A novel H-shape fishway with excellent hydraulic characteristics

An, R.D., Li, J., Yi, W.M., Mao, X., 2019. Hydraulics and swimming behavior of schizothorax prenanti in vertical slot fishways. J. Hydrodyn., 31, 1, 169–176.10.1007/s42241-019-0009-1 Search in Google Scholar

Bombač, M., Novak, G., Rodič, P., Četina, M., 2014. Numerical and physical model study of a vertical slot fishway. J. Hydrol. Hydromech., 62, 2, 150–159.10.2478/johh-2014-0013 Search in Google Scholar

Bombač, M., Novak, G., Mlačnik, J., Četina, M., 2015. Extensive field measurements of flow in vertical slot fishway as data for validation of numerical simulations. Ecol. Eng., 84, 476–484.10.1016/j.ecoleng.2015.09.030 Search in Google Scholar

Bombač, M., Četina, M., Novak, G., 2017. Study on flow characteristics in vertical slot fishways regarding slot layout optimization. Ecol. Eng., 107, 126–136.10.1016/j.ecoleng.2017.07.008 Search in Google Scholar

Ead, S.A., Katopodis, C., Sikora, G.J., Rajaratnam, N., 2004. Flow regimes and structure in pool and weir fishways. J. Environ. Eng. Sci., 3, 5, 379–390.10.1139/s03-073 Search in Google Scholar

Fuentes-Pérez, J.F., Sanz-Ronda, F.J., Martínez de Azagra Paredes, A., García-Vega, A., 2014. Modeling water-depth distribution in vertical-slot fishways under uniform and nonuniform scenarios. J. Hydraul. Eng., 140, 10, 06014016.10.1061/(ASCE)HY.1943-7900.0000923 Search in Google Scholar

Fuentes-Pérez, J.F., Sanz-Ronda, F.J., de Azagra, A.M., García-Vega, A., 2016. Non-uniform hydraulic behavior of pool-weir fishways: a tool to optimize its design and performance. Ecol. Eng., 86, 5–12.10.1016/j.ecoleng.2015.10.021 Search in Google Scholar

Fuentes-Pérez, J.F., Tuhtan, J.A., Eckert, M., Romão, F., Ferreira, M.T., Kruusmaa, M., Branco, P., 2019. Hydraulics of vertical-slot fishways: Nonuniform profiles. J. Hydraul. Eng., 145, 2, 06018020.10.1061/(ASCE)HY.1943-7900.0001565 Search in Google Scholar

Katopodis, C., Rajaratnam, N., Wu, S., Tovell, D., 1997. Denil fishways of varying geometry. J. Hydraul. Eng., 123, 7, 624–631.10.1061/(ASCE)0733-9429(1997)123:7(624) Search in Google Scholar

Katopodis, C., Williams, J.G., 2012. The development of fish passage research in a historical context. Ecol. Eng., 48, 8–18.10.1016/j.ecoleng.2011.07.004 Search in Google Scholar

Mao, X., Fu, J.J., Tuo, Y.C., An, R.D., Li, J., 2012. Influence of structure on hydraulic characteristics of T shape fishway. J Hydrodyn., 24, 5, 684–691.10.1016/S1001-6058(11)60292-8 Search in Google Scholar

Mao, X., Zhang, J., Tang, K., Zhao, W., 2019. Designs for T shape fishways. Stavební obzor - Civil Engineering Journal, 28, 2, 270–280.10.14311/CEJ.2019.02.0022 Search in Google Scholar

Marriner, B.A., Baki, A.B., Zhu, D.Z., Cooke, S.J., Katopodis, C., 2016. The hydraulics of a vertical slot fishway: a case study on the multi-species Vianney-Legendre fishway in Quebec, Canada. Ecol. Eng., 90, 190–202.10.1016/j.ecoleng.2016.01.032 Search in Google Scholar

Menter, F.R., Kuntz, M., Langtry, R., 2003. Ten years of industrial experience with the SST turbulence model. Turbul. Model. Heat. Mass. Tran., 4, 1, 625–632. Search in Google Scholar

Puertas, J., Cea, L., Bermúdez, M., Pena, L., Rodríguez, Á., Rabunal, J.R., Balairón, L., Lara, Á., Aramburu, E., 2012. Computer application for the analysis and design of vertical slot fishways in accordance with the requirements of the target species. Ecol. Eng., 48, 51–60.10.1016/j.ecoleng.2011.05.009 Search in Google Scholar

Quaranta, E., Katopodis, C., Revelli, R., Comoglio, C., 2017. Turbulent flow field comparison and related suitability for fish passage of a standard and a simplified low gradient vertical slot fishway. River Res. Appl., 33, 8, 1295–1305.10.1002/rra.3193 Search in Google Scholar

Quaresma, A.L., Romão, F., Branco, P., Ferreira, M.T., Pinheiro, A.N., 2018. Multi slot versus single slot pool-type fish-ways: a modelling approach to compare hydrodynamics. Ecol. Eng., 122, 197–206.10.1016/j.ecoleng.2018.08.006 Search in Google Scholar

Quaranta, E., Katopodis, C., Comoglio, C., 2019. Effects of bed slope on the flow field of vertical slot fishways. River Res. Appl., 35, 6, 656–668.10.1002/rra.3428 Search in Google Scholar

Rajaratnam, N., Katopodis, C., 1984. Hydraulics of Denil fish-ways. J. Hydraul. Eng., 110, 9, 1219–1233.10.1061/(ASCE)0733-9429(1984)110:9(1219) Search in Google Scholar

Rajaratnam, N., Katopodis, C., Mainali, A., 1989. Pool-orifice and pool-orifice-weir fishways. Can. J. Civ. Eng., 16, 5, 774–777.10.1139/l89-112 Search in Google Scholar

Rajaratnam, N., Katopodis, C., Solanki, S., 1992. New designs for vertical slot fishways. Can. J. Civ. Eng., 19, 3, 402–414.10.1139/l92-049 Search in Google Scholar

Rodríguez, T.T., Agudo, J.P., Mosquera, L.P., González, E.P., 2006. Evaluating vertical slot fishway designs in terms of fish swimming capabilities. Ecol. Eng., 27, 1, 37–48.10.1016/j.ecoleng.2005.09.015 Search in Google Scholar

Santos, J.M., Silva, A., Katopodis, C., Pinheiro, P., Pinheiro, A., Bochechas, J., Ferreira, M.T., 2012. Ecohydraulics of pool-type fishways: getting past the barriers. Ecol. Eng., 48, 38–50.10.1016/j.ecoleng.2011.03.006 Search in Google Scholar

Tarrade, L., Texier, A., David, L., Larinier, M., 2008. Topologies and measurements of turbulent flow in vertical slot fishways. Hydrobiologia, 609, 1, 177–188.10.1007/s10750-008-9416-y Search in Google Scholar

Yagci, O., 2010. Hydraulic aspects of pool-weir fishways as ecologically friendly water structure. Ecol. Eng., 36, 1, 36–46.10.1016/j.ecoleng.2009.09.007 Search in Google Scholar

Zhang, D., Jiang, C., Liang, D., Chen, Z., Yang, Y., Shi, Y., 2014. A refined volume-of-fluid algorithm for capturing sharp fluid interfaces on arbitrary meshes. J. Comput. Phys., 274, 709–736.10.1016/j.jcp.2014.06.043 Search in Google Scholar

Zhang, D., Jiang, C., Liang, D., Cheng, L., 2015. A review on TVD schemes and a refined flux-limiter for steady-state calculations. J. Comput. Phys., 302, 114–154.10.1016/j.jcp.2015.08.042 Search in Google Scholar

Zhang, D., Cheng, L., An, H., Draper, S., 2021. Flow around a surface-mounted finite circular cylinder completely submerged within the bottom boundary layer. Eur. J. Mech. B Fluids., 86, 169–197.10.1016/j.euromechflu.2020.11.011 Search in Google Scholar