Hazards Resulting from Improper Building Drainage System By the Use of BIM

Koda, E., Matusiewicz, W. & Osiński, P. (2017). Niesprawność systemów odwadniających w obiektach budowlanych. In M. Kaszyńska (Ed.), Monografia awarie budowlane: zapobieganie, diagnostyka, naprawy, rekonstrukcje (pp. 411–422). Szczecin: Wydawnictwo Uczelniane Zachodniopomorskiego Uniwersytetu Technologicznego w Szczecinie.Search in Google Scholar

Matusiewicz, W. (2003). Performance of storm water system in urban catchment under conditions of heavy rainfall. Acta Sci. Pol. Architectura, 2 (2), 83–96.Search in Google Scholar

Matusiewicz, W. (2011). Safety abatement of building foundation caused by incorrect method of dewatering. Scientific Review – Engineering and Environmental Sciences, 20 (4), 344–354.Search in Google Scholar

Matusiewicz, W. (2013). Foundation walls drying and de-watering of soil adjacent to the Ursyn Niemcewicz Palace. Scientific Review – Engineering and Environmental Sciences, 22 (2), 208–221.Search in Google Scholar

Matusiewicz, W. (2015). Dewatering of sanitary installations located under building basement. Scientific Review – Engineering and Environmental Sciences, 24 (3), 286–300.Search in Google Scholar

Matusiewicz, W. & Wrzesiński, G. (2018). Drainage of the depression area in a small urban catchment. Acta Sci. Pol. Architectura, 17 (3), 131–144. doi: 10.22630/ASPA.2018.17.3.3510.22630/ASPA.2018.17.3.35Search in Google Scholar

Mielcarzewicz, E. (1971). Melioracje terenów miejskich i przemysłowych. Warszawa: Arkady.Search in Google Scholar

Patel, A. (2019). Geotechnical Investigations and Improvement of Ground Conditions. doi: 10.1016/B978-0-12-817048-9.00004-410.1016/B978-0-12-817048-9.00004-4Search in Google Scholar

Pawluk, K., Wrzesiński, G. & Lendo-Siwicka, M. (2017). Strength and numerical analysis in the design of permeable reactive barriers. IOP Conference Series: Materials Science and Engineering, 245, 1–8.10.1088/1757-899X/245/5/052017Search in Google Scholar

Thomas, S., Goodfellow, T. & Watson, J. (2019). Ground-water Recharge Systems to Mitigate the Impact from Construction Dewatering. In J. Monteiro, A.J. Silva, A. Mortal, J. Aníbal, M. M. da Silva, M. Oliveira & N. Sousa (Eds.), INCREaSE 2019. Proceedings of the 2nd International Congress on Engineering and Sustainability in the XXI Century (pp. 757–765). Cham: Springer.Search in Google Scholar

Todd, D. (1980). Groundwater Hydrology. 2nd ed. Chichester: John Wiley & Sons.Search in Google Scholar

Wrzesiński, G. (2020). Permeability coefficient tests in non-cohesive soils. Scientific Review – Engineering and Environmental Sciences, 29 (1), 72–80. doi: 10.22630/PNIKS.2020.29.1.710.22630/PNIKS.2020.29.1.7Search in Google Scholar

Wrzesiński, G., Kowalski, J. & Miszkowska, A. (2018). Numerical analysis of dewatering process of deep excavation. In 18th International Multidisciplinary Scientific GeoConference (SGEM 2018): Hydrogeology, Engineering Geology and Geotechnics. Science and Technologies in Geology, Exploration and Mining Conference Proceedings. Issue 1.2 (pp. 497–504). Sofia: International Multidisciplinary Scientific GeoConferences (SGEM).Search in Google Scholar

Zaborova, D. D. & Petrichenko M. R. (2018). Technology of rapid dewatering for excavations. In M. A. Ali & P. Platko (Eds.), Advances and Trends in Engineering Sciences and Technologies III (pp. 663–668). London: CRC Press. doi: 10.1201/978042902159610.1201/9780429021596Search in Google Scholar