Spectral analysis of oscillatory wind wave parameters in fetch-limited deep-water conditions at a small reservoir and their prediction: Case Study of the Hulín Reservoir in the Czech Republic

Kotaška, Stanislav; Duchan, David; Pelikán, Petr; Špano, Miroslav

doi:10.2478/johh-2023-0042

Abstract

The dams and banks of small water reservoirs face significant erosion from wind-generated oscillatory waves. Proper design of structure height is crucial to protect such banks against erosion, considering the maximum characteristics of wind waves. Long-term measurements at the Hulín reservoir revealed that the wave spectrum aligns best with the Bretschneider type. This spectrum serves as a basis for simulating oscillatory waves and their impact on shore protection structure design. Empirical models were evaluated using wind and wave data from Hulín reservoir in the Czech Republic. The measured wind speeds attained a maximum of 8 m/s, and wave heights reached up to 15 cm. The Bretschneider (SMB) empirical formula provided the most accurate estimation of wave height (H_m₀), with an average underestimate of RMSE = 0.038 m. On the other hand, Wilson revisited (WIL rev.) performed less effectively, with an average RMSE = 0.304 m. For wave period (T) estimation, Bretschneider (SMB) yielded the best results, with an average RMSE = 0.062 s. Conversely, Wilson revisited (WIL rev.) showed poorer performance, with an average underestimate of RMSE = 2.196 s. The discrepancy between the empirical formulas and measured values, particularly in underestimating H_m₀, can be attributed to inaccurate determination of fetch length and wind speed.

References

Alves, J.H.G.M., Banner, M.L., Young, I.R., 2003. Revisiting the Pierson-Moskowitz Asymptotic Limits for Fully Developed Wind Waves. Journal of Physical Oceanography, 33, 7, 1301–1323.
Search in Google Scholar Back to article
Bretschneider, C.L., 1959. Wave variability and wave spectra for wind-generated gravity waves. Technical Memorandum No. 118. Beach Erosion Board, U.S. Army Corps of Engineers, 196 p.
Search in Google Scholar Back to article
Brodtkorb, P.A., Johannesson, P., Lindgren, G., Rychlik, I., Rydén, J., Sjo, E., 2000. WAFO – a Matlab toolbox for analysis of random waves and loads. Paper no. ISOPE 2000-GFC-02, 8 p.
Search in Google Scholar Back to article
BS-MS, 1993. British Standard, Maritime Structures (BS-MS). Part 1: Code of practice for general criteria. BS 6349-1:200.
Search in Google Scholar Back to article
Carter, D.J.T., 1982. Prediction of wave height and period for a constant wind velocity using the JONSWAP results. Ocean Engineering, 9, 1, 17–33.
Search in Google Scholar Back to article
CAS, 2022. Institute of Atmospheric Physics. Available: http://vitr.ufa.cas.cz/male-vte/ (accessed on 11 November 2022).
Search in Google Scholar Back to article
CSN 75 0255, 1988. Calculation of Wave Effects on Hydrotechnic Structures on Water Reservoirs. Czechoslovakia, 32 p. (In Czech). Available online: http://technicke-normy-csn.cz/750255-csn-75-0255_4_31249.html (accessed on 11 November 2022).
Search in Google Scholar Back to article
Donelan, M.A., 1980. Similarity theory applied to the forecasting if wave heights, periods and directions. In: Proceedings Canadian Coastal Conference. National Research Council, Canada.
Search in Google Scholar Back to article
Etemad-Shahidi, A., Kazeminezhad, M.H., Mousavi, S.J., 2009. On the prediction using simplified methods. Journal of Coastal Research, 1, Special Issue 56, 505–509.
Search in Google Scholar Back to article
Hanslian, D., Hošek, J., Chládová, Z., Pop, L., 2013. Wind conditions in the Czech Republic at a height of 10 m above the surface I. (In Czech.) Available: https://oze.tzb-info.cz/vetrna-energie/9770-vetrne-podminky-v-ceske-republice-ve-vysce-10-mnad-povrchem-i (accessed on 11 November 2022).
Search in Google Scholar Back to article
Hasselmann, K., Barnett, T.P., Bouws, E., Carlson, H., Cartwright, D.E., Enke, K., Ewing, J.A., Gienapp, H., Hasselmann, D.E., Kruseman, P., Meerburg, A., Muller, P., Olbers, D.J., Richter, K., Sell, W., Walden, H., 1973. Measurements of Wind-Wave Growth and Swell Decay during the Joint North Sea Wave Project (JONSWAP). UDO 551.466.31. ANE German Bight, Deutsches Hydrographisches Institut, Hamburg, Germany, 94 p.
Search in Google Scholar Back to article
Choi, B.-Y., Jo, H.-J., Lee, K.-H., Byoun, D.-H., 2018. Development of Wind Induced Wave Predict Using Revisited Methods. Journal of Advanced Research in Ocean Engineering, 4, 3, 124–134.
Search in Google Scholar Back to article
Kazeminezhad, M.H., Etemad-Shahidi, A., Mousavi, S.J., 2005. Application of fuzzy inference system in the prediction of wave parameters. Ocean Engineering, 32, 14–15, 1709–1725.
Search in Google Scholar Back to article
Klaus, H., Olbers, D.J., 1973. Measurements of Wind-Wave Growth and Swell Decay During the Joint North Sea Wave Project (JONSWAP), pp. 2–95.
Search in Google Scholar Back to article
Kotaška, S., 2019. Measurement of wind oscillatory waves on reservoir. Master’s Thesis. Brno University of Technology. Faculty of Civil Engineering. Department of Water Structures Brno, 101 p. (In Czech.) Available online: http://hdl.handle.net/11012/137529. (accessed on 11 November 2022).
Search in Google Scholar Back to article
Krylov, Y.M., Strekalov, S.S., Tsyplukhin, V.F., 1976. Wind Waves and Their Impact on Structures. Gidrometeoizdat, Leningrad, 255 p. (In Russian.)
Search in Google Scholar Back to article
Le Méhauté, B., 1976. An Introduction to Hydrodynamics and Water Waves. Springer-Verlag.
Search in Google Scholar Back to article
Mahmood, M.F, Henderson, D., Segur, H., 2010. Water Waves Theory and Experiment. In: Proceedings of the Conference. World Scientific Publishing Co., River Edge, NJ, USA, pp. 79–81.
Search in Google Scholar Back to article
Marinet, 2015. Best Practice Manual for Wave Simulation. WP2: Marine Energy System Testing – Standardisation and Best Practice. Version 3, 47 p.
Search in Google Scholar Back to article
MATLAB, 2022. Matlab version 9.12.0 (R2022a). The MathWorks Inc, Natick, Massachusetts.
Search in Google Scholar Back to article
McCormick, M.E., 1998. On the Use of Wind-Wave Spectral Formulas to Estimate Wave Energy Resources. Journal of Energy Resources Technology, 120, 314–317.
Search in Google Scholar Back to article
Michel, W.H., 1968. Sea Spectra Simplified. In: Proc. Meeting of the Gulf Section of the Society of Naval Architects and Marine Engineers.
Search in Google Scholar Back to article
Nash, J.E.; Sutcliffe, J.V., 1970. River flow forecasting through conceptual model. Part 1 – A discussion of principles. Journal of Hydrology, 10, 282–290.
Search in Google Scholar Back to article
NDBC, 2022. National Data Buoy Center. Available: https://www.ndbc.noaa.gov (accessed on 11 November 2022).
Search in Google Scholar Back to article
OCADIJ, 2002. Overseas Coastal Area Development Institute of Japan (OCADIJ). Technical Standards and Commentaries for Port and Harbor Facilities in Japan. Japan, 664 p.
Search in Google Scholar Back to article
Ochi, M.K., Hubble, E.N., 1976. Six-parameter wave spectra. In: Proc. Int. Conf. Coastal. Eng. 1, 15, pp. 301–328.
Search in Google Scholar Back to article
Owen, M.W., Steele, A.A.J., 1988. Wave prediction in reservoirs, comparison of available methods. Report EX 1809, HR Walling-ford, 110 p. Available online: https://eprints.hrwalling-ford.com/179/ (accessed on 11 November 2022).
Search in Google Scholar Back to article
Ozeren, Y., Wren, D., 2009. Predicting wind-driven waves in small reservoirs. American Society of Agricultural and Biological Engineers (ASABE), 51, 5, 1599–1612.
Search in Google Scholar Back to article
Pelikán, P., Marková, J., 2013. Wind effect on water surface of water reservoirs. Acta Univ. Agric. Silvic. Mendel. Brun., 61, 6, 1823–1828.
Search in Google Scholar Back to article
Pelikán, P., Šlezingr, M., 2015. Parameters of wind-driven waves on Nove Mlyny water reservoir. In: Proc. Conf. Water Management and Hydraulic Engineering 2015. Institute of Water Structures, FCE, BUT, Brno, Czech Republic, pp. 55–64.
Search in Google Scholar Back to article
Pelikán, P., Koutný, L., 2016. Hindcast of wind driven wave heights in water reservoirs. Soil Water Res., 11, 3, 205–211.
Search in Google Scholar Back to article
Pelikán, P., Hubačíková, V., Kaletova, T., Fuska, J., 2020. Comparative assessment of different modelling schemes and their applicability to inland small reservoirs: A Central Europe case study. Sustainability, 12, 14 pp.
Search in Google Scholar Back to article
Pelikán, P., Špano, M., Čejda, M., 2020. Equipment for measuring and transmitting data of wind oscillating waves on water reservoirs (In Czech: Zařízení pro měření a přenos dat větrových oscilačních vln na vodních nádržích.). Utility model, Office industry property Czech Republic, 7 p. Available online: https://isdv.upv.cz/doc/FullFiles/UtilityModels/FullDocuments/FDUM0034/uv034513.pdf (accessed on 11 November 2022).
Search in Google Scholar Back to article
Phillips, O.M., 1958. The equilibrium range in the spectrum of wind-generated waves. J. Fluid Mech., 4, 426–434.
Search in Google Scholar Back to article
Říha, J., Špano, M., 2012. The influence of current on the height of wind wave run-up, a comparison of experimental results with the Czech National Standard. J. Hydrol. Hydromech., 60, 3, 174–184. Saville, T., McClendon, E.W., Cochran, A.L., 1962. Freeboard allowances for waves in inland reservoirs. Journal of Waterways and Harbors Division, ASCE, 88, 2, 93–124.
Search in Google Scholar Back to article
Sibul, O., 1955. Laboratory Study of the Generation of Wind Waves in Shallow Water. Technical Memo No. 72. U.S. Army Corps of Engineers Beach Erosion Board, p. 35.
Search in Google Scholar Back to article
Smith, J.M., 1991. Wind-Wave Generation on Restricted Fetches. Miscellaneous Paper CERC-91-2. US Army Waterways Experiment Station, Vicksburg, MS.
Search in Google Scholar Back to article
SPM, 1977. United States Army Corps of Engineers and Coastal Engineering Research Center (U.S. Army, 1977). Shore Protection Manual (SPM). Department of the Army, Waterways Experiment Station, Corps of Engineers, Coastal Engineering Research Center.
Search in Google Scholar Back to article
SPM, 1984. United States Army Corps of Engineers and Coastal Engineering Research Center (U.S. Army, 1984). Shore Protection Manual, Department of the Army, Waterways Experiment Station, Corps of Engineers, Coastal Engineering Research Center, 652 p.
Search in Google Scholar Back to article
Stoica, P., Moses, R., 2005.Spectral analysis of signals. Prentice Hall, Upper Saddle River, New Jersey 07458, USA, 447 p. ISBN 0-13-113956-8.
Search in Google Scholar Back to article
Sverdrup, H.V., Munk, W.H., 1947. Wind, sea, and swell: Theory of relations for forecasting. Hydrographic Office Pub. 60, US Navy.
Search in Google Scholar Back to article
Špano, M., 2019. Protection of embankments and banks against action caused by oscillatory wind waves. In: Proceedings of the ICOLD 2019 Symposium 9.-14.6.2019 Ottawa, Canada. Sustainable and Safe Dams Around the World. ICOLD/CIGB. Paris, France, pp. 3095–3102.
Search in Google Scholar Back to article
Špano, M., Duchan, D., Kotaška, S., Skřečková, K., Prokopová, E., Pelikán, P., Hrůza, O., Seidl, R., Dvořáková, S., Švancara, J., Čejda, M., 2020. Protection of water structures and natural banks against the effects of oscillating wind waves. (In Czech: Ochrana konstrukcí vodních staveb a přirozených břehů před účinky oscilačních větrových vln.) Partial report of TH03030182: Protection of hydraulic structures against action caused by oscilatory wind waves. Brno: BUT, TAČR No. I/2020, 56 p.
Search in Google Scholar Back to article
Špano, M., Duchan, D., 2021. Threat to embankments and natural banks posed by oscillatory wind waves. Gospodarka wodna, 873, 9, 10–16.
Search in Google Scholar Back to article
Špano, M., Bornschein, A., Pohl, R., Říha, J., Schuttrumpf, H., 2022. Wave run-ups and overtopping affected by oblique wave approaches and currents. Slovak Journal of Civil Engineering, 30, 2, 12–21.
Search in Google Scholar Back to article
Torsethaugen, K., 1993. Two peak wave spectrum model. In: Proceedings of the International Conference on Offshore Mechanics and Arctic Engineering – OMAE, (2), pp. 2–10.
Search in Google Scholar Back to article
Vincent, C.L., Demirbilek Z., Weggel, J.R., 2002. Coastal Engineering Manual: Part II. Coastal Hydrodynamics. Engineer Manual 1110‐2‐1100. U.S. Army Corps of Engineers, Washington, D.C., 623 p.
Search in Google Scholar Back to article
WAFO GROUP, 2017. A Matlab Toolbox for Analysis of Random Waves and Loads. Tutorial for WAFO version 2017. Lund University, Faculty of Engineering, Centre for Mathematical sciences, Mathematical statistics, 195 p.
Search in Google Scholar Back to article
Wilson, B.W., 1955. Graphical approach to the forecasting of waves in moving fetches. U.S. Army. Tech. Mem., No. 73. Beach Erosion Board, Corps of Engrs., 31 p.
Search in Google Scholar Back to article
Wilson, B.W., 1965. Numerical prediction of ocean waves in the North Atlantic for December, 1959. Deutsche Hydrographische Z., 18, 3, 114–130.
Search in Google Scholar Back to article
Yarde, A.J., Banyard, L.S., Allsop, N.W.H., 1996. Reservoir dams: wave conditions, wave overtopping and slab protection. HR Wallingford, no. CAS 0021, 62 p.
Search in Google Scholar Back to article

Spectral analysis of oscillatory wind wave parameters in fetch-limited deep-water conditions at a small reservoir and their prediction: Case Study of the Hulín Reservoir in the Czech Republic

Abstract

Paradigm

My account