UFR 2-15 References: Difference between revisions
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# <div id="23"> '''Le, T., Matsumoto, M., Shirato H.''', 2009. Spanwise coherent structure of wind turbulence and induced pressure on rectangular cylinders. Wind & Structures 2(5), 441 – 455.</div> | # <div id="23"> '''Le, T., Matsumoto, M., Shirato H.''', 2009. Spanwise coherent structure of wind turbulence and induced pressure on rectangular cylinders. Wind & Structures 2(5), 441 – 455.</div> | ||
# <div id="24"> '''Lyn, D.A., Einav, S., Rodi, W., Park, J.H.''', 1995. A laser-Doppler velocimetry study of ensemble-averaged characteristics of the turbulent wake of a square cylinder. Journal of Fluid Mechanics 304, 285 – 319.</div> | # <div id="24"> '''Lyn, D.A., Einav, S., Rodi, W., Park, J.H.''', 1995. A laser-Doppler velocimetry study of ensemble-averaged characteristics of the turbulent wake of a square cylinder. Journal of Fluid Mechanics 304, 285 – 319.</div> | ||
# <div id="25"> '''Mannini, C., Weinman, K., | # <div id="25"> '''Mannini, C., Weinman, K., Šoda, A., Schewe, G.''', 2009. Three-dimensional numerical simulation of flow around a 1:5 rectangular cylinder. In: Proceedings of EACWE 5, Florence, Italy.</div> | ||
\bibitem[{Mannini et~al.(2010)}]{mannini2010} | \bibitem[{Mannini et~al.(2010)}]{mannini2010} |
Revision as of 10:05, 11 March 2014
Benchmark on the Aerodynamics of a Rectangular 5:1 Cylinder (BARC)
Flows Around Bodies
Underlying Flow Regime 2-15
References
- Arslan, T., Pettersen B., Andersson H.I., 2011. Calculations of the flow around rectangular shaped floating structures, In: Proceedings of the thirteenth International Conference on Wind Engineering, Amsterdam, The Netherlands.
- Bartoli, G., Bruno, L., Buresti, G., Ricciarelli, F., Salvetti, M.V., Zasso, A., 2008a. BARC Overview Document. http://www.aniv-iawe.org/barc.
- Bartoli, G., Bruno, L., Buresti, G., Ricciarelli, F., Salvetti, M.V., Zasso, A., 2008b. Requests for Computational Simulations. http://www.aniv-iawe.org/barc.
- Bartoli, G., Bruno, L., Buresti, G., Ricciarelli, F., Salvetti, M.V., Zasso, A., 2008c. Requests for Wind Tunnel Tests. http://www.aniv-iawe.org/barc.
- Bartoli, G., Borsani, A., Mannini, C., Marra, A.M., Procino, L., Ricciardelli, F., 2011. Wind tunnel study on the aerodynamics of a 5:1 rectangular cylinder in smooth flow, In: Proceedings of the thirteenth International Conference on Wind Engineering, Amsterdam, The Netherlands.
- Bearman, P.W., 1969. On vortex shedding from a circular cylinder in the critical Reynolds number regime. Journal of Fluid Mechanics 37, 577 – 585.
- Bronkhorst, A.J., Geurts, C.P.W., van Bentum, C.A., 2011. Unsteady pressure measurements on a 5:1 rectangular cylinder, In: Proceedings of the thirteenth International Conference on Wind Engineering, Amsterdam, The Netherlands.
- Bruno, L., Fransos, D., Coste, N., Bosco, A., 2010. 3D flow around a rectangular cylinder: a computational study. Journal of Wind Engineering and Industrial Aerodynamics 98, 263 – 276.
- Bruno, L., Fransos, D., 2011. Probabilistic evaluation of the aerodynamic properties of a bridge deck. Journal of Wind Engineering and Industrial Aerodynamics 99, 718 – 728.
- Bruno, L., Coste, N., Fransos, D., 2011. Effect of the spanwise features of the computational domain on the simulated flow around a rectangular 5:1 cylinder, In: Proceedings of the thirteenth International Conference on Wind Engineering, Amsterdam, The Netherlands.
- Bruno, L., Coste, N., Fransos, D., 2012. Simulated flow around a rectangular 5:1 cylinder: Spanwise discretisation effects and emerging flow features. Journal of Wind Engineering and Industrial Aerodynamics 104 – 106, 203 – 215.
- Bruno, L., Salvetti, M.V., Ricciardelli, F., 2014. Benchmark on the Aerodynamics of a Rectangular 5:1 Cylinder: an overview after the first four years of activity. Journal of Wind Engineering and Industrial Aerodynamics, in press (DOI: 10.1016/j.jweia.2014.01.005)
- Carassale, L., 2008. Flow-induced actions on cylinders in statistically-symmetric cross flow. Probabilistic Engineering Mechanics 24(3), 323 – 339.
- De Grenet, E.T., Ricciardelli, F., 2005. The span-wise correlation of aerodynamic forces on a rectangular cylinder for different vibration regimes. In: Proceedings of the 6th European Conference on Structural Dynamics Eurodyn 2005, Paris, France.
- Ercoftac test case LES2, Ercoftac database case 43. http://ercoftac.mech.surrey.ac.uk/LESig/les2/homepage.html
- Ercoftac QNET-CFD Knowledge Base Wiki, Underlying Flow Regime UFR2-02
- Grozescu, A.N., Salvetti, M.V., Camarri, S., Buresti, G., 2011. Variational multiscale large-eddy simulations of the BARC flow configuration. In: Proceedings of the thirteenth International Conference on Wind Engineering, Amsterdam, The Netherlands.
- Grozescu, A.N., Bruno, L., Fransos, D., Salvetti, M.V., 2011. Large-eddy simulations of of a Benchmark on the Aerodynamics of a Rectangular 5:1 Cylinder. In: Proceedings of the 20th Italian Conference on Theoretical and Applied Mechanics, Bologna, Italy.
- Han F.L., Kareem A., 2009. Anatomy of Turbulence Effects on the Aerodynamics of an Oscillating Prism. Journal of Engineering Mechanics, ASCE, 135, 987 – 999.
- Han X., Pierre Sagaut P., Lucor D., 2012. On sensitivity of RANS simulations to uncertain turbulent inflow conditions. Computers & Fluids 61, 2 – 5.
- Hourigan, K., Thompson, M. C., Tan, B. T., 2001. Self-sustained oscillations in flows around long blunt plates. Journal Fluid and Structures 15, 387 398.
- Knisely, C.W., 1990. Strouhal numbers of rectangular cylinders at incidence: a review and new data. Journal of Fluids and Structures 4(4), 371 – 393.
- Le, T., Matsumoto, M., Shirato H., 2009. Spanwise coherent structure of wind turbulence and induced pressure on rectangular cylinders. Wind & Structures 2(5), 441 – 455.
- Lyn, D.A., Einav, S., Rodi, W., Park, J.H., 1995. A laser-Doppler velocimetry study of ensemble-averaged characteristics of the turbulent wake of a square cylinder. Journal of Fluid Mechanics 304, 285 – 319.
- Mannini, C., Weinman, K., Šoda, A., Schewe, G., 2009. Three-dimensional numerical simulation of flow around a 1:5 rectangular cylinder. In: Proceedings of EACWE 5, Florence, Italy.
\bibitem[{Mannini et~al.(2010)}]{mannini2010} Mannini, C., \v{S}oda, A., Schewe, G., 2010. Unsteady RANS modelling of flow past a rectangular cylinder: Investigation of Reynolds number effects. Computational Fluids 39(9), 1609--1624.
\bibitem[{Mannini et~al.(2011)}]{mannini2011} Mannini, C., \v{S}oda, A., Schewe, G., 2011. Numerical investigation on the three-dimensional unsteady flow past a 5:1 rectangular cylinder. Journal of Wind Engineering and Industrial Aerodynamics 99, 469--482.
\bibitem[{Mannini and Schewe(2011)}]{mannini_sch_2011} Mannini, Schewe, G., 2011. Numerical study on the three-dimensional unsteady flow past a 5:1 rectangular cylinder using the DES approach, In: Proceedings of the thirteenth International Conference on Wind Engineering, Amsterdam, The Netherlands.
\bibitem[{Matsumoto et~al.(2003)}]{matsumoto} Matsumoto, M., Shirato, H., Aaraki, K., Haramura, T., Hashimoto, T., 2003. Spanwise coherence characteristic of surface pressure field on 2D bluff bodies. Journal of Wind Engineering and Industrial Aerodynamics 91, 155--163.
\bibitem[{Matsumoto et~al.(2008)}]{matsumoto2008} Matsumoto, M., Yagi, T., Hashimoto, M., Nakase, T., Maeta, K., Hori, K., Kawasima, Y., 2008. Steady Galloping /Unsteady Galloping and Vortex-induced Vibration of Bluff Bodies associated with Mitigation of Karman Vortex Shedding. In: Proceedings of the 6th International Colloquium on Bluff Body Aerodynamics and Applications, Milan, Italy.
\bibitem[{McLean and Gartshore(1992)}]{McLean1992} McLean, I., Gartshore, I., 1992. Spanwise correlations of pressure on a rigid
square section cylinder. Journal of Wind Engineering and Industrial Aerodynamics 41, 797--808.
%\bibitem[{Murakami and Mochida(1995)}]{murakami1995} %Murakami, S., Mochida, A., 1995. On turbulent vortex shedding flow past a square cylinder %predicted by CFD.Journal of Wind Engineering and Industrial Aerodynamics 54, 191--211.
\bibitem{nakaguchi1968} Nakaguchi, H., Hashimoto, K., Muto, S., 1968. An experimental study on aerodynamic drag of rectangular cylinders. Journal of the Japan Society of Aeronautical and Space Sciences 16, 1--5
\bibitem[{Nakamura and Mizota(1975)}]{nakamura1975} Nakamura, Y., Mizota, T., 1975. Torsional flutter of rectangular prisms. Journal of the Engineering Mechanics Division 101(EM2), 125-142.
\bibitem[{Nakamura and Yoshimura(1982)}]{nakamura1982} Nakamura, Y., Yoshimura, T., 1982. Flutter and vortex excitation of rectangular prisms in pure torsion in smooth and turbulent flows. Journal of Sound and Vibration 84(3), 305--317.
\bibitem[{Nakamura and Nakshima(1986)}]{nakamura1986} Nakamura, Y., Nakashima, M., 1986. Vortex excitation of prisms with elongated rectangular, H and |- cross-sections. Journal of Fluid Mechanics 163, 149--169.
\bibitem[{Nakamura et~al.(1991)}]{nakamura1991} Nakamura, Y., Ohya, Y., Tsuruta, H., 1991. Experiments on vortex shedding from flat plates with square leading and trailing edges. Journal of Fluid Mechanics 222, 437--447.
\bibitem[{Nakamura et~al.(1996)}]{nakamura1996} Nakamura, Y., Ohya, Y., Ozono, S., Nakamaya, R., 1996. Experimental and numerical analysis of vortex shedding from elongated rectangular cylinders at low Reynolds numbers 200-1000. Journal of Wind Engineering and Industrial Aerodynamics 65, 301--308.
\bibitem[{Namiranian and Gartshore(1988)}]{Namiranian1988} Namiranian, F., Gartshore, I., 1988. Direct measurements of oscillating lift on
a rigid square section cylinder in a turbulent stream. Journal of Wind Engineering and Industrial Aerodynamics 28, 209--218.
\bibitem[{Ohya et~al.(1992)}]{ohya1992} Ohya, Y., Nakamura, Y., Ozono, S., Nakamaya, R., 1992. A numerical study of vortex shedding from flat plates with square lading and trailing edges. Journal of Fluid Mechanics 236, 445--460.
\bibitem[{Oka and Ishihara(2009)}]{oka2009} Oka, S., Ishihara, T., 2009. Numerical study of aerodynamic characteristics of a square prism in a uniform flow, Journal of Wind Engineering and Industrial Aerodynamics 97, 548--559.
\bibitem[{Okajima(1982)}]{okajima1982} Okajima, A., 1982. Strouhal numbers of rectangular cylinders. Journal of Fluid Mechanics 123, 379--398.
\bibitem[{Okajima et~al. (1983)}]{okajima1983} Okajima, A., Sugitani, K., Mizota, T., 1983. Strouhal Number and Base Pressure Coefficient of Rectangular Cylinders : The Case of a Section of a Width/Height Ratio of 1-9. Transactions of the Japan Society of Mechanical Engineers Series B, 49(447), 2551--2558.
\bibitem[{Parker and Welsh(1983)}]{parker1983} Parker, R., Welsh, M.C., 1983. Effects of sound on flow separation from blunt flat plates. International Journal of Heat and Fluid Flow 4(2), 113--127.
%\bibitem[{Pope(2000)}]{pope} %Pope, S.B., 2000. Turbulent Flows, Cambridge University Press.
{ \bibitem[{Posdziech and Grundmann(2007)}]{Posdziech2007} Posdziech, O., Grundmann, R., 2007. A systematic approach to the numerical calculation of fundamental quantities of the two-dimensional flow over a circular cylinder. Journal of Fluids and Structures 23, 479--499.
\bibitem[{Qu et al.(2013)}]{Qu2013} Qu, L., Norberg, C., Davidson, L., Peng, S.H., Wang, F., 2013. Quantitative numerical analysis of flow past a circular cylinder at Reynolds number between 50 and 200. Journal of Fluids and Structures 39, 347--370. }
\bibitem[{Ribeiro(2011)}]{ribeiro2011} Ribeiro, A.F.P., 2011. Unsteady RANS modelling of flow past a rectangular 5:1 cylinder: investigation of edge sharpness effects, In: Proceedings of the thirteenth International Conference on Wind Engineering, Amsterdam, The Netherlands.
\bibitem[{Ricciardelli and Marra(2008)}]{ricciardelli2008} Ricciardelli, F., Marra, A.M., 2008. Sectional aerodynamic forces and their longitudinal correlation on a vibrating 5:1 rectangular cylinder. In: Proceedings of the 6th International Colloquium on Bluff Body Aerodynamics and Applications, Milan, Italy.
\bibitem[{Ricciardelli(2010)}]{ricciardelli2010} Ricciardelli, F., 2010. Effects of the vibration regime on the spanwise correlation of the aerodynamic forces on a 5:1 rectangular cylinder, Journal of Wind Engineering and Industrial Aerodynamics 98, 215--225.
\bibitem[{Rodi (1997)}]{rodi1997} Rodi, W., 1997. Comparison of LES and RANS calculations of the flow around bluff bodies, Journal of Wind Engineering and Industrial Aerodynamics 69--71, 55--75.
%\bibitem[{Rodi et~al.(1995)}]{rodi1995} %Rodi, W., Ferziger, J.H., Breuer M., Pourquie,M., 1995. Proceedings of the Workshop on Large-Eddy Simulation of Flows past Bluff Bodies, Rottach-Egern, Germany. % \bibitem[{Rodi(2002)}]{rodi2002} Rodi, W., 2002. Large-Eddy Simulations of the Flow Past Bluff Bodies. In: Launder, B.E., Sandham, N.D. (Eds.), Closure strategies for turbulent and transitional flows. Cambridge University Press, 361-391.
%\bibitem[{Rung et~al.(1999)}]{Rung1999} %Rung, T., Lubcke, H., Franke, M., Xue, L., Thiele, F. and Fu, S., 1995. Assessment of explicit algebraic %stress models in transonic flows. Proceedings 4th International Symposium on Engineering Turbulence Modelling and Experiments, Ajaccio, France, 659 - 668.
\bibitem[{Schewe(1983)}]{schewe1983} Schewe, G., 1983. On the Force Fluctuations Acting on a Circular Cylinder in Cross Flow From Subcritical up to Transcritical Reynolds Numbers, Journal of Fluid Mechanics 153, 265--285.
\bibitem[{Schewe(1989)}]{schewe1989} Schewe, G. 1989. Nonlinear Flow induced Resonances of an H shaped Section. Journal of Fluids and Structures 3, 327--348.
\bibitem[{Schewe(2006)}]{schewe2006} Schewe, G., 2006. Influence of the Reynolds-number on flow-induced vibrations of generic bridge sections. In:Radi$\breve{c}$ J. (Ed.), Proceedings of the International Conference on Bridges, Dubrovnik, Croatia, 351358.
\bibitem[{Schewe(2009)}]{schewe2009} Schewe, G., 2009. Reynolds-number-effects in flow around a rectangular cylinder with aspect ratio1:5. In: Proceedings of the Fifth European and African Conference on Wind Engineering, Florence, Italy.
\bibitem[{Shimada and Ishihara(2002)}]{shimada} Shimada, K. Ishihara, T., 2002. Application of a modified $k-\varepsilon$ model to the prediction of aerodynamic characteristics of rectangular cross-section cylinders. Journal of Fluids and Structures 16 (4), 465-485.
\bibitem[{Shirato et~al.(2010)}]{shirato2010} Shirato, H., Yuichi, S., Sasaki, O., Van Baod, D., 2010. Coherent structure of surface pressures on 2-D rectangular cylinders, In: Proceedings of the fifth International Symposium on Computational Wind Engineering, Chapel Hill, North Carolina, USA.
\bibitem[{Shirato et~al.(2011)}]{shirato} Shirato, H., Yuichi, S., Sasaki, O., 2011. Surface pressure correlation and buffeting force evaluation, In: Proceedings of the thirteenth International Conference on Wind Engineering, Amsterdam, The Netherlands.
%\bibitem[{Smagorinsky(1963)}]{smag} %%Smagorinsky, J., 1963. General circulation experiments with the primitive equations. I. The basic experiment. %Monthly Weather Review 91, 99--164.
\bibitem[{Spalart and Allmaras(1992)}]{Spalart1992} Spalart, P.R. and Allmaras, S.R., 1992. A one-equation turbulence model for aerodynamic flows. Proceedings of 30th AIAA Aerospace Sciences Meeting and Exhibit, Reno (NV), USA, 92.
\bibitem[{Spalart et al.(1997)}]{Spalart1997} Spalart, P.R., Jou, W.-H., Stretlets, M. and Allmaras, S.R, 1997. Comments on the Feasibility of LES for Wings and on the Hybrid RANS/LES Approach. Proceedings of the First AFOSR International Conference on DNS/LES, Ruston, Louisiana, USA.
\bibitem[{Stokes and Welsh(1986)}]{stokes1986} Stokes, A.N., Welsh, M.C., 1986. Flow-resonant sound interaction in a duct containing a plate, II:square leading edge. Journal of Sound and Vibration 104(1), 55-73.
\bibitem[{Tamura et~al.(1993)}]{tamura1993} Tamura, T., Ito, Y., Kuwahara, K., 1993. Computational separated-reattaching flows around a rectangular cylinder, Journal of Wind Engineering and Industrial Aerodynamics 50, 9--18.
\bibitem[{Tamura et~al.(1995)}]{tamura1995} Tamura, T., Ito, Y., Wada, A., Kuwahara, K., 1995. Numerical study of pressure fluctuations on a rectangular cylinder in aerodynamic oscillations, Journal of Wind Engineering and Industrial Aerodynamics 54/55, 239--250.
\bibitem[{Tamura and Ito(1996)}]{tamura1996} Tamura, T., Ito, Y., 1996. Aerodynamic characteristics and flow structures around a rectangular cylinder with a section of various depth/breadth ratios. Journal of Structural and Construction Engineering 486, 153-162 (in Japanese).
\bibitem[{Tamura et~al.(1998)Tamura, Miyagi, and Kitagishi}]{tamura1998} Tamura, T., Miyagi, T., Kitagishi, T., 1998. Numerical prediction of unsteady pressures on a square cylinder with various corner shapes. Journal of Wind Engineering and Industrial Aerodynamics 74-76, 531--542.
\bibitem[{Tan et~al.(2004)}]{tan2004} Tan, B.T., Thompson, M.C., Hourigan, F., 2004. Flow past rectangular cylinders: receptivity to transverse forcing. Journal of Fluid Mechanics 515, 33--62.
\bibitem[{Travin et~al.(1999)Travin, Shur, Strelets, and Spalart}]{travin1999} Travin, A.K., Shur, M.L., Strelets, M.Kh., Spalart, P.R., 1999. Detached-eddy simulations past a circular cylinder. Flow Turbulence and Combustion 63(14), 293--313.
\bibitem[{Vickery(1966)}]{vickery} Vickery, B.J., 1996. Fluctuating lift and drag on a long cylinder of square cross-section in a smooth and in a turbulent stream. Journal of Fluid Mechanics 25, 481--494.
\bibitem[{Voke(1997)}]{voke1997} Voke, P.R., 1997. Flow past a square cylinder: test LES2, In: Direct and Large- Eddy Simulation II, J.P. Chollet et al. (eds.), ERCOFTAC Series, vol. 5, Kluwer Academic Publishers, 355--373.
{ \bibitem[{Yu et~al.(2013)}]{yu_2013} Yu, D., Butler K., Kareem, A., Glimm J., Sun J., 2013. Simulation of the Influence of Aspect ratios on the Aerodynamics of rectangular Prisms. Journal of Engineering Mechanics, ASCE, 139, 429--438. }
\bibitem[{Yu and Kareem(1998)}]{yu2} Yu, D., Kareem, A., 1998. Parametric study of flow around rectangular prisms using LES. Journal of Wind Engineering and Industrial Aerodynamics 77-78, 653--662.
\bibitem[{Wei and Kareem(2011)}]{wei} Wei, Z., Kareem, A., 2011. A benchmark study of flow around a rectangular cylinder with aspect ratio 1:5 at Reynolds number 1.E5, In: Proceedings of the thirteenth International Conference on Wind Engineering, Amsterdam, The Netherlands.
Contributed by: Luca Bruno, Maria Vittoria Salvetti — Politecnico di Torino, Università di Pisa
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