Dilatometer Test Calibrations for Evaluating Soil Parameters

Głuchowski, A. & Sas, W. (2020). Long-Term Cyclic Load-Long-Term Cyclic Loading Impact on the Creep Deformation Mechanism in Cohesive Materials. Materials, 13 (17), 3907. https://doi.org/10.3390/ma1317390710.3390/ma13173907 Search in Google Scholar

Godlewski, T. & Szczepański, T. (2012). Determination of soil stiffness parameters using in-situ seismic methods insight in repeatability and methodological aspects. In R.Q. Coutinho, P.W. Mayne (Eds.), Geotechnical and Geophysical Site Characterization 4: Proceedings of the 4th International Conference on Site Characterization (ISC-4, Pernambuco, Brazil, 2012) (Vol. 1, pp. 441– –446). London: CRC Press. Search in Google Scholar

Godlewski, T. & Szczepański, T. (2015). Measurement of soil shear wave velocity using in situ and laboratory seismic methods: some methodological aspects. Geological Quarterly, 59. https://doi.org/10.7306/gq.118210.7306/gq.1182 Search in Google Scholar

Joint Committee for Guides in Metrology [JCGM] (1993). Guide to Expression of Uncertainity in Measurement (ISO/IEC Guide 98:1993). Geneva: International Organization for Standardization. Search in Google Scholar

Katedra Geoinżynierii SGGW (2000–2005). Raporty pośrednie. Dokumentacja geotechniczna do projektów budynków na terenie kampusu SGGW w Warszawie z lat 2000–2005. Szkoła Główna Gospodarstwa Wiejskiego w Warszawie, Warszawa [unpublished]. Search in Google Scholar

Larsson, R. (1989). Dilatometer Försök för bedömning au jordagerföljd och egenskaper I jord. (Information 10). Linköping: Statens geotekniska institut. Search in Google Scholar

Larsson, R. & Åhnberg, H. (2003). Effekter av avschaktnin-gar vid släntkrön, Portryckssituation-Hållfasthetseg-enskaper – Stabilitet – Miljö (Rapport 61). Linköping: Statens geotekniska institut. Search in Google Scholar

Lech, M., Skutnik, Z., Bajda, M. & Markowska-Lech, K. (2020). Applications of electrical resistivity surveys in solving selected geotechnical and environmental problems. Applied Sciences, 10 (7), 2263. https://doi.org/10.3390/app1007226310.3390/app10072263 Search in Google Scholar

Lechowicz, Z., Rabarijoely, S. & Kutia, T. (2017). Determination of undrained shear strength and constrained modulus from DMT for stiff overconsolidated clays. Annals of Warsaw University of Life Sciences – SGGW. Land Reclamation, 49 (2), 107–116.10.1515/sggw-2017-0009 Search in Google Scholar

Marchetti, S. (1980). In Situ Tests by Flat Dilatometer. Journal of the Geotechnical Engineering Division, 106 (3), 299–321.10.1061/AJGEB6.0000934 Search in Google Scholar

Marchetti, S. (2015). Some 2015 updates to the TC16 DMT report 2001. In S. Marchetti, P. Monaco, A.V. da Fonseca (Eds.), International Conference on the Flat Dilatometer DMT’15 (pp. 43–65). [s.l.: s.n]. Search in Google Scholar

Marchetti, S. & Crapps, D. K. (1981). Flat dilatometer manual (report). Gainesville: GPE Inc. Search in Google Scholar

Młynarek, Z. & Wierzbicki, J. (2007). Nowe możliwości i problemy interpretacyjne polowych badań gruntów. Geologos, 11, 97–118. Search in Google Scholar

Młynarek, Z., Wierzbicki, J. & Stefaniak, K. (2018). Interre-Interrelationship between undrained shear strength from DMT and CPTU tests for soils of different origin. Geotechnical Testing Journal, 41 (5), 890–901. Search in Google Scholar

Polski Komitet Normalizacyjny [PKN] (1981). Grunty budowlane. Posadowienie bezpośrednie budowli. Obliczenia statyczne i projektowanie (PN-B-03020). Warszawa: Polski Komitet Normalizacyjny. Search in Google Scholar

Polski Komitet Normalizacyjny [PKN] (2007). Eurokod 7: Projektowanie geotechniczne. Część 2: Rozpoznawanie i badanie podłoża gruntowego (ENV 1997-2). Warszawa: Polski Komitet Normalizacyjny. Search in Google Scholar

Rabarijoely, S. (2018). Evaluation of correlation between Evaluation of correlation between parameters from CPTU and DMT tests and soil type behaviour chart. Annals of Warsaw University of Life Sciences – SGGW. Land Reclamation, 50 (4), 313–326.10.2478/sggw-2018-0025 Search in Google Scholar

Spitler, J. D., Yavuzturk, N. & Jain, N. (1999). Refinement and validation of in situ parameter estimation models (report). Stillwater, OK: Oklahoma State University. Search in Google Scholar

Tarnawski, M. (Ed.), 2020). Badanie podłoża budowli. Metody polowe. Warszawa: Wydawnictwo Naukowe PWN. Search in Google Scholar

Wierzbicki, G., Ostrowski, P., Bartold, P., Bujakowski, F., Falkowski, T. & Osiński, P. (2021). Urban geomorphol-Urban geomorphology of the Vistula River valley in Warsaw. Journal of Maps. https://doi.org/10.1080/17445647.2020.186669810.1080/17445647.2020.1866698 Search in Google Scholar

Zawrzykraj, Z. P. (2019). Zróżnicowanie właściwości fizy-cznych i mechanicznych iłów warwowych „zastoiska warszawskiego” w świetle badań terenowych. Warszawa: Wydawnictwa Uniwersytetu Warszawskiego.10.31338/uw.9788323537403 Search in Google Scholar