condensation and result in fast (of the order of acoustic time scale) pressure transients which could have serious implications on structural integrity and safety, especially in nuclear power plants. Therefore, understanding of the underlying physics and characteristics of DCC phenomenon has a paramount importance. DCC is a complex thermo-hydraulic event in which the phase change process is governed by the interplay between several thermo-mechanical factors (e.g. local heat transfer coefficient, interfacial area density, turbulence intensity in the liquid phase) across the phasic interface. In this chapter, different situations of the DCC events, their characteristics and underlying mechanisms are discussed in detail. A detailed review of the earlier works which includes both system-level and interface scale modelling of the phenomena is also addressed in this chapter. An emphasis is given on the DCC events which are always associated with the large amplitude pressure spikes such as chugging and condensation-induced water hammer.

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Barna IF, Ezsöl G (2011) Multiple condensation induced water hammer events, experiments and theoretical investigations. Kerntechnik 76:231–236CrossRef

Barna IF, Imre AR, Baranyai G, Ézsöl G (2010a) Experimental and theoretical study of steam condensation induced water hammer phenomena. Nucl Eng Des 240:146–150CrossRef

Barna IF, Pocsai A, Guba A, Imre AR (2015) Theoretical study of steam condensation induced water hammer phenomena in horizontal pipelines. Kerntechnik 80:420–423CrossRef

Barna IF, Varga L, Ézsöl G (2010b) Steam condensation induced water hammer simulations for different pipelines in nuclear reactor. In: The 8th international topical meeting on nuclear thermal-hydraulics, operation and safety (NUTHOS-8), Shanghai, China

Bjorge RW, Griffith P (1984) Initiation of water hammer in horizontal and nearly horizontal pipes containing steam and subcooled water. ASME J Heat Transf 106:835–840CrossRef

Ceuca SC, Laurinavicius D (2015) Experimental and numerical investigations on the direct contact condensation phenomenon in horizontal flow channels and its implications in nuclear safety. Kerntechnik 81:504–511CrossRef

Chan CK, Lee CKB (1982) A regime map for direct contact condensation. Int J Multiph Flow 8:11–20CrossRef

Chandrasekhar S (1961) Hydrodynamic and hydromagnetic stability. Dover Publications, INC., New YorkMATH

Chun M-H, Kim Y-S, Park J-W (1996) An investigation of direct condensation of steam jet in subcooled water. Int Commun Heat Mass Transf 23:947–958CrossRef

Datta P, Chakravarty A, Ghosh K, Mukhopadhyay A, Sen S (2018) Modeling of steam–water direct contact condensation using volume of fluid approach. Numer Heat Transf, Part A 73:17–33CrossRef

Datta P, Chakravarty A, Ghosh K, Mukhopadhyay A, Sen S (2017) Modeling aspects of vapour bubble condensation in subcooled liquid using the VOF approach. Numer Heat Transf, Part A 72:236–254CrossRef

Datta P, Chakravarty A, Ghosh K, Mukhopadhyay A, Sen S, Dutta A, Goyal P (2016) A numerical analysis on the effect of inlet parameters for condensation induced water hammer. Nucl Eng Des 304:50–62CrossRef

Dirndorfer S (2017) Steam condensation induced water hammer in a vertical up-fill configuration within an integral test facility: experiments and computational simulations. Ph.D. Thesis, Universität der Bundeswehr München, Germany

Drazin PG (2002) Introduction to hydrodynamic stability. Cambridge University Press, CambridgeCrossRef

Giot M (2000) Two-phase flow water hammer transients and induced loads on materials and structures of nuclear power plants (WAHALoads). https://cordis.europa.eu/docs/publications/6996/69969381-6_en.pdf

Gregu G, Takahashi M, Pellegrini M, Mereu R (2017) Experimental study on steam chugging phenomenon in a vertical sparger. Int J Multiph Flow 88:87–98CrossRef

Griffith P (1997) Screening reactor steam/water piping systems for water hammer. Massachusetts Institute of Technology, NUREGICR-6519

Hou X, Sun Z, Su J, Fan G (2016) An investigation on flashing instability induced water hammer in an open natural circulation system. Prog Nucl Energy 93:418–430CrossRef

Jones OC, Saha PJ, Wu BJC, Ginsberg T (1979) condensation induced water hammer in steam generators. Department of Nuclear Energy, Brookhaven National Laboratory, New York, BNL-NUREG-26789

Kim HY, Bae YY, Song C-H, Park JK, Choi SM (2001) Experimental study on stable steam condensation in a quenching tank. Int J Energy Res 25:239–252CrossRef

Kim Y-S, Park J-W, Song C-H (2004) Investigation of the steam-water direct contact condensation heat transfer coefficients using interfacial transport models. Int Commun Heat Mass Transf 31:397–408CrossRef

Lahey RT, Moody FJ (1993) The thermal-hydraulics of a boiling water nuclear reactor. American Nuclear Society, La Grange Park

Laine J, Puustinen M (2005) Condensation pool experiments with steam using DN200 blowdown pipe. Lappeenranta University of Technology, Finland, NKS-111, ISBN 187-7893-7171-7891

Li SQ, Wang P, Lu T (2015) CFD based approach for modeling steam-water direct contact condensation in subcooled water flow in a tee junction. Prog Nucl Energy 85:729–746CrossRef

Liang K-S (1991) Experimental and analytical study of direct contact condensation of steam in water, Ph.D. Thesis, Department of Nuclear Engineering, Massachusetts Institute of Technology, USA

Liang K-S, Griffith P (1994) Experimental and analytical study of direct contact condensation of steam in water. Nucl Eng Des 147:425–435CrossRef

Mahapatra PS, Datta P, Chakravarty A, Ghosh K, Manna NK, Mukhopadhyay A, Sen S (2017) Molten drop to coolant heat transfer during premixing of fuel coolant interaction. In: Basu S, Agarwal AK, Mukhopadhyay A, Patel C (eds) Application paradigms of droplet and spray transport: paradigms and applications. Springer Nature Singapore Pte Ltd, Singapore

Milivojevic S, Stevanovic V, Maslovaric B (2014) Condensation induced water hammer: numerical prediction. J Fluids Struct 50:416–436CrossRef

Pellegrini M, Araneo L, Ninokata H, Ricotti M, Naitoh M, Achilli A (2016) Suppression pool testing at the SIET laboratory: experimental investigation of critical phenomena expected in the Fukushima Daiichi suppression chamber. J Nucl Sci Technol 53:614–629CrossRef

Puustinen M, Laine J (2008) Characterizing experiments of the PPOOLEX test facility. Lappeenranta University of Technology, Finland, NKS-167, ISBN 978-187-7893-7232-7897

Puustinen M, Laine J, Räsänen A, Hujala E (2014) Chugging test with DN100 blowdown pipe in the PPOOLEX facility, NKS-310, ISBN 978-387-7893-7388-7891

Sideman S, Maron D (1982) Direct contact condensation. Adv Heat Transf 15:227–281CrossRef

Simpson ME, Chan CK (1982) Hydrodynamics of a subsonic vapor jet in subcooled liquid. ASME J Heat Transf 104:271–277CrossRef

Tanskanen V (2012) CFD modelling of direct contact condensation in suppression pools by applying condensation models of separated flow. Ph.D. Thesis, Lappeenranta University of Technology, Finland

Tanskanen V, Jordan A, Puustinen M, Kyrki-Rajamäki R (2014) CFD simulation and pattern recognition analysis of the chugging condensation regime. Ann Nucl Energy 66:133–143CrossRef

Tiselj I, Horvat A, Černe G, Gale J, Parzer I, Mavko B, Giot M, Seynhaeve JM, Kucienska B, Lemonnier H (2004) WAHALoads-Two-phase flow water hammer transients and induced loads on materials and structures of nuclear power plants, Deliverable D10: WAHA3 code manual, IJS-DP-8841

Urban C, Schlüter M (2014) Investigations on the stochastic nature of condensation induced water hammer. Int J Multiph Flow 67:1–9CrossRef

Wang L, Yue X, Chong D, Chen W, Yan J (2018) Experimental investigation on the phenomenon of steam condensation induced water hammer in a horizontal pipe. Exp Thermal Fluid Sci 91:451–458CrossRef

Wu X, Yan J, Li W, Pan D, Chong D (2009) Experimental study on sonic steam jet condensation in quiescent subcooled water. Chem Eng Sci 64:5002–5012CrossRef

Wu X, Yan J, Shao S, Cao Y, Liu J (2007) Experimental study on the condensation of supersonic steam jet submerged in quiescent subcooled water: steam plume shape and heat transfer. Int J Multiph Flow 33:1296–1307CrossRef

Xu Q, Ye S, Chen Y, Chen Q, Guo L (2018) Condensation regime diagram for supersonic and subsonic steam jet condensation in water flow in a vertical pipe. Appl Therm Eng 130:62–73CrossRef

Titel: Direct Contact Condensation of Steam in Subcooled Water
verfasst von: Priyankan Datta
Aranyak Chakravarty
Koushik Ghosh
Achintya Mukhopadhyay
Swarnendu Sen
Verlag: Springer Singapore
Buch: Two-Phase Flow for Automotive and Power Generation Sectors
Print ISBN: 978-981-13-3255-5

Electronic ISBN: 978-981-13-3256-2

Copyright-Jahr: 2019
DOI: https://doi.org/10.1007/978-981-13-3256-2_13

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