The Winter-Kennedy (WK) method is commonly used in relative discharge measurement and to quantify efficiency step-up in hydropower refurbishment projects. The method utilizes the differential pressure between two taps located at a radial section of a spiral case, which is related to the discharge with the help of a coefficient and an exponent. Nearly a century old and widely used, the method has shown some discrepancies when the same coefficient is used after a plant upgrade. The reasons are often attributed to local flow changes. To study the change in flow behavior and its impact on the coefficient, a numerical model of a semi-spiral case (SC) has been developed and the numerical results are compared with experimental results. The simulations of the SC have been performed with different inlet boundary conditions. Comparison between an analytical formulation with the computational fluid dynamics (CFD) results shows that the flow inside an SC is highly three-dimensional (3D). The magnitude of the secondary flow is a function of the inlet boundary conditions. The secondary flow affects the vortex flow distribution and hence the coefficients. For the SC considered in this study, the most stable WK configurations are located toward the bottom from to after the curve of the SC begins, and on the top between two stay vanes.
Issue Section:
Flows in Complex Systems
References
1.
IEA
, 2012
, “Technology Roadmap—Hydropower,” Organisation for Economic Co-operation and Development/International Energy Agency, Paris, France, Report
.https://www.iea.org/publications/freepublications/publication/technology-roadmap-hydropower.html2.
Trivedi
, C.
, Cervantes
, M. J.
, and Dahlhaug
, O. G.
, 2016
, “Numerical Techniques Applied to Hydraulic Turbines: A Perspective Review
,” ASME Appl. Mech. Rev.
, 68
(1), p. 010802
.3.
IEC,
1991
, “Field Acceptance Tests to Determine the Hydraulic Performance of Hydraulic Turbines, Storage Pumps and Pump Turbines
,” International Electrotechnical Commission
, Geneva, Switzerland, Standard No. 60041:1991
.https://webstore.iec.ch/publication/1544.
Almquist
, C. W.
, Taylor
, J. W.
, and Walsh
, J. T.
, 2011
, “Kootenay Canal Flow Rate Measurement Comparison Test Using Intake Methods,” HydroVision
, Sacramento, CA, July 19–22.https://www.aqflow.com/reports/HydroVision-2011-Almquist.pdf5.
Cervantes
, M. J.
, Gunilla
, A.
, Peter
, K.
, and Sundström
, J.
, 2012
, “Flow Measurements in Low-head Hydro Power Plants,” Elforsk, Stockholm, Sweden, Report No. 12:61
http://ltu.diva-portal.org/smash/record.jsf?pid=diva2%3A997466&dswid=2806.6.
Winter
, I. A.
, and Kennedy
, A. M.
, 1933
, “Improved Type of Flow Meter for Hydraulic Turbines
,” ASCE, Proc.
, 59
(4
), pp. 565–584.7.
Greitzer
, E.
, Tan
, C.
, and Graf
, M.
, 2004
, Internal Flow: Concepts and Applications
, Cambridge University Press
, Cambridge, UK
.8.
Kurokawa
, J.
, and Nagahara
, H.
, 1986
, “Flow Characteristics in Spiral Casings of Water Turbines
,” 13th IAHR Symposium on Hydraulic Machinery and Systems
, Montreal, QC, Canada, Sept. 2–5, Paper No. 62.9.
Lövgren
, M.
, Andersson
, U.
, and Andrée
, G.
, 2008
, “Skew Inlet Flow in a Model Turbine-Effects on Winter-Kennedy Measurements,” Hydro, Ljubljana, Oct. 6–8, Paper No. 7.03.10.
Rau
, T.
, and Eissner
, M.
, 2014
, “Experience With Winter-Kennedy Coefficients on Hydraulic Identical Units,” Tenth International Conference on Hydraulic Efficiency Measurements (IGHEM), Itajuba, Brazil, Sept. 16–19, Paper No. 397
http://www.ighem.org/Papers_IGHEM/397.pdf.11.
Nicolle
, J.
, and Proulx
, G.
, 2010
, “A New Method for Continuous Efficiency Measurement for Hydraulic Turbines,” Eighth International Conference on Hydraulic Efficiency Measurements (IGHEM
), Roorkee, India, Oct. 21–23, pp. 198–205.http://www.ahec.org.in/links/IGHEM_2010/Papers/TSE-01.pdf12.
Muciaccia
, F. F.
, and Walter
, R. B.
, 2000
, “Evaluation of the Benefits of Turbine Refurbishment by Means of Index Test Method Reliability of Results and Problems in Applications,” Third International Conference on Hydraulic Efficiency Measurements (IGHEM
), Kempten, Germany, July, Paper No. 248.13.
Lövgren
, M.
, Andersson
, U.
, and Cervantes
, M. J.
, 2013
, “Some Limitations of the Winter-Kennedy Flow Measuring Method,” International Conference and Exhibition on Promoting the Versalite Role of Hydro (Hydro), Innsbruck, Austria, Oct. 7–9, Paper No. 19.07.14.
Andersson
, U.
, 2009
, “An Experimental Study of the Flow in a Sharp-Heel Kaplan Draft Tube,” Doctoral thesis
, Luleå University of Technology, Luleå, Sweden.https://www.diva-portal.org/smash/get/diva2:990757/FULLTEXT01.pdf15.
Gebart
, B.
, Gustavsson
, L.
, and Karlsson
, R.
, 2000
, “Proceedings of Turbine-99-Workshop on Draft tube Flow,” Luleå University of Technology, Luleå, Sweden, Technical Report No. 2000:11.16.
Nilsson
, H.
, Andersson
, U.
, and Videhult
, S.
, 2005
, “An Experimental Investigation of the Flow in the Spiral Casing and Distributor of the Hölleforsen Kaplan Turbine Model,” Chalmers University of Technology, Göteborg, Sweden.17.
ANSYS, 2015, “ANSYS CFX 16.0 Solver Theory Guide,” ANSYS Inc., Canonsburg, PA.
18.
Menter
, F. R.
, 1994
, “Two-Equation Eddy-Viscosity Turbulence Models for Engineering Applications
,” AIAA J.
, 32
(8
), pp. 1598
–1605
.19.
Menter
, F. R.
, Kuntz
, M.
, and Langtry
, R.
, 2003
, “Ten Years of Industrial Experience With the SST Turbulence Model
,” Turbulence, Heat and Mass Transfer
, 4th ed., K.
Hanjalic
, Y.
Nagano
, and M.
Tummers
, eds., Begell House
, Danbury, CT, pp. 625
–632
.20.
Mössinger
, P.
, Zürker-Jester
, R.
, and Jung
, A.
, 2015
, “Investigation of Different Simulation Approaches on a High-Head Francis Turbine and Comparison With Model Test Data: Francis-99
,” J. Phys.: IOP Conf. Ser.
, 579
, p. 012005
.21.
Trivedi
, C.
, Cervantes
, M. J.
, Gandhi
, B. K.
, and Dahlhaug
, O. G.
, 2013
, “Experimental and Numerical Studies for a High Head Francis Turbine at Several Operating Points
,” ASME J. Fluids Eng.
, 135
(11
), p. 111102
.22.
Celik
, I.
, Ghia
, U.
, Roache
, P.
, Freitas
, C.
, Coleman
, H.
, and Raad
, P.
, 2008
, “Procedure for Estimation and Reporting of Uncertainty Due to Discretization in CFD Applications
,” ASME J. Fluids Eng.
, 130
(7
), p. 078001
.23.
Geberkiden
, B. M.
, and Cervantes
, M. J.
, 2007
, “Effects of Inlet Boundary Conditions on Spiral Casing Simulation
,” Second IAHR International Meeting on the Workgroup on Cavitation and Dynamic Problems in Hydraulic Machinery and Systems
, Timisoara, Romania, Oct. 24–26, pp. 217–224.https://www.diva-portal.org/smash/get/diva2:1008938/FULLTEXT01.pdf24.
Kubota
, T.
, 1989
, “Normalization of Flow Profile Data Measured at Runner Inlet
,” 3D-Computation of Incompressible Internal Flows: Proceedings of the GAMM Workshop at EPFL
, Lausanne, Switzerland, Sept. 13–15, pp. 55
–62
.25.
Nilsson
, H.
, and Davidson
, L.
, 2000
, “A Numerical Comparison of Four Operating Conditions in a Kaplan Water Turbine, Focusing on Tip Clearance Flow
,” 20th IAHR Symposium on Hydraulic Machinery and Systems
, Charlotte, NC, Aug. 6–9, p. 9885.http://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.462.2811&rep=rep1&type=pdf26.
Taylor
, A. M. K. P.
, Whitelaw
, J. H.
, and Yianneskis
, M.
, 1982
, “Curved Ducts With Strong Secondary Motion: Velocity Measurements of Developing Laminar and Turbulent Flow
,” ASME J. Fluids Eng.
, 104
(3
), pp. 350
–359
.27.
Sudo
, K.
, Sumida
, M.
, and Hibara
, H.
, 1998
, “Experimental Investigation on Turbulent Flow in a Circular-Sectioned 90-Degree Bend
,” Exp. Fluids
, 25
(1
), pp. 42
–49
.28.
Shyy
, W.
, and Vu
, T. C.
, 1993
, “Modeling and Computation of Flow in a Passage With 360-Degree Turning and Multiple Airfoils
,” ASME J. Fluids Eng.
, 115
(1
), pp. 103
–108
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