A study on flow fields and performance of water wheel turbine using experimental and numerical analyses

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Müller G, Kauppert K. Performance characteristics of water wheels. J Hydraul Res, 2004, 42: 451–460

Jones Z. Domestic electricity generation using waterwheels on moored barge. Dissertation for the Master’s Degree. Edinburgh: Heriot Watt University, 2005

Capecchi D. Over and undershot waterwheels in the 18th Century: Science-technology controversy. Adv Hist Stud, 2013, 02: 131–139

Quaranta E, Revelli R. Performance characteristics, power losses and mechanical power estimation for a breastshot water wheel. Energy, 2015, 87: 315–325

Denny M. The efficiency of overshot and undershot waterwheels. Eur J Phys, 2004, 25: 193–202

Müller G, Denchfield S, Schelmerdine R. Stream wheels for applications in shallow and deep water. In: Proceedings of 32nd IAHR Congress, 2007. 291–100

Nguyen M H, Hoang A D, Yang C J. A parametric study about blade shapes and blade numbers of water wheel type tidal turbine by numerical method. J Korean Soc Marine Environ & Safety, 2016, 22: 296–303

Yelguntwar P, Bhange P, Lilhare Y, et al. Design, fabrication and testing of a waterwheel for power generation in an open channel flow. Intl J Eng and Advanced Tech, 2014, 2: 1–7

Turnock S R, Müller G, Nicholls-Lee R F, et al. Development of a floating tidal energy system suitable for use in shallow water. In: Proceedings of the 7th European Wave and Tidal Energy Conference, 2007. 822–831

Gandhi J R, Jha H, Jha S N, et al. Renewable energy based floating power generator (rivers and canals). Int J Eng Res & Appl, 2016, 6: 49–52

Batten W M J, Weichbrodt F, Müller G, et al. Design and stability of a floating free stream energy converter. In: Proceedings of the 34th World Congress of the International Association for Hydro-Environment Research and Engineering, 2011. 624–630

Sam A A. Water wheel CFD simulation. Dissertation for the Master’s Degree. Lund University, 2010

Nishi Y, Inagaki T, Li Y, et al. Study on an undershot cross-flow water turbine. J Therm Sci, 2014, 23: 239–245

Nishi Y, Inagaki T, Li Y, et al. Research on the flow field of undershot cross-flow water turbines using experiments and numerical analysis. In: Proceedings of IOP Conference Series: Earth and Environmental Science, 2014. 22–31

James A S. Hydrostatic pressure converters for the exploitation of very low head hydropower potential. Dissertation for the Doctoral Degree. Southampton: University of Southampton, 2009

Paudel S, Linton N, Zanke U C E, et al. Experimental investigation on the effect of channel width on flexible rubber blade water wheel performance. Renew Energ, 2013, 52: 1–7

Müller G, Jenkins R, Batten W M J. Potential, performance limits and environmental effects of floating water mills. In: Proceedings of River Flow, 2010. 192–198

Bresse J A C. Water wheels or hydraulic motors. Honolulu: University Press of the Pacific, 2003

Müller G, Kauppert K. Die wasserräder als hydraulische kraftmaschinen. Bautechnik, 2003, 80: 181–189

Mehmood N, Liang Z, Khan J. Diffuser augmented horizontal axis tidal current turbines. Res J Applied Sci Eng & Tech, 2012, 18: 3522–3532

Nguyen M H, Hoang A D, Yang C J. Evaluation of vane tidal turbine’s performance and comparison of efficiency among six-bladed, eight-bladed and twelve-bladed types. In: Proceedings of the 38th KOSME Spring Conference, 2014. 134–135