Browse > Article
http://dx.doi.org/10.5293/IJFMS.2016.9.2.182

Effects of load variation on a Kaplan turbine runner  

Amiri, K. (Department of Engineering Science and Mathematics, Division of Fluid and Experimental Mechanics, Lulea University of Technology)
Mulu, B. (Vattenfall Research and Development)
Cervantes, M.J. (Department of Engineering Science and Mathematics, Division of Fluid and Experimental Mechanics, Lulea University of Technology)
Raisee, M. (Mechanical Engineering Department, University of Tehran)
Publication Information
International Journal of Fluid Machinery and Systems / v.9, no.2, 2016 , pp. 182-193 More about this Journal
Abstract
Introduction of intermittent electricity production systems like wind and solar power to electricity market together with the deregulation of electricity markets resulted in numerous start/stops, load variations and off-design operation of water turbines. Hydraulic turbines suffer from the varying loads exerted on their stationary and rotating parts during load variations since they are not designed for such operating conditions. Investigations on part load operation of single regulated turbines, i.e., Francis and propeller, proved the formation of a rotating vortex rope (RVR) in the draft tube. The RVR induces pressure pulsations in the axial and rotating directions called plunging and rotating modes, respectively. This results in oscillating forces with two different frequencies on the runner blades, bearings and other rotating parts of the turbine. This study investigates the effect of transient operations on the pressure fluctuations exerted on the runner and mechanism of the RVR formation/mitigation. Draft tube and runner blades of the Porjus U9 model, a Kaplan turbine, were equipped with pressure sensors for this purpose. The model was run in off-cam mode during different load variations. The results showed that the transients between the best efficiency point and the high load occurs in a smooth way. However, during transitions to the part load a RVR forms in the draft tube which induces high level of fluctuations with two frequencies on the runner; plunging and rotating mode. Formation of the RVR during the load rejections coincides with sudden pressure change on the runner while its mitigation occurs in a smooth way.
Keywords
Kaplan turbine; Runner pressure measurement; Load variations; Rotating vortex rope formation; Rotating vortex rope mitigation;
Citations & Related Records
연도 인용수 순위
  • Reference
1 Houde, S., Fraser, R., Ciocan, G., Deschenes, C., 2012, "Experimental study of the pressure fluctuations on propeller turbine runner blades: part 2, transient conditions," Earth and Environmental Science, Vol. 15, 062061.
2 Gagnon, M., Leonard, F., 2013, "Transient response and life assessment: Case studies on the load rejection of two hydroelectric turbines," Proceedings of the International Conference Surveillance, Chartres, France, pp. 1-11.
3 Gagnon, M., Tahan, S. A., Bocher, P., Thibault, D., 2010, "Impact of startup scheme on Francis runner life expectancy," Earth and Environmental Science, Vol. 12, 012107.
4 Trivedi, C., Gandi, B. K., Cervantes, M. J., 2012, "Effect of transients on Francis turbine runner life: a review," Journal of Hydraulic Research, Vol. 51, No. 2, pp. 121-132.   DOI
5 Kishor, N., Saini, R. P., Singh, S. P., 2007, "A review on hydropower plant models and control," Renewable and Sustainable Energy Reviews, Vol. 11, No. 5, pp. 776-796.   DOI
6 Chirag, T., Cervantes, M. J., Bhupendrakumar, G., Dahlhaug, O. G., 2014, "Pressure measurements on a high-head Francis turbine during load acceptance and rejection," Journal of Hydraulic Research, Vol. 52, No.2, pp. 283-279   DOI
7 Trivedi, C., Cervantes, M. J., Gandhi, B. K., Dahlhaug, O. G., 2014, "Experimental investigations of transient pressure variations in a high head model Francis turbine during start-up and shutdown," Journal of Hydrodynamics, Vol. 26, No., 2, pp. 277-290.   DOI
8 Simmons, G. F., Aidanpaa, J., Cervantes, M. J., Glavatskih, S., 2013, "Operational transients in the guide bearings of a 10 MW Kaplan turbine," International journal on hydropower and dams, Vol. 20, No.5, pp. 94-100.
9 Simmons, G. F., 2013, "Journal Bearing Design, Lubrication and Operation for Enhanced Performance," Ph. D. Thesis, Lulea Univ. of Tech., Lulea, Sweden.
10 Jansson, I., 2013, "Vibrant bodies of swirling flow: On the limits of mechanical power transformation," Ph. D. Thesis, Lulea Univ. of Tech., Lulea, Sweden.
11 Mulu, B. G., Jonsson, P. P., Cervantes, M. J., "2012 Experimental investigation of a Kaplan draft tube - Part I: Best efficiency point," Applied Energy, Vol. 93, pp. 695-706.   DOI
12 Jonsson, P. P., Mulu, B. G., Cervantes, M. J., 2012, "Experimental investigation of a Kaplan draft tube - Part II: Off-design conditions," Applied Energy, Vol. 94, pp. 71-83.   DOI
13 Amiri, K., Cervantes, M. J., Mulu, B. G., 2015, "Experimental investigation of the hydraulic loads on the runner of a Kaplan turbine model and the corresponding prototype," Journal of Hydraulic Research, Vol. 53, No.4, pp. 452-465.   DOI
14 Amiri, K., 2014, "An Experimental Investigation of flow in a Kaplan runner: steady-state and transient," Licentiate Thesis, Lulea Univ. of Tech, Lulea, Sweden.
15 Amiri, K., Mulu, B. G., Cervantes, M. J., 2015, "Experimental Investigation of the Interblade Flow in a Kaplan Runner at Several Operating Points Using Laser Doppler Anemometry," Journal of Fluids Engineering, Vol. 138, 021106-2.
16 Amiri, K., Mulu, B. G., Raisee, M., Cervantes, M. J., 2015, "Unsteady pressure measurements on the runner of a Kaplan turbine during load acceptance and load rejection," Journal of Hydraulic Research, DOI:10.1080/00221686.2015.1110626.   DOI