How to cite this paper
Reihani, A., Ojaghi, A., Derakhshan, S & Beigzadeh, B. (2014). Shaft fatigue life and efficiency improvement of a micro cross flow turbine.Engineering Solid Mechanics, 2(1), 1-14.
Refrences
Banki, D. (1918). NeueWasser turbine, Turbienwesen, Nos 21-24.
Box, G. E., & Behnken, D. W. (1960). Some new three level designs for the study of quantitative variables. Technometrics, 2(4), 455-475.
Budynas, R. G., & Nisbett, J. K. (2008). Shigley & apos; s mechanical engineering design. New York: McGraw-Hill.
Castilla, R., Gamez-Montero, P. J., Ertürk, N., Vernet, A., Coussirat, M., & Codina, E. (2010). Numerical simulation of turbulent flow in the suction chamber of a gear pump using deforming mesh and mesh replacement. International Journal of Mechanical Sciences, 52(10), 1334-1342.
Choi, Y. D., Lim, J. I., Kim, Y. T., & Lee, Y. H. (2008). Performance and internal flow characteristics of a cross-flow hydro turbine by the shapes of nozzle and runner blade. Journal of Fluid Science and Technology, 3(3), 398-409.
Costa Pereira, N. H., & Borges, J. E. (1996). Study of the nozzle flow in a cross-flow turbine. International journal of mechanical sciences, 38(3), 283-302.
Demeulenaere, A., Ligout, A., & Hirsch, C. (2004). Application of multipoint optimization to the design of turbomachinery blades. ASME.
Derakhshan, S., Mohammadi, B., & Nourbakhsh, A. (2008). Incomplete sensitivities for 3D radial turbomachinery blade optimization. Computers & Fluids, 37(10), 1354-1363.
Derakhshan, S., & Nourbakhsh, A. (2008). Experimental study of characteristic curves of centrifugal pumps working as turbines in different specific speeds. Experimental thermal and fluid science, 32(3), 800-807.
Derakhshan, S., Pourmahdavi, M., Abdolahnejad, E., Reihani, A., & Ojaghi, A. (2013). Numerical Shape Optimization of a Centrifugal Pump Impeller Using Artificial Bee Colony Algorithm. Computers & Fluids.
Desai, V. R., & Aziz, N. M. (1994). An experimental investigation of cross-flow turbine efficiency. Journal of Fluids Engineering; (United States), 116(3).
Fiuzat, A. A., & Akerkar, B. P. (1991). Power outputs of two stages of cross-flow turbine. Journal of Energy Engineering, 117(2), 57-70.
Fiuzat, A. A., & Akerkar, B. (1989, August).The use of interior guide tube in cross flow turbines. In Waterpower’89 (pp. 1111-1119). ASCE.
Furukawa, A., Okuma, K. (1995). Extra-low head hydro power utilization with Darrieus type runner, Turbomachiney, 30, 142–146.
Hirt, C. W., & Nichols, B. D. (1981).Volume of fluid (VOF) method for the dynamics of free boundaries. Journal of computational physics, 39(1), 201-225.
Inagaki, A., & Kanemoto, T. (2005). Development of Gyro-Type Hydraulic Turbine Suitable for Shallow Stream (2nd Report, Flow Conditions and Rotor Works). Nippon Kikai Gakkai Ronbunshu B Hen (Transactions of the Japan Society of Mechanical Engineers Part B)(Japan), 17(4), 1092-1098.
Kanemoto, T., Furukawa, A., Ikeda, T., & Iio, S. (2007). Research and development on hydroelectric units for micro-hydro power utilization. In Proceedings of the 2007 small hydropower/ocean energy international co-seminar and sixth hydropower technical association seminar (pp. 3-7).
Kanemoto, T., Inagaki, A., Misumi, H., & Kinoshita, H. (2004). Development of gyro-type hydraulic turbine suitable for shallow stream (1st report, rotor works and hydroelectric power generation). Nippon Kikai GakkaiRonbunshu B Hen (Transactions of the Japan Society of Mechanical Engineers Part B) (Japan), 16(2), 413-418.
Khosrowpanah, S., Fiuzat, A. A., & Albertson, M. L. (1988). Experimental study of cross-flow turbine. Journal of Hydraulic Engineering, 114(3), 299-314.
Kosnik, L. (2008). The potential of water power in the fight against global warming in the US. Energy Policy, 36(9), 3252-3265.
Lal, J. (1961). Hydraulic machines. Metropolitan Book Company.
Matsuura, K., Okuma, K., Watanabe, S., & Furukawa, A. (2006). Operation characteristics of ducted Darrieus turbine for extra-low head hydropower. Proceedings of renewable energy, CD-ROM ON-4-5, 2732-4.
Munson, B. R., Young, D. F., & Okiishi, T. H. (1990). Fundamentals of fluid mechanics. New York.
Nakajima, M., Iio, S., & Ikeda, T. (2008). Performance of double-step Savonius rotor for environmentally friendly hydraulic turbine, Journal of Fluid Science and Technology, 3, 410–419.
Nakajima, M., Iio, S., & Ikeda, T. (2008). Performance of Savonius rotor for environmentally friendly hydraulic turbine. Journal of Fluid Science and Technology, 3(3), 420-429.
Nechleba, M. (1980). Hydraulic turbine-design and equipment, ARTIA Prague.
Nourbakhsh, A., Safikhani, H., & Derakhshan, S. (2011). The comparison of multi-objective particle swarm optimization and NSGA II algorithm: applications in centrifugal pumps. Engineering Optimization, 43(10), 1095-1113.
Pasandideh Pour, M. (2012).Numerical simulation of Cross-Flow turbine, M.Sc. thesis, Iran University of Science and Technology.
Penche, C. (1994). Layman & apos; s Guidebook on how to Develop a Small Hydropower Site, Commission of the European Communities.
Phommachamh, D., Kurokawa, J., Choi, Y. D., Nakajima, N., & Motohashi, T. (2006). Development and performances of a micro positive displacement hydropower turbine. Turbomachinery, 34(10), 621-11.
Shepherd, D. G. (1956). Principles of turbomachinery. Macmillan.
Speziale, C. G., & Thangam, S. (1992). Analysis of an RNG based turbulence model for separated flows. International Journal of Engineering Science, 30(10), 1379-IN4.
Takamatsu, Y., Furukawa, A., Okuma, K., & Takenouchi, K. (1991). Experimental studies on a preferable blade profile for high efficiency and the blade characteristics of Darrieus-type cross-flow water turbines. JSME international journal. Ser. 2, Fluids engineering, heat transfer, power, combustion, thermophysical properties, 34(2), 149-156.
Thévenin, D., & Janiga, G. (Eds.).(2008). Optimization and computational fluid dynamics. Springer.
Yakhot, V., Orszag, S. A., Thangam, S., Gatski, T. B., & Speziale, C. G. (1992). Development of turbulence models for shear flows by a double expansion technique. Physics of Fluids A: Fluid Dynamics, 4, 1510.
Yassi, Y. (2010). Improvement of the efficiency of the Agnew micro hydro turbine at part loads due to installing guide vanes mechanism. Energy Conversion and Management, 51(10), 1970-1975.
Yassi, Y. (2009). The effects of improvement of the main shaft on the operating conditions of the Agnew turbine. Energy Conversion and Management, 50(10), 2486-2494.
Box, G. E., & Behnken, D. W. (1960). Some new three level designs for the study of quantitative variables. Technometrics, 2(4), 455-475.
Budynas, R. G., & Nisbett, J. K. (2008). Shigley & apos; s mechanical engineering design. New York: McGraw-Hill.
Castilla, R., Gamez-Montero, P. J., Ertürk, N., Vernet, A., Coussirat, M., & Codina, E. (2010). Numerical simulation of turbulent flow in the suction chamber of a gear pump using deforming mesh and mesh replacement. International Journal of Mechanical Sciences, 52(10), 1334-1342.
Choi, Y. D., Lim, J. I., Kim, Y. T., & Lee, Y. H. (2008). Performance and internal flow characteristics of a cross-flow hydro turbine by the shapes of nozzle and runner blade. Journal of Fluid Science and Technology, 3(3), 398-409.
Costa Pereira, N. H., & Borges, J. E. (1996). Study of the nozzle flow in a cross-flow turbine. International journal of mechanical sciences, 38(3), 283-302.
Demeulenaere, A., Ligout, A., & Hirsch, C. (2004). Application of multipoint optimization to the design of turbomachinery blades. ASME.
Derakhshan, S., Mohammadi, B., & Nourbakhsh, A. (2008). Incomplete sensitivities for 3D radial turbomachinery blade optimization. Computers & Fluids, 37(10), 1354-1363.
Derakhshan, S., & Nourbakhsh, A. (2008). Experimental study of characteristic curves of centrifugal pumps working as turbines in different specific speeds. Experimental thermal and fluid science, 32(3), 800-807.
Derakhshan, S., Pourmahdavi, M., Abdolahnejad, E., Reihani, A., & Ojaghi, A. (2013). Numerical Shape Optimization of a Centrifugal Pump Impeller Using Artificial Bee Colony Algorithm. Computers & Fluids.
Desai, V. R., & Aziz, N. M. (1994). An experimental investigation of cross-flow turbine efficiency. Journal of Fluids Engineering; (United States), 116(3).
Fiuzat, A. A., & Akerkar, B. P. (1991). Power outputs of two stages of cross-flow turbine. Journal of Energy Engineering, 117(2), 57-70.
Fiuzat, A. A., & Akerkar, B. (1989, August).The use of interior guide tube in cross flow turbines. In Waterpower’89 (pp. 1111-1119). ASCE.
Furukawa, A., Okuma, K. (1995). Extra-low head hydro power utilization with Darrieus type runner, Turbomachiney, 30, 142–146.
Hirt, C. W., & Nichols, B. D. (1981).Volume of fluid (VOF) method for the dynamics of free boundaries. Journal of computational physics, 39(1), 201-225.
Inagaki, A., & Kanemoto, T. (2005). Development of Gyro-Type Hydraulic Turbine Suitable for Shallow Stream (2nd Report, Flow Conditions and Rotor Works). Nippon Kikai Gakkai Ronbunshu B Hen (Transactions of the Japan Society of Mechanical Engineers Part B)(Japan), 17(4), 1092-1098.
Kanemoto, T., Furukawa, A., Ikeda, T., & Iio, S. (2007). Research and development on hydroelectric units for micro-hydro power utilization. In Proceedings of the 2007 small hydropower/ocean energy international co-seminar and sixth hydropower technical association seminar (pp. 3-7).
Kanemoto, T., Inagaki, A., Misumi, H., & Kinoshita, H. (2004). Development of gyro-type hydraulic turbine suitable for shallow stream (1st report, rotor works and hydroelectric power generation). Nippon Kikai GakkaiRonbunshu B Hen (Transactions of the Japan Society of Mechanical Engineers Part B) (Japan), 16(2), 413-418.
Khosrowpanah, S., Fiuzat, A. A., & Albertson, M. L. (1988). Experimental study of cross-flow turbine. Journal of Hydraulic Engineering, 114(3), 299-314.
Kosnik, L. (2008). The potential of water power in the fight against global warming in the US. Energy Policy, 36(9), 3252-3265.
Lal, J. (1961). Hydraulic machines. Metropolitan Book Company.
Matsuura, K., Okuma, K., Watanabe, S., & Furukawa, A. (2006). Operation characteristics of ducted Darrieus turbine for extra-low head hydropower. Proceedings of renewable energy, CD-ROM ON-4-5, 2732-4.
Munson, B. R., Young, D. F., & Okiishi, T. H. (1990). Fundamentals of fluid mechanics. New York.
Nakajima, M., Iio, S., & Ikeda, T. (2008). Performance of double-step Savonius rotor for environmentally friendly hydraulic turbine, Journal of Fluid Science and Technology, 3, 410–419.
Nakajima, M., Iio, S., & Ikeda, T. (2008). Performance of Savonius rotor for environmentally friendly hydraulic turbine. Journal of Fluid Science and Technology, 3(3), 420-429.
Nechleba, M. (1980). Hydraulic turbine-design and equipment, ARTIA Prague.
Nourbakhsh, A., Safikhani, H., & Derakhshan, S. (2011). The comparison of multi-objective particle swarm optimization and NSGA II algorithm: applications in centrifugal pumps. Engineering Optimization, 43(10), 1095-1113.
Pasandideh Pour, M. (2012).Numerical simulation of Cross-Flow turbine, M.Sc. thesis, Iran University of Science and Technology.
Penche, C. (1994). Layman & apos; s Guidebook on how to Develop a Small Hydropower Site, Commission of the European Communities.
Phommachamh, D., Kurokawa, J., Choi, Y. D., Nakajima, N., & Motohashi, T. (2006). Development and performances of a micro positive displacement hydropower turbine. Turbomachinery, 34(10), 621-11.
Shepherd, D. G. (1956). Principles of turbomachinery. Macmillan.
Speziale, C. G., & Thangam, S. (1992). Analysis of an RNG based turbulence model for separated flows. International Journal of Engineering Science, 30(10), 1379-IN4.
Takamatsu, Y., Furukawa, A., Okuma, K., & Takenouchi, K. (1991). Experimental studies on a preferable blade profile for high efficiency and the blade characteristics of Darrieus-type cross-flow water turbines. JSME international journal. Ser. 2, Fluids engineering, heat transfer, power, combustion, thermophysical properties, 34(2), 149-156.
Thévenin, D., & Janiga, G. (Eds.).(2008). Optimization and computational fluid dynamics. Springer.
Yakhot, V., Orszag, S. A., Thangam, S., Gatski, T. B., & Speziale, C. G. (1992). Development of turbulence models for shear flows by a double expansion technique. Physics of Fluids A: Fluid Dynamics, 4, 1510.
Yassi, Y. (2010). Improvement of the efficiency of the Agnew micro hydro turbine at part loads due to installing guide vanes mechanism. Energy Conversion and Management, 51(10), 1970-1975.
Yassi, Y. (2009). The effects of improvement of the main shaft on the operating conditions of the Agnew turbine. Energy Conversion and Management, 50(10), 2486-2494.