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References
|
Adam JL, Ricot D, Dubief F, Guy C (2008). Aeroacoustic simulation of automotive ventilation outlets. J. Acoust. Soc. Am. 123(5):3250-3250. Crossref |
||||
|
Cavar D, Meyer KE (2011). Investigation of turbulent boundary layer flow over 2D bump using highly resolved lager eddy simulation. J. Fluids Eng. 133:111204. Crossref |
||||
|
Curle N (1955).The influence of solid boundaries upon aerodynamic sound. Proc. R. Soc. London, Ser. A. 231:505–514. Crossref |
||||
|
Dai HL, Wang L, Qian Q, Ni Q (2013). Vortex-Induced Vibrations of Pipes Conveying Fluid in the Subcritical and Supercritical Regimes. J. Fluids Struct. 39:322-334. Crossref |
||||
|
Eguchi Y, Murakami T, Tanaka M, Yamano H (2011). A ï¬nite element LES for high-Re flow in a short-elbow pipe with undisturbed inlet velocity. Nucl. Eng. Des. 241:4368–4378. Crossref |
||||
|
Ji M, Wang M (2010). Sound generation by turbulent boundary-layer flow over small steps. J. Fluid Mech. 654:161-193. Crossref |
||||
|
Jung SY, Chuang YM (2012). Large-Eddy simulation of accelerated turbulent flow in a circular pipe. Int. J. Heat Fluid Flow 33(1):1-8. Crossref |
||||
|
Katrien H, Bauters F (2010). The value of auto-adjustable CPAP devices in pressure titration and treatment of patients with obstructive sleep apnea syndrome. Sleep Med. Rev. 14(2):115-119. Crossref |
||||
|
Kim K, Baek SJ, Sung HJ (2002). An implicit velocity decoupling procedure for the incompressible Navier-Stokes equations. Int. J. Numer. Meth. Fluids 38(2):125-138. Crossref |
||||
|
Kolesnikov YI, Fedin KV, Kargapolov AA, Emanov AF (2012). Instability detection in piping supports by acoustic noise. J. Min. Sci. 48(4):642-648. Crossref |
||||
|
Kuhn S, Kenjereš S, Rudolf von Rohr P (2010). Large Eddy simulations. of wall heat transfer and coherent structures in mixed convection over a wavy wall. Int. J. Therm. Sci. 49(10):1209-1226. Crossref |
||||
|
Lafon P, Caillaud S,Devos JP, Lambert C (2003). Aeroacoustical coupling in a ducted shallow cavity and fluid/structure effects on a steam line. J. Fluids Struct. 18:695–713. Crossref |
||||
|
Lilly DK (1992).A proposed modification of the Germanosubgrid-scale closure method. Phys. Fluids 4(3):633-635. Crossref |
||||
|
Lin SC, Tsai ML (2012). An integrated performance analysis for a backward-inclined centrifugal fan. Comput. Fluids 56:24-38. Crossref |
||||
|
Liu YH, Du GS, Liu ZG, Li L, Tao LL (2010). The profile-linear average velocity for the transition in pipes based on the method of LES. J Hydrodyn. 22(5):366-370. Crossref |
||||
|
Lighthill MJ (1951). On sound generated aerodynamically: Part I. General theory. Proc. R. Soc. London, Ser. A. 211:564–587. Crossref |
||||
|
Martínez-Lera P, Schram C, Bériot H, Hallez R (2014). An approach to aerodynamic sound prediction based on incompressible flow pressure. J. Sound Vib. 333(1):132-143. Crossref |
||||
|
Mcdaid C, Kate HD, Susan CG, Helen LAW, Stradling JR, Robert JOD, Mark JS, Marie EW (2009). A systematic review of continuous positive airway pressure for obstructive sleep apnoea–hypopnoea syndrome. Sleep Med. Rev. 13(6):427-436. Crossref |
||||
|
Moon YJ, Seo JH, Bae YM, Roger M, Becker S (2010). A hybrid prediction method for low-subsonic turbulent flow noise. Comput. Fluids 39(7):1125–1135. Crossref |
||||
|
Pavić G (2003). Acoustical analysis of pipe with flow using invariant filed functions. J. Sound Vib. 263:153–174. Crossref |
||||
|
Park IS, Sohn CH, Lee S, Song HY, Oh JK (2010). Flow-induced noise in a suction nozzle with a centrifugal fan of a vacuum cleaner and its reduction. Appl. Acoust. 71(5):460–469. Crossref |
||||
|
Rütten F, Schröder W, Meinke M (2005). Large-Eddy simulation of low frequency oscillations of the dean vortices in turbulent pipe bendflows. PhysFluids 17:035107. Crossref |
||||
|
Shi L, Zhang CC, Wang J, Ren LQ (2012). Numerical simulation of the effect of bionic serrated structures on the aerodynamic noise of a circular cylinder. J. Bionic Eng. 9(1):91-98. Crossref |
||||
|
Tan L, Zhu BS, Wang YC, Cao SL, Liang KH (2014). Turbulent flow simulation using large eddy simulation combined with characteristic-based split scheme. Comput. Fluids 94:161-172. Crossref |
||||
|
Wang Y, Wang SX, Liu YH, Chen CY (2011). Influence of cavity shape on hydrodynamic noise by a hybrid LES–FW–H method. China Ocean Eng. 25(3):381–394. Crossref |
||||
| Williams JF, Hawkings D (1969). Sound generation by turbulence and surfaces in arbitrary motion. Proc. R. Soc. London, Ser. A. 264:321–342. | ||||
|
Zhang N, Shen HC, Yao HZ (2010). Numerical simulation of cavity flow induced noise by LES and FW–H acoustic analogy. J. Hydrodyn. Ser. B. 22:242–247. Crossref |
||||
|
Zhang YO, Zhang T, Ouyang H, Li TY (2014).Flow-induced noise analysis for 3D trash rack based on LES/Lighthill hybrid method. Appl. Acoust. 79:141–152. Crossref |
||||
|
Zhu JC, Chen H, Chen XD (2013).Large Eddy simulation of vortex shedding and pressure fluctuation in aerostatic bearings. J. Fluid Struct. 40:42-51. Crossref |
||||
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