Characteristics and mechanism investigation on drag reduction of oblique riblets

Yun-qing Gu; Tian-xing Fan; Jie-gang Mou; Deng-hao Wu; Shui-hua Zheng; Evan Wang

doi:10.1007/s11771-017-3542-5

Journal of Central South University ›› 2017, Vol. 24 ›› Issue (6) : 1379 -1386. DOI: 10.1007/s11771-017-3542-5

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Characteristics and mechanism investigation on drag reduction of oblique riblets

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Abstract

This work primarily focuses on the drag reduction characteristics and mechanism investigation of oblique riblets. First, a calculation model of the oblique riblets surface is established, and Reynolds stress model (RSM) turbulence model is used for numerical simulation of the oblique riblets flow field. Subsequently, the influence of inclination angle between flow direction and arrangement direction of riblets on friction resistance and drag reduction rate is further analyzed. Through the investigation of the distribution of shear stress, pressure stress and velocity in oblique riblets boundary layer, the oblique riblets drag reduction mechanism is finally revealed. Results show that, with increase of velocity and inclination angle, the pressure resistance increases obviously, along with the decreasing of the viscous resistance distinctly. The maximum drag reduction rate of the oblique riblets is 7.33%. Moreover, when the inclination angle increases, the wall shear stress reduces on oblique riblets surface; while differential pressure increases at both sides of oblique riblets tips. In addition, when inclination angle is small, the secondary vortex at oblique riblets tips will disappear soon. New vortices will be formed inside the oblique riblets and cause the decrease of viscosity resistance. Thus, oblique riblets show a better drag reduction effect and have an effective control on boundary layer.

Keywords

oblique riblets / drag reduction / Reynolds stress model (RSM) / secondary vortex / numerical simulation

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Yun-qing Gu, Tian-xing Fan, Jie-gang Mou, Deng-hao Wu, Shui-hua Zheng, Evan Wang. Characteristics and mechanism investigation on drag reduction of oblique riblets. Journal of Central South University, 2017, 24(6): 1379-1386 DOI:10.1007/s11771-017-3542-5

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References

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[1]	ChenH-w, RaoF-g, ShangX-p, ZhangD-y, HagiwaraI. Biomimetic drag reduction study on herringbone riblets of bird feather [J]. Journal of Bionic Engineering, 2013, 10(3): 341-349

[2]	BuffatM, PenvenL L, CadiouA, MontagnierJ. DNS of bypass transition in entrance channel flow induced by boundary layer interaction [J]. European Journal of Mechanics-B/Fluids, 2014, 43: 1-13

[3]	WalshM J. Riblets as a viscous drag reduction technique [J]. AIAA Journal, 1983, 21(4): 485-486

[4]	LeeS J, LimH C, HanM, LeeS S. Flow control of circular cylinder with a V-grooved micro-riblet film [J]. Fluid Dynamics Research, 2005, 37(4): 246-266

[5]	LeeS J, ChoiY S. Decrement of spanwise vortices by a drag-reducing riblet surface [J]. Journal of Turbulence, 2008, 9(23): 1-15

[6]	StenzelV, WilkeY, HageW. Drag-reducing paints for the reduction of fuel consumption in aviation and shipping [J]. Progress in Organic Coatings, 2011, 70(4): 224-229

[7]	ChamorroL P, ArndtR E A, SotiropoulosF. Drag reduction of large wind turbine blades through riblets: Evaluation of riblet geometry and application strategies [J]. Renewable Energy, 2013, 50: 1095-1105

[8]	NugrohoB, HutchinsN, MontyJ P. Large-scale spanwise periodicity in a turbulent boundary layer induced by highly ordered and directional surface roughness [J]. International Journal of Heat and Fluid Flow, 2013, 41: 90-102

[9]	DeanB, BhushanB. The effect of riblets in rectangular duct flow [J]. Applied Surface Science, 2012, 258(8): 3936-3947

[10]	PeetY, SagautP, CharronY. Pressure loss reduction in hydrogen pipelines by surface restructuring [J]. International Journal of Hydrogen Energy, 2009, 34(21): 8964-8973

[11]	StalioE, NobileE. Direct numerical simulation of heat transfer over riblets [J]. International Journal of Heat and Fluid Flow, 2003, 24(3): 356-371

[12]	DeanB, BhushanB. Shark-skin surfaces for fluid-drag reduction in turbulent flow: A review [J]. Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences, 2010, 368(1929): 4775-4806

[13]	LeeS J, JangY G. Control of flow around a NACA 0012 airfoil with a micro-riblet film [J]. Journal of Fluids and Structures, 2005, 20(5): 659-672

[14]	DenkenaB, KöhlerJ, WangB. Manufacturing of functional riblet structures by profile grinding [J]. CIRP Journal of Manufacturing Science and Technology, 2010, 3(1): 14-26

[15]	GuY-q, ZhaoG, ZhengJ-x, LiZ-y, LiuW-b, MuhammadF K. Experimental and numerical investigation on drag reduction of non-smooth bionic jet surface [J]. Ocean Engineering, 2014, 81: 50-57

[16]	LinC H, YenC H, FerngY M. CFD investigating the flow characteristics in a triangular-pitch rod bundle using Reynolds stress turbulence model [J]. Annals of Nuclear Energy, 2014, 65: 357-364

[17]	EscueA, CuiJ. Comparison of turbulence models in simulating swirling pipe flows [J]. Applied Mathematical Modelling, 2010, 34(10): 2840-2849

[18]	TsukaharaT, MotozawaM, TsurumiD, KawaguchiY. PIV and DNS analyses of viscoelastic turbulent flows behind a rectangular orifice [J]. International Journal of Heat and Fluid Flow, 2013, 41: 66-79

[19]	Martín-AlcántaraA, Sanmiguel-RojasE, Gutiérrez-MontesC, Martínez-BazánC. Drag reduction induced by the addition of a multi-cavity at the base of a bluff body [J]. Journal of Fluids and Structures, 2014, 48: 347-361

[20]	TezdoganT, DemirelY K, KellettP, KhorasanchiM, IncecikA, TuranO. Full-scale unsteady RANS CFD simulations of ship behaviour and performance in head seas due to slow steaming [J]. Ocean Engineering, 2015, 97: 186-206

[21]	GuY-q, MouJ-g, DaiD-s, ZhengS-h, JiangL-f, WuD-h, RenY, LiuF-qing. Characteristics on drag reduction of bionic jet surface based on earthworm’s back orifice jet [J]. Acta Physica Sinica, 2015, 64(2): 024701

[22]	TanH F, KangJ T, WangC G. Study on grooved wall flow under rarefied condition using the lattice Boltzmann method [J]. International Journal of Mechanical Sciences, 2015, 901-5

[23]	El-SamniO A, ChunH H, YoonH S. Drag reduction of turbulent flow over thin rectangular riblets [J]. International Journal of Engineering Science, 2007, 45(2-8): 436-454

[24]	AbdulbariH A, YunusR M, AbdurahmanN H, CharlesA. Going against the flow—A review of non-additive means of drag reduction [J]. Journal of Industrial and Engineering Chemistry, 2013, 19(1): 27-36