Details
Title
Impact of a thermocline on water dynamics in reservoirs – Dobczyce reservoir caseJournal title
Archive of Mechanical EngineeringYearbook
2017Volume
vol. 64Issue
No 2Authors
Affiliation
Hachaj, Paweł S. : Institute of Water Engineering and Water Management, Cracow University of Technology, Poland ; Szlapa, Monika : Institute of Water Engineering and Water Management, Cracow University of Technology, PolandKeywords
storage reservoir ; water dynamics ; numerical simulation ; thermocline ; stratificationDivisions of PAS
Nauki TechniczneCoverage
189-203Publisher
Polish Academy of Sciences, Committee on Machine BuildingBibliography
[1] A. Bojarski, M. Cebulska, L. Lewicki, S. Mazon, G. Mazurkiewicz-Boron, E. Nachlik, P. Opalinski, P. Przecherski and S. Rybicki. Long- and short time perspectives for the usage of the Dobczyce reservoir. Cracow, Poland, 2012. (in Polish).[2] J. Starmach and G. Mazurkiewicz-Boron (Eds). Dobczyce Reservoir Ecology-Eutrophication-Protection. Dept. of Freshwater Biology, Institute of Nature Conservation, Polish Academy of Sciences, Cracow, Poland, 2000. (in Polish).
[3] P. Hachaj. Numerical modelling of pollution transport phenomena in the lake of Dobczyce. In P.M. Rowinski, editor, Hydraulic Methods for Catastrophes: Floods, Droughts, Environmental Disasters, Publications of the Institute of Geophysics, Polish Academy of Sciences. E –Hydrology (formerly Water Resources), E-10(406):47-54, 2008.
[4] P. Hachaj, L. Lewicki, E. Nachlik and T. Siuta. Effectiveness of hydrodynamic models in assessment of dammed reservoir dynamics. Gospodarka Wodna, 8:286-288, 2014. (in Polish).
[5] P. Hachaj. Modelling of a two-dimensional velocity field for the water flow in the lake of Dobczyce. In P.M. Rowinski, editor, Transport Phenomena in Hydraulics, Publications of the Institute of Geophysics, Polish Academy of Sciences. E – Hydrology (formerly Water Resources), E-7(401):87-95, 2007.
[6] M. Gałek. Sensitivity analysis of the FESWMS model applied to the Dobczyce Reservoir. M.Sc. Thesis. Carcow University of Technology, Poland, 2010. (in Polish).
[7] R.C. Berger, J.N. Tate, G.L. Brown and G. Savant. Adaptive hydraulics users manual. AQUAVEO, 2010.
[8] K. Winters. Adaptive hydraulics – 2D shallow water flow model interface within the surfacewater modeling system. M.Sc. Thesis. Brigham Young University, Provo, UT, USA, 2008.
[9] M. Gałek and P. Hachaj. Application of theRMA2/RMA4models to simulate pollution transport in a retention reservoir. In P. Rowinski, editor, Experimental and Computational Solutions of Hydraulic Problems. GeoPlanet: Earth and Planetary Science, pages 301-313, Springer, 2013. doi: 10.1007/978-3-642-30209-1_21.
[10] P. Hachaj and M.Tutro. Flow patterns for dryling and wetting of a retention reservoir bed –umerical modeling. I nfrastructure and Ecology of Rural Areas, IV(3):1407-1419, 2014. doi: 10.14597/infraeco.2014.4.3.106.
[11] P. S. Hachaj, M. Szlapa and M. Tutro. Numerical modeling of sub-glacial flow in a retention reservoir. Technical Transactions; Environment Enginering, 1-S(18):37-51, Cracow University of Technology, 2015. doi: 10.4467/2353737XCT.15.182.4387.
[12] A. Bojarski, Z. Gręplowska and E. Nachlik. Goczałkowice Reservoir. Cause and effect DPSIR analysis of processes and important phenomena from the viewpoint of managing dam reservoir. Cracow University of Technology, Monograph No. 420. 2012. (in Polish).
[13] K. Witek. Water flow simulations in the Tresna reservoir using the AdH numerical model. B.Eng. Thesis, Cracow University of Technology, Poland, 2013. (in Polish).
[14] A. Saggio and J. Imberger. Mixing and turbulent fluxes in the metalimnion of stratified lake. Limnology and Oceanography, 46(2):392-409, 2001.