The safety of hydraulic structures in small catchment areas is addressed. A procedure for assessing the influence of climate and landscape changes on the maximum discharge that determines the sizes of structure elements is developed. The data from a network weather station and the landscape characteristics of the catchment area were analyzed using statistical methods and geoinformation technologies. The main results are the increase in the maximum daily precipitation and landscape changes over the past decades and their influence on the maximum discharge obtained using probability theory and runoff theory.
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References
P. Ya. Groisman, R.W. Knight, and O. G. Zolina, “Recent trends in regional and global intense precipitation patterns,” in: R. A. Pilke (ed.), Climate Vulnerability: Understanding and Addressing Threats to Essential Resources, Academic Press (2013), pp. 25 – 52.
O. Zolina, C. Simmer, A. Kapala, P. Shabanov, P. Becker, H. Mächel, S. Gulev, and P. Groisman, “Precipitation variability and extremes in Central Europe: New view from STAMMEX results,” Bull. Am. Meteorol. Soc., 95(7), 995 – 1002 (2014).
D. Raynaud, J. Thielen, P. Salamon, P. Burek, S. Anquetin, and L. Alfieri, “A dynamic runoff co-efficient to improve flash flood early warning in Europe: evaluation on the 2013 central European floods in Germany,” Meteorol. Appl., 22(3), 410 – 418 (2015).
O. G. Zolina and O. N. Bulygina, “Current climatic variability of extreme precipitation in Russia,” Fund. Appl. Climatol., 1, 84 – 103 (2016).
V. Iliinich, E. Akulova, V. Belchihina, and K. Ponomarchuk, “Estimation of statistical characteristics for storm precipitation with long-term data to assess climate change,” J. Climate Change, 2(2), 83 – 87 (2016).
M. Yu. Lapushkin and V. V. Il’inich, “Assessment of changes in storm rainfalls in the north of Moscow affecting the reliability of hydraulic structures,” Gidrotekhn. Stroit., No. 3, 96 – 99 (2020).
Rules and Regulations SP 33-101–2003. Determining the Basic Hydrological Characteristics [in Russian], Gosstroi RF, Moscow (2004).
R. Dmowska, D. L. Hartmann, and T. Rossby (eds.), Statistical Methods in Atmospheric Sciences. Vol. 1, Int. Geof. Ser., Oxford, UK (2011).
A. V. Sikan, Methods of Statistical Processing of Hydrometeorological Data [in Russian], RGGMU, St. Petersburg (2007).
Hydrologic Modeling System HEC-HMS. Technical Reference Manual (2000); http://www.hec.usace.army.mil/software/hechms/documentation/HECHMS
MIKE 11. A Modeling System for Rivers and Channels: Reference Manual, DHI (2008).
Manual for Determination of Design Hydrological Characteristics [in Russian], Gidrometizdat, Leningrad (1984).
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Translated from Gidrotekhnicheskoe Stroitel’svo, No. 7, July 2022, pp. 15 – 19. DOI: https://doi.org/10.34831/EP.2022.30.59.003
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Ilinich, V.V., Perminov, A.V. & Naumova, A.A. Influence of Landscape and Climate Changes on the Maximum Discharge of Small Catchment Areas. Power Technol Eng 56, 635–638 (2023). https://doi.org/10.1007/s10749-023-01565-1
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DOI: https://doi.org/10.1007/s10749-023-01565-1