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Citation:
 Tao Zhang,Yongou Zhang,Huajiang Ouyang and Tao Guo.Flow-induced Noise and Vibration Analysis of aPiping Elbow with/without a Guide Vane[J].Journal of Marine Science and Application,2014,(4):394-401.[doi:10.1007/s11804-014-1271-9]
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Flow-induced Noise and Vibration Analysis of a Piping Elbow with/without a Guide Vane

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Title:
Flow-induced Noise and Vibration Analysis of aPiping Elbow with/without a Guide Vane
Author(s):
Tao Zhang Yong’ou Zhang Huajiang Ouyang and Tao Guo
Affilations:
Author(s):
Tao Zhang Yong’ou Zhang Huajiang Ouyang and Tao Guo
1. School of Naval Architecture and Ocean Engineering, Huazhong University of Science and Technology, Wuhan 430074, China2. Hubei Key Laboratory of Naval Architecture and Ocean Engineering Hydrodynamics, Huazhong University of Science and Technology, Wuhan 430074, China3. School of Engineering, University of Liverpool, Liverpool L69 3GH, UK
Keywords:
: flow-induced noise flow-induced vibration piping elbow guide vane large eddy simulation fluid structure interaction Actran
分类号:
-
DOI:
10.1007/s11804-014-1271-9
Abstract:
The effect of a guide vane installed at the elbow on flow-induced noise and vibration is investigated in the range of Reynolds numbers from 1.70?105 to 6.81?105, and the position of guide vane is determined by publications. The turbulent flow in the piping elbow is simulated with large eddy simulation (LES). Following this, a hybrid method of combining LES and Lighthill’s acoustic analogy theory is used to simulate the hydrodynamic noise and sound sources are solved as volume sources in code Actran. In addition, the flow-induced vibration of the piping elbow is investigated based on a fluid-structure interaction (FSI) code. The LES results indicate that the range of vortex zone in the elbow without the guide vane is larger than the case with the guide vane, and the guide vane is effective in reducing flow-induced noise and vibration in the 90° piping elbow at different Reynolds numbers.

References:

Anwer M, So RMC (1993). Swirling turbulent flow through a curved pipe, I - Effect of swirl and bend curvature. Experiments in Fluids, 14(1-2), 85-96.

Firouz-Abadi RD, Noorian MA, Haddadpour H (2010). A fluid-structure interaction model for stability analysis of shells conveying fluid. Journal of Fluids and Structures, 26, 747-763.
Guo Tao, Zhang Tao, Zhao Wei (2012). Flow-induced vibration analysis of straight pipe based on LES. Engineering Mechanics, 29(10), 340-346. (in Chinese)
Hambric SA, Boger DA, Fahnline JB, Campbell RL (2010). Structure-and fluid-borne acoustic power sources induced by turbulent flow in 90° piping elbows. Journal of Fluids and Structures, 26(1), 121-147.
Ito H (1960). Pressure losses in smooth pipe bends. Trans. ASME Journal of Basic Engineering, 82(1), 131-143.
Liu Jiming, Zhang Tao, Zhang Yongou (2013). Numerical study on flow-induced noise for a steam stop-valve using large eddy simulation. Journal of Marine Science and Application, 12(3), 351-360.
Mao Q, Zhang JH, Luo YS, Wang HJ, Duan Q (2006). Experimental studies of orifice-induced wall pressure fluctuations and pipe vibration. International Journal of Pressure Vessels and Piping, 83(7), 505-511.
Modi PP, Jayanti S (2004). Pressure losses and flow maldistribution in ducts with sharp bends. Chemical Engineering Research and Design, 82(3), 321-331.
Ni Q, Zhang ZL, Wang L (2011). Application of the differential transformation method to vibration analysis of pipes conveying fluid. Applied Mathmatics and Computation, 217(16), 7028-7038.
Ono A, Kimura N, Kamide H, Tobita A (2011). Influence of elbow curvature on flow structure at elbow outlet under high Reynolds number condition. Nuclear Engineering and Design, 241(11), 4409-4419.
Pa?doussis MP (1998). Fluid-structure interactions: slender structures and axial flow. Academic Press, London.
Pittard MT, Evans RP, Maynes RD, Blotter JD (2004). Experimental and numerical investigation of turbulent flow induced pipe vibration in fully developed flow. Review of Scientific Instruments, 75(7), 2393-2401.
Rani HP, Divya T, Sahaya RR, Vivekanand K, Barua DK (2014). Unsteady turbulent flow in 90° bend under the wall thinning degradation environment. Nuclear Engineering and Design, 267, 164-171.
Sakakibara J, Machida N (2012). Measurement of turbulent flow upstream and downstream of a circular pipe bend. Physics of Fluids, 24(4), 041702.
Shiraishi T, Watakabe H, Sago H, Konomura M, Yamaguchi A, Fujii T (2006). Resistance and fluctuating pressures of a large elbow in high Reynolds numbers. Journal of Fluids Engineering, 128(5), 1063-1073.
So RMC, Anwer M (1993). Swirling turbulent flow through a curved pipe. II–Recovery from swirl and bend curvature. Experiments in Fluids, 14(3), 169-177.
Sudo K, Sumida M, Hibara H (2000). Experimental investigation on turbulent flow through a circular-sectioned 180° bend. Experiments in Fluids, 28(1), 51-57.
Sudo K, Sumida M, Hibara H (2001). Experimental investigation on turbulent flow in a square-sectioned 90-degree bend. Experiments in Fluids, 30(3), 246-252.
Takamura H, Aizawa K, Yamano H, Ebara S, Hashizume H (2012). Flow visualization and frequency characteristics of velocity fluctuations of complex turbulent flow in a short elbow piping under high Reynolds number condition. Journal of Fluids Engineering, 134(10), 101201.
Tan L, Zhu B, Wang Y, Cao S, Liang K (2014). Turbulent flow simulation using large eddy simulation combined with characteristic-based split scheme. Computers and Fluids, 94, 161-172.
Wilson SR, Liu Y, Matida EA, Johnson MR (2011). Aerosol deposition measurements as a function of Reynolds number for turbulent flow in a ninety-degree pipe bend. Aerosol Science and Technology, 45(3), 364-375.
Yamano H, Tanaka M, Murakami T, Iwamoto Y, Yuki K, Sago H, Hayakawa S (2011a). Unsteady elbow pipe flow to develop a flow-induced vibration evaluation methodology for Japan Sodium-Cooled Fast Reactor. Journal of Nuclear Science and Technology, 48(4), 677-687.
Yamano H, Tanaka M, Kimura N, Oshima H, Kamide H, Watanabe O (2011b). Development of flow-induced vibration evaluation methodology for large-diameter piping with elbow in Japan sodium-cooled fast reactor. Nuclear Engineering and Design, 241(11), 4464-4475.
Zhang Nan, Shen Hongcui, Yao Huizhi (2010). Numerical simulation of cavity flow induced noise by LES and FW-H acoustic analogy. Journal of Hydrodynamics, Ser. B, 22(5), 242-247.
Zhang YO, Zhang T, Ouyang H, Li TY (2014a). Flow-induced noise analysis for 3D trash rack based on LES/Lighthill hybrid method. Applied Acoustics, 79, 141-152.
Zhang YO, Zhang T, Li TY (2014b). Flow-induced noise simulation based on LES/Lighthill hybrid method. 6th International Conference on Mechanical and Electronics Engineering, Beijing, China.
Zhang CJ, Luo YX, Liang JX, Li LL, Li J (2014c). Flow-induced noise prediction for 90° bend pipe by LES and FW-H hybrid method. Scientific Research and Essays, 9(11), 483-494.

Memo

Memo:
Supported by the Independent Innovation Foundation for National Defense of Huazhong University of Science and Technology (No. 01-18-140019).
Last Update: 2014-12-09