Heat transfer simulation of annular elliptical fin-and-tube heat exchanger by transition SST model

H. Nemati; A. R. Rahimzadeh; Chi-chuan Wang

doi:10.1007/s11771-020-4452-5

Journal of Central South University ›› 2020, Vol. 27 ›› Issue (8) : 2324 -2337. DOI: 10.1007/s11771-020-4452-5

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Heat transfer simulation of annular elliptical fin-and-tube heat exchanger by transition SST model

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Abstract

In this study, thermo-fluid characteristics of elliptical annular finned tube heat exchanger were numerically studied in detail. Transition SST model was utilized to simulate turbulent flow. Effects of air velocities, horizontal to vertical fin diameter ratios, and fin densities were examined in detail. The simulations indicate superior performance of elliptical fin layout. It was shown that pressure drop of annular elliptical fin can be only one half of that of a circular annular fin while containing comparable heat transfer performance. The vertical elliptical annular fin may even contain a higher heat transfer performance over circular fin. Correlations are proposed to estimate the Nu number and pressure drop based on the annular circular fin. The maximum deviations between the proposed correlations and simulations regarding pressure drop and heat transfer coefficient are 5.6% and 3.2%, respectively. For further elaboration of the superiority of the elliptical layout from the second law perspective, normalized entropy generation was also studied. In all cases, the entropy generation rate in circular fin was higher than that of an elliptical fin.

Keywords

annular fin / elliptical fin / entropy generation / transition SST model / tube bundle

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H. Nemati, A. R. Rahimzadeh, Chi-chuan Wang. Heat transfer simulation of annular elliptical fin-and-tube heat exchanger by transition SST model. Journal of Central South University, 2020, 27(8): 2324-2337 DOI:10.1007/s11771-020-4452-5

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References

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[1]	NiM L, ChenY P, DongC, WuJ F. Numerical simulation of heat transfer and flow of cooling air in triangular wavy fin channels. Journal of Central South University, 2014, 21(7): 2759-2765

[2]	GhasemiS, ValipourP, HatamiM, GanjiD. Heat transfer study on solid and porous convective fins with temperature-dependent heat generation using efficient analytical method. Journal of Central South University, 2014, 21(12): 4592-4598

[3]	MosayebidorchehS, Rahimi-GorjiM, GanjiD, MoayebidorchehT, PourmehranO, BiglarianM. Transient thermal behavior of radial fins of rectangular, triangular and hyperbolic profiles with temperature-dependent properties using DTM-FDM. Journal of Central South University, 2017, 24(3): 675-682

[4]	SHAH R K, SEKULIC D P. Fundamentals of heat exchanger design [M]. John Wiley & Sons, 2003.

[5]	NEAL S, HITCHCOCK J. A study of the heat transfer processes in banks of finned tubes in cross flow, using a large scale model technique [C]// Proceedings of the Third International Heat Transfer Conference. Chicago, Illinois, 1966.

[6]	LegkiyV. Investigation of local heat transfer in a tube with annular fins in transverse air flow. Heat Tranfer-Soviet Research, 1974, 6: 101-107

[7]	StasiuleviciusJ, SkrinskaA, ZukauskasA. Heat transfer of finned tube bundles in crossflow. International Journal of Heat and Fluid Flow, 1998, 9(3): 347-348

[8]	GorobetsV. Coupled convective heat transfer from annular fins in transverse flow. Journal Of Applied Mechanics And Technical Physics, 1993, 34: 392-398

[9]	XiG, TorikoshiKComputation and visualization of flow and heat transfer in finned tube heat exchangers, 1996, Beijing, China, ISHT, 632637

[10]	HashizumeK, MorikawaR, KoyamaT, MatsueT. Fin efficiency of serrated fins. Heat Transfer Engineering, 2002, 23: 6-14

[11]	YakarG, KarabacakR. Investigation of thermal performance of perforated finned heat exchangers. Experimental Heat Transfer, 2015, 28: 354-365

[12]	BuyrukE, KarabulutK. Enhancement of heat transfer for plate fin heat exchangers considering the effects of fin arrangements. Heat Transfer Engineering, 2018, 39: 1392-1404

[13]	VälikangasT, KarvinenR. Conjugated heat transfer simulation of a fin-and-tube heat exchanger. Heat Transfer Engineering, 2018, 39: 1192-1200

[14]	NematiH, MoradaghayM. Parametric study of natural convection over horizontal annular finned tube. Journal of Central South University, 2019, 26(8): 2077-2087

[15]	JangJ Y, LaiJ T, LiuL C. The thermal-hydraulic characteristics of staggered circular finned-tube heat exchangers under dry and dehumidifying conditions. Int J Heat Mass Tran, 1998, 41: 3321-3337

[16]	MonM S, GrossU. Numerical study of fin-spacing effects in annular-finned tube heat exchangers. Int J Heat Mass Tran, 2004, 47: 1953-1964

[17]	NematiH, MoghimiM. Numerical study of flow over annular-finned tube heat exchangers by different turbulent models. CFD Letters, 2014, 6: 101-112

[18]	BošnjakovićM, ČikićA, MuhičS, StojkovM. Development of a new type of finned heat exchanger. Tehnički Vjesnik-Technical Gazette, 2017, 24: 1785-1796

[19]	Morales-FuentesA, Loredo-SáenzY. Identifying the geometry parameters and fin type that lead to enhanced performance in tube-and-fin geometries. Applied Thermal Engineering, 2018, 131: 793-805

[20]	BenmachicheA H, TahrourF, AissaouiF, AksasM, BougriouC. Comparison of thermal and hydraulic performances of eccentric and concentric annular-fins of heat exchanger tubes. Heat and Mass Transfer, 2017, 53: 2461-2471

[21]	TahrourF, BenmachicheA H, AksasM, BougriouC. 3-D numerical study and comparison of eccentric and concentric annular-finned tube heat exchangers. J Eng Sci Technol, 2015, 10: 1508-1524

[22]	NematiH, MoghimiM, SapinP, MarkidesC. Shape optimisation of air-cooled finned-tube heat exchangers. International Journal of Thermal Sciences, 2020, 150: 106233

[23]	JangJ Y, YangJ Y. Experimental and 3-D numerical analysis of the thermal-hydraulic characteristics of elliptic finned-tube heat exchangers. Heat Transfer Engineering, 1998, 1955-67

[24]	MatosR, VargasJ, LaursenT, BejanA. Optimally staggered finned circular and elliptic tubes in forced convection. Int J Heat Mass Tran, 2004, 47: 1347-1359

[25]	KhanW A, CulhamR J, YovanovichM M. Fluid flow around and heat transfer from elliptical cylinders: analytical approach. Journal of thermophysics and Heat Transfer, 2005, 19: 178-185

[26]	SHEARD G J. Cylinders with elliptic cross-section: wake stability with variation in angle of incidence [C]// Proceedings of the IUTAM Symposium on Unsteady Separated flows and Their Control. Citeseer, 2007.

[27]	AlawadhiE M. Laminar forced convection flow past an in-line elliptical cylinder array with inclination. Journal of Heat Transfer, 2010, 132: 071701

[28]	KunduB, DasP. Performance analysis and optimization of elliptic fins circumscribing a circular tube. International Journal of Heat And Mass Transfer, 2007, 50173-180

[29]	NematiH, SamivandS. Simple correlation to evaluate efficiency of annular elliptical fin circumscribing circular tube. Arabian Journal for Science and Engineering, 2014, 39: 9181-9186

[30]	NematiH, SamivandS. Numerical study of flow over annular elliptical finned tube heat exchangers. Arabian Journal for Science and Engineering, 2016, 41: 4625-4634

[31]	ZhukauskasA. Investigation of heat-transfer in different arrangements of heat-exchanger surfaces. Thermal Engineering, 1974, 21: 40-46

[32]	JacobiA M, ShahR K. Air-side flow and heat transfer in compact heat exchangers: A discussion of enhancement mechanisms. Heat Transfer Engineering, 1998, 19: 29-41

[33]	MenterF, LangtryR, VölkerS. Transition modelling for general purpose CFD codes. Flow, Turbulence and Combustion, 2006, 77: 277-303

[34]	MenterF R. Two-equation eddy-viscosity turbulence models for engineering applications. AIAA Journal, 1994, 32: 1598-1605

[35]	ANSYS/Fluent user guide version 18.1 [R]. ANSYS Incorporated, 2018.

[36]	OsleyW G, DroegemuellerP, EllerbyP, GibbardI. Computational fluid dynamics investigation of air cooled heat exchangers. Chemical Engineering Transactions, 2014, 39: 1351-1356

[37]	BriggsD E, YoungE H. Convection heat transfer and pressure drop of air flowing across triangular pitch banks of finned tubes. Chemical Engineering Progress Symposium Series, 1963, 59(41): 1-10

[38]	GianolioE, CutiF. Heat transfer coefficients and pressure drops for air coolers with different numbers of rows under induced and forced draft. Heat Transfer Engineering, 1981, 3: 38-48

[39]	VEREIN DEUTSCHER INGENIEUREV G V U C. VDI-WärmeatlasBerechnungsblätter für den Wärmeübergang, 2002, Berlin Heidelberg, Springer

[40]	WardD, YoungE. Heat transfer and pressure drop of air in forced convection across triangular pitch banks of finned tubes. Chemical Engineering Progress, 1959, 55(29): 37-44

[41]	ROBINSON K K, BRIGGS D E. Pressure drop of air flowing across triangular pitch banks of finned tubes [J]. Chemical Engineering Progress Symposium Series, 1966: 177–184.