PDF
(1297KB)
Abstract
The intermediate fluid vaporizer (IFV), different from other liquefied natural gas (LNG) vaporizers, has many advantages and has shown a great potential for future applications. In this present paper, studies of IFV and its heat transfer characteristics in the LNG vaporization unit E2 are systematically reviewed. The research methods involved include theoretical analysis, experimental investigation, numerical simulation, and process simulation. First, relevant studies on the overall calculation and system design of IFV are summarized, including the structural innovation design, the thermal calculation model, and the selection of different intermediate fluids. Moreover, studies on the fluid flow and heat transfer behaviors of the supercritical LNG inside the tubes and the condensation heat transfer of the intermediate fluid outside the tubes are summarized. In the thermal calculations of the IFV, the selections of the existing heat transfer correlations about the intermediate fluids are inconsistent in different studies, and there lacks the accuracy evaluation of those correlations or comparison with experimental data. Furthermore, corresponding experiments or numerical simulations on the cryogenic condensation heat transfer outside the tubes in the IFV need to be further improved, compared to those in the refrigeration and air-conditioning temperature range. Therefore, suggestions for further studies of IFV are provided as well.
Graphical abstract
Keywords
intermediate fluid vaporizer
/
design of structure and intermediate fluid
/
condensation heat transfer
Cite this article
Download citation ▾
Shu LI, Yonglin JU.
Review of the LNG intermediate fluid vaporizer and its heat transfer characteristics.
Front. Energy, 2022, 16(3): 429-444 DOI:10.1007/s11708-021-0747-y
| [1] |
IGU. State of the LNG Industry. 2020 World LNG Report, 2020
|
| [2] |
Cheng H, Ju Y L, Fu Y Z. Thermal performance calculation with heat transfer correlations and numerical simulation analysis for typical LNG open rack vaporizer. Applied Thermal Engineering, 2019, 149: 1069–1079
|
| [3] |
Ooka I, Sato T, Niwa K. Apparatus and process for vaporizing liquefied natural gas. US patent, 813095, 1979
|
| [4] |
Li J H. Process analysis of IFV seawater system. Shanghai Gas, 2013, (3): 4–6 (in Chinese)
|
| [5] |
Chen Y D, Chen X D. Technology analysis of heat exchanger in large LNG plant and terminal. Natural Gas Industry, 2010, 30(01): 96–100, 147–148 (in Chinese)
|
| [6] |
Cai X H, Qin F. Research on the key technology of domestically produced intermediate medium gasifier. China Offshore Oil and Gas, 2013, 25(04): 59–62, 66 (in Chinese)
|
| [7] |
Liu F X, Dai Y Q, Wei W, Feasibility of intermediate fluid vaporizer with spiral wound tubes. China Petroleum Processing and Petrochemical Technology, 2013, 15(01): 73–77
|
| [8] |
Liu F, Li H, Zhang X F, Development and manufacture of LNG intermediate fluid vaporizer used in sea water condition. Chemical Industry and Engineering Progress, 2015, 34(S1): 99–103
|
| [9] |
Kim D Y, Sung T H, Kim K C. Application of metal foam heat exchangers for a high-performance liquefied natural gas regasification system. Energy, 2016, 105: 57–69
|
| [10] |
Wang Z, Cai W J, Hong W, Multi-objective optimization design and performance evaluation of a novel multi-stream intermediate fluid vaporizer with cold energy recovery. Energy Conversion and Management, 2019, 195: 32–42
|
| [11] |
Wang B J, Wang W, Qi C, Simulation of performance of intermediate fluid vaporizer under wide operation conditions. Frontiers in Energy, 2020, 14(3): 452–462
|
| [12] |
Bai Y H, Liao Y, Lu Y K, Calculation method for heat exchange area of large-scale LNG intermediate fluid vaporizer. Natural Gas and Oil, 2013, 31(03): 31–35, 5 (in Chinese)
|
| [13] |
Pu L, Qu Z G, Bai Y H, Thermal performance analysis of intermediate fluid vaporizer for liquefied natural gas. Applied Thermal Engineering, 2014, 65(1–2): 564–574
|
| [14] |
Xu S Q, Chen X D, Fan Z C. Thermal design of intermediate fluid vaporizer for subcritical liquefied natural gas. Journal of Natural Gas Science and Engineering, 2016, 32: 10–19
|
| [15] |
Higashi K, Kondou C, Koyama S. Feasibility analysis for intermediated fluid type LNG vaporizers using R32 and R410A considering fluid properties. International Journal of Refrigeration, 2020, 118: 325–335
|
| [16] |
Dittus F W, Boelter L M K. Heat transfer in automobile radiators of the tubular type. International Communications in Heat and Mass Transfer, 1985, 12(1): 3–22
|
| [17] |
Cooper M G. Saturation nucleate pool boiling–a simple correlation. In: Simpson H C, Hewitt G F, Boland D, Bott T R, Furber B N, Hall W B, Heggs P J, Rowe P N, Saunders E A D, Spalding D B, eds. 1st UK National Conference on Heat Transfer. London: The Institution of Chemical Engineers, 1984, 785–793
|
| [18] |
Stephan K, Abdelsalam M. Heat-transfer correlations for natural convection boiling. International Journal of Heat and Mass Transfer, 1980, 23(1): 73–87
|
| [19] |
Gorenflo D, Baumhögger E, Windmann T, Nucleate pool boiling, film boiling and single-phase free convection at pressures up to the critical state. Part I: integral heat transfer for horizontal copper cylinders. International Journal of Refrigeration, 2010, 33(7): 1229–1250
|
| [20] |
Ribatski G, Jabardo J M S. Experimental study of nucleate boiling of halocarbon refrigerants on cylindrical surfaces. International Journal of Heat and Mass Transfer, 2003, 46(23): 4439–4451
|
| [21] |
Jung D, Kim Y, Ko Y, Nucleate boiling heat transfer coefficients of pure halogenated refrigerants. International Journal of Refrigeration, 2003, 26(2): 240–248
|
| [22] |
Jung D, Lee H, Bae D, Nucleate boiling heat transfer coefficients of flammable refrigerants. International Journal of Refrigeration, 2004, 27(4): 409–414
|
| [23] |
Wang Y Z, Hua Y X, Meng H. Numerical studies of supercritical turbulent convective heat transfer of cryogenic-propellant methane. Journal of Thermophysics and Heat Transfer, 2010, 24(3): 490–500
|
| [24] |
Jackson J D, Hall W B. Forced convection heat transfer to fluids at supercritical pressure. In: Kakac S, Spalding D B, eds. Turbulent Forced Convection in Channels and Bundles. New York: Hemisphere, 1979, 563–612
|
| [25] |
Nusselt W. The surface condensation of water vapour. Journal of the Association of German Engineers, 1916, 60: 541–546
|
| [26] |
Dhir V, Lienhard J. Laminar film condensation on plane and axisymmetric bodies in nonuniform gravity. Journal of Heat Transfer, 1971, 93(1): 97–100
|
| [27] |
Jung D, Chae S, Bae D, Condensation heat transfer coefficients of flammable refrigerants. International Journal of Refrigeration, 2004, 27(3): 314–317
|
| [28] |
Kern D Q. Mathematical development of tube loading in horizontal condensers. AIChE Journal, 1958, 4(2): 157–160
|
| [29] |
Honda H, Uchima B, Nozu S, Condensation of downward flowing R-113 vapor on bundles of horizontal smooth tubes. Transactions of the Japan Society of Mechanical Engineers Series B, 1988, 54(502): 1453–1460
|
| [30] |
Zhukauskas A A. Convective Heat Transfer in the Heat Exchanger. Beijing: Science Press, 1986
|
| [31] |
Xu S Q, Cheng Q, Zhuang L J, LNG vaporizers using various refrigerants as intermediate fluid: comparison of the required heat transfer area. Journal of Natural Gas Science and Engineering, 2015, 25: 1–9
|
| [32] |
Han H, Yan Y, Wang S, Thermal design optimization analysis of an intermediate fluid vaporizer for liquefied natural gas. Applied Thermal Engineering, 2018, 129: 329–337
|
| [33] |
Yan Y, Li Y X, Wang S. The comparison and parameters optimization for the mixed intermediate fluid of intermediate fluid vaporizer. In: ASME 2019 Asia Pacific Pipeline Conference, Qingdao, China, 2019
|
| [34] |
Wang S, Han H, Li Y X, Parameters optimization of intermediate fluid vaporizer based on mixed working fluid. Oil & Gas Storage and Transportation, 2020, 39(01): 104–111
|
| [35] |
Ji X, Chen S S, Lin W S. Analysis of single-phase heat transfer process in LNG intermediate fluid vaporizer. Chinese Journal of Refrigeration Technology, 2016, 36(04): 57–60+67 (in Chinese)
|
| [36] |
Ji X, Chen S S, Song Y, Heat transfer experiment of sub-cooled intermediate fluid vaporizer. CIESC Journal, 2015, 66(S2): 56–61
|
| [37] |
Song Y, Ji X, Lin W S. Numerical simulation of heat transfer process within sub-cooled intermediate fluid vaporizer. CIESC Journal, 2015, 66(S2): 62–65
|
| [38] |
Pizzarelli M, Urbano A, Nasuti F. Numerical analysis of deterioration in heat transfer to near-critical rocket propellants. Numerical Heat Transfer Part A, 2010, 57(5): 297–314
|
| [39] |
Yang V. Modeling of supercritical vaporization, mixing, and combustion processes in liquid-fueled propulsion systems. Proceedings of the Combustion Institute, 2000, 28(1): 925–942
|
| [40] |
Yang J, Oka Y, Ishiwatari Y, Numerical investigation of heat transfer in upward flows of supercritical water in circular tubes and tight fuel rod bundles. Nuclear Engineering and Design, 2007, 237(4): 420–430
|
| [41] |
Zhang X R, Yamaguchi H. Forced convection heat transfer of supercritical CO2 in a horizontal circular tube. Journal of Supercritical Fluids, 2007, 41(3): 412–420
|
| [42] |
Sharabi M, Ambrosini W, He S, Prediction of turbulent convective heat transfer to a fluid at supercritical pressure in square and triangular channels. Annals of Nuclear Energy, 2008, 35(6): 993–1005
|
| [43] |
Sharabi M, Ambrosini W. Discussion of heat transfer phenomena in fluids at supercritical pressure with the aid of CFD models. Annals of Nuclear Energy, 2009, 36(1): 60–71
|
| [44] |
Pizzarelli M, Nasuti F, Paciorri R, Numerical analysis of three-dimensional flow of supercritical fluid in asymmetrically heated channels. AIAA Journal, 2009, 47(11): 2534–2543
|
| [45] |
Xu K K, Tang L J, Meng H. Numerical study of supercritical-pressure fluid flows and heat transfer of methane in ribbed cooling tubes. International Journal of Heat and Mass Transfer, 2015, 84: 346–358
|
| [46] |
Liang K M, Yang B, Zhang Z L. Investigation of heat transfer and coking characteristics of hydrocarbon fuels. Journal of Propulsion and Power, 1998, 14(5): 789–796
|
| [47] |
Ricci D, Natale P, Battista F. Experimental and numerical investigation on the behaviour of methane in supercritical conditions. Applied Thermal Engineering, 2016, 107: 1334–1353
|
| [48] |
Yao S G, Xu W J, Ye Y, Numerical simulation analysis of flow and heat transfer of supercritical LNG in the IFV condenser. Bulgarian Chemical Communications, 2016, 48: 123–130
|
| [49] |
Xu S Q, Chen X D, Fan Z C. CFD simulation of supercritical LNG heat transfer in a horizontal tube of an intermediate fluid vaporizer. In: ASME 2017 Pressure Vessels and Piping Conference, Waikoloa, NY, USA, 2017
|
| [50] |
Xu S Q, Chen X D, Fan Z C, The influence of chemical composition of LNG on the supercritical heat transfer in an intermediate fluid vaporizer. Cryogenics, 2018, 91: 47–57
|
| [51] |
Cheng H, Ju Y L, Fu Y Z. Experimental and simulation investigation on heat transfer characteristics of supercritical nitrogen in a new rib tube of open rack vaporizer. International Journal of Refrigeration, 2020, 111: 103–112
|
| [52] |
Cheng H, Yin L, Ju Y L, Experimental investigation on heat transfer characteristics of supercritical nitrogen in a heated vertical tube. International Journal of Thermal Sciences, 2020, 152: 106327
|
| [53] |
Kutateladze S S. Semi-empirical theory of film condensation of pure vapours. International Journal of Heat and Mass Transfer, 1982, 25(5): 653–660
|
| [54] |
Honda H, Nozu S. A prediction method for heat transfer during film condensation on horizontal low integral-fin tubes. Journal of Heat Transfer, 1987, 109(1): 218–225
|
| [55] |
Cavallini A, Col D D, Doretti L, A new model for refrigerant condensation on the outside of three-dimensional enhanced tubes. In: Heat Transfer Conference, 1998, 6: 355–360
|
| [56] |
Al-Badri A R, Gebauer T, Leipertz A, Element by element prediction model of condensation heat transfer on a horizontal integral finned tube. International Journal of Heat and Mass Transfer, 2013, 62: 463–472
|
| [57] |
Jung D, Kim C B, Cho S, Condensation heat transfer coefficients of enhanced tubes with alternative refrigerants for CFC11 and CFC12. International Journal of Refrigeration, 1999, 22(7): 548–557
|
| [58] |
Jung D, Kim C B, Hwang S M, Condensation heat transfer coefficients of R22, R407C, and R410A on a horizontal plain, low fin, and turbo-C tubes. International Journal of Refrigeration, 2003, 26(4): 485–491
|
| [59] |
Park K J, Jung D. Condensation heat transfer coefficients of flammable refrigerants on various enhanced tubes. Journal of Mechanical Science and Technology, 2005, 19(10): 1957–1963
|
| [60] |
Gebauer T, Al-Badri A R, Gotterbarm A, Condensation heat transfer on single horizontal smooth and finned tubes and tube bundles for R134a and propane. International Journal of Heat and Mass Transfer, 2013, 56(1–2): 516–524
|
| [61] |
Sajjan S K, Kumar R, Gupta A. Experimental investigation of vapor condensation of iso-butane over single horizontal plain tube under different vapor pressures. Applied Thermal Engineering, 2015, 76: 435–440
|
| [62] |
Sajjan S K, Kumar R, Gupta A. Experimental investigation during condensation of R-600a vapor over single horizontal integral-fin tubes. International Journal of Heat and Mass Transfer, 2015, 88: 247–255
|
| [63] |
Ji W T, Chong G H, Zhao C Y, Condensation heat transfer of R134a, R1234ze(E) and R290 on horizontal plain and enhanced titanium tubes. International Journal of Refrigeration, 2018, 93: 259–268
|
| [64] |
Chen S S, Ji X, Lin W S. Experiments on phase-change heat transfer of propane intermediate fluid vaporizer. CIESC Journal, 2015, 66(S2): 192–197
|
| [65] |
Pang X D, Yang G C, Chen J, Experimental investigation of heat transfer characteristics of propane condensation in helical baffle shell-tube heat exchanger. Chinese Journal of Refrigeration Technology, 2016, 036(005): 31–37 (in Chinese)
|
| [66] |
Mi X G, Yang G C, Chen J, Experimental investigation on mixed hydrocarbon refrigerant flow condensation characteristics in shell side of helically baffled shell-and-tube condenser. Chinese Journal of Refrigeration Technology, 2018, 38(2): 6–10 (in Chinese)
|
| [67] |
Al-Badri A R, Bär A, Gotterbarm A, The influence of fin structure and fin density on the condensation heat transfer of R134a on single finned tubes and in tube bundles. International Journal of Heat and Mass Transfer, 2016, 100: 582–589
|
| [68] |
Li W, Sun Z C, Guo R H, Condensation heat transfer of R410A on outside of horizontal smooth and three-dimensional enhanced tubes. International Journal of Refrigeration, 2019, 98: 1–14
|
| [69] |
Ko J, Jeon D. Experimental study on film condensation heat transfer characteristics of R134a, R1234ze(E) and R1233zd(E) over condensation tube with enhanced surfaces. Heat and Mass Transfer, 2020, 56(11): 3001–3010
|
| [70] |
Tang W Y, Kukulka D J, Li W, Comparison of the evaporation and condensation heat transfer coefficients on the external surface of tubes in the annulus of a tube-in-tube heat exchanger. Energies, 2020, 13(4): 952
|
| [71] |
Beatty K O, Katz D L. Condensation of vapors on outside of finned tubes. Chemical Engineering Progress, 1948, 44(1): 55–70
|
| [72] |
Yang Y W, Yin J X, Ou L J. Numerical study on condensation heat transfer of steam with non-condensable gas outside an elliptical tube. Science Technology and Engineering, 2016, 16(5): 71–76 (in Chinese)
|
| [73] |
Lu J H, Cao H S, Li J M. Condensation heat and mass transfer of steam with non-condensable gases outside a horizontal tube under free convection. International Journal of Heat and Mass Transfer, 2019, 139: 564–576
|
| [74] |
Minko K B, Yankov G G, Artemov V I, A mathematical model of forced convection condensation of steam on smooth horizontal tubes and tube bundles in the presence of noncondensables. International Journal of Heat and Mass Transfer, 2019, 140: 41–50
|
| [75] |
Park H C, Choi H S. CFD study of Marangoni condensation heat transfer of vapor mixture on a horizontal tube. Heat and Mass Transfer, 2020, 56(9): 2743–2755
|
| [76] |
Ji W T, Mao S F, Chong G H, Numerical and experimental investigation on the condensing heat transfer of R134a outside plain and integral-fin tubes. Applied Thermal Engineering, 2019, 159: 113878
|
| [77] |
Kleiner T, Rehfeldt S, Klein H. CFD model and simulation of pure substance condensation on horizontal tubes using the volume of fluid method. International Journal of Heat and Mass Transfer, 2019, 138: 420–431
|
| [78] |
Zhang L L, Zhang G M, Mao W L, Experimental and numerical study on filmwise condensation of pure propane and propane/methane mixture. International Journal of Heat and Mass Transfer, 2020, 156: 119744
|
RIGHTS & PERMISSIONS
Higher Education Press
