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Hydrogeologicznego, Chwaszczyno (in Polish). Stuyt L. C. P. M., Dierickx W., Martinez Beltran J. (2005) Materials for subsurface land drainage systems, Food and Agriculture Organization of the United Nations, Irrigation and drainage paper, 60 rev. 1. Sterpejkowicz-Wersocki W. (2013) The durability of geosynthetics in filtration applications in hydraulic engineering, Inżynieria Morska i Geotechnika (in Polish), 34 (5), 447-456. Sterpejkowicz-Wersocki W., Szudek W. (2013) Renovation of drainage system in hydropower plant Podgaje, Monografie Instytutu Meteorologii i GospodarkiWodnej

REFERENCES B omba A., T kachuk M., H avryliuk V., K yrysha R., G erasimov I., P inchuk O. 2018. Mathematical modelling of filtration processes in drainage systems using conformal mapping. Journal of Water and Land Development. No. 39 (X–XII) p. 11–15. DOI 10.2478/jwld-2018-0054. E vans I.S. 2016. Quantifying variation in wetland composition and configuration for landscape-scale reclamation planning [online]. Master thesis. Waterloo, Ontario. University of Waterloo pp. 102. [Access 03.01.2019]. Available at: http://hdl.handle.net/10012/10985 G ramlich A

References Alterra / ILRI Wageningen, Ritzema H. (2008): Materials from “International Course on Land Drainage”, module 3: “Design, Implementation and Operation of Drainage Systems” Pre drainage investigations for Mahstul Pilot Area (Nile Delta, Egypt) Wageningen, The Netherlands, pp. 43-58. Boussinesq J. (1904): Recherches théoretiques sur l’écoulement des nappes d’eau infiltrées dans le sol et sur le débit des sources. Journal de mathématiques pures et appliquées, no.10, part 5: 5-78. Dam J. C. van (2000): Field-scale water flow and solute transport. SWAP model

References [1] GRZEGORCZYK K., KENIG J., JAGOSZ Z., Report defining geological and engineering conditions of planned investment site, Wrocław, May 2007. [2] STRZELECKI T., STRZELECKI M., PUŁA O., Detailed design of vertical drainage in vicinity of airport terminal, Wrocław, 2013. [3] STRZELECKI T., KOSTECKI S., ŻAK S., Modelling of flows through porous media, Lower Silesia Educational Publishers, 2008. [4] MicroStation v.8: www.bentley.com [5] InRoads: www.bentley.com [6] Flex PDE v.633: http://www.pdesolutions.com/

Part A, 36, 507-524. Kalantari, Z., Briel, A., Lyon, S.W., Olofsson, B, Folkeson, L., 2014. On the utilization of hydrological modelling for road drainage design under climate and land use change . Science of the Total Environment, 475, 97-103, DOI: 10.1016/j.scitotenv.2013.12.114 Karelová, Z., Vranayová, Z., Káposztasová, D., Purcz P., 2013. Rainwater harvesting and its risk assessment . Construction of Optimized Energy Potential, 1(11), 58-65. Kowacki, M., 2015. Odwodnienia dróg, ulic i mostów . Nowoczesne Budownictwo Inżynieryjne, 5, 48-52. Majer, S., 2016

ioduszewski W., K owalewski Z., Ż urawski R., S tankiewicz J. 2010. Drainage system in the Kampinos National Park. Journal of Water and Land Development. No. 14 p. 83–95. DOI 10.1515/jwld-2017-0056. R okochinskiy A., V olk P., P inchuk O., M endus S., K optyuk R. 2017. Comparative evaluation of various approaches to the foundation of parameters of agricultural drainage. Journal of Water and Land Development. No. 34 p. 215–220. R okochinskiy A.M., M uranov V.G., T ymeychuk O.Y., V olk P.P., M endus S.P., K optyuk R.M. 2013. Naukovo-metodichnі rekomendacіi do

vodopronicaemosti, kharaktera vodnogo pitaniya i uslovij rel'efa. In: Osushenie tyazhelykh pochv [Investigation of the parameters of closed drainage when drying loamy soils of different genetic types, taking into account their permeability, the nature of the water supply, and the conditions of the relief. In: Dewatering of heavy soils]. Moscow. Kolos p. 85-98. LAZARCHUK M.A., MURANOV V.G., CHERENKOV A.V., ROKOCHINSKIY A.M. 1989. Tekhnicheskie ukazaniya po optimizacii parametrov gorizontal'nogo drenazha na osnovanii ekonomiko-matematicheskogo rascheta pri proektirovanii osushitel

References Avakumović, D. 2005. Hydrotechnical melioration - Drainage. University of Belgrade, Faculty of Civil Engineering. Belgrade. (In Serbian) Barta, K. 2013. Inland excess water projection based on meteorological and pedological monitoring data on a study area located in the southern part of the Great Hungarian Plain. Journal of Environmental Geography 6 (3–4), 31–37. DOI: 10.2478/jengeo-2013-0004 Belić, S., Conić, J., Škorić, M., Stojšić, M., Šević, Đ., Stojiljković, D., Zdravić, M., Nešković-Zdravić, V. 1995. Land protection from excessive inland waters

Introduction The successful design and implementation of site-specific land drainage systems is dependent on fully characterising soil physical properties with regard to their drainage characteristics ( Martínez-Beltrán, 1988 ; Bos and Boers, 1994 ; Schultz et al ., 2007 ; Skaggs et al ., 2012 ). While methods for measuring relevant physical properties are long established ( Bouwer and Rice, 1983 ; Van Beers, 1983 ; BS 1377-5:1990 ), the implementation of site-specific design is often disregarded in favour of locally established drainage design practices

References BARAKAT, M.A.: New trends in removing heavy metals from industrial wastewater. Arab. J. Chem., 4, 2011, 361-377. COSTA, M.C., MARTINS, M., JESUS, C., DUARTE, J.C.: Treatment of acid mine drainage by sulphate-reducing bacteria using low cost matrices. Water Air Soil Pollut., 2008, 189, 149-162. DUARTE, J.C., SAAGUA, M.C., PAIXAO, S., BAETA-HALL, L., COSTA, C.: Sulphate reducing bacteria for metals bioremediation. Proceedings of the 4 th European BioRemedation Conference: E-proceedings. Chania, Crete, Greece, September 3-6, 2008, ID 117. ISBN 978