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In this paper authors have described the analytical method of continuous static load test Q-s curve conversion for any given pile. Authors have used data sets from static load tests conducted by Energopol Szczecin S.A. in a full range of loads which allows to use of measured values of pile maximum bearing capacity and determine relation between it and pile length and diameter. All the piles used in this paper were CFA piles bored in mostly loam soil conditions. The research described in this work was based on the Meyer-Kowalow method (M-K method) of static load test interpretation. The M-K method allows for a full description of the load-settlement relation, as a continuous curve (M-K curve) using three parameters that described pile-soil interaction. As a result of conducted research relations between parameters describing M-K curve and pile dimensions were established, which allows for a practical application of the proposed method. In this paper, the authors presented an example of the practical use of curve conversion to analyze the impact of changes in geometric dimensions on pile-soil interaction. The proposed method allows for a curve conversion of the total resistance curve, as well as a curve describing base and skin resistances.
Czasopismo
Rocznik
Tom
Strony
119--126
Opis fizyczny
Bibliogr. 19 poz.
Twórcy
autor
- Prof.; West Pomeranian University of Technology in Szczecin, Faculty of Civil and Environmental Engineering,al. Piastów 50a, 70-311 Szczecin, Poland
autor
- PhD; Koszalin University of Technology, Faculty of Civil, Environmental Engineering and Geodesy,ul. Śniadeckich 2, 75-453 Koszalin, Poland
Bibliografia
- [1] Stachecki, K. (2022). Analiza możlwiości konwersji krzywej próbnego statycznego obciążenia pala przy zmianie jego geometrii (Analysis of pile static load test curve conversion possibilities in case of changed geometry) (PhD thesis, West Pomeranian University of Technology in Szczecin). Poland, Szczecin
- [2] Briaud, J. (2013). Geotechnical Engineering. Unsaturated and saturated soils. New Jersey: John Wiley & sons.
- [3] Hansen, J.B. (1961). A general formula for bearing capacity. Danish Geotechnical Institute Bulletin, 28, 5–11.
- [4] Chin, F.K. (1970). Estimation of the Ultimate load of piles not carried to failure. Proceeding of 2nd Southeast Asia Conference on Soil Engineering, 81–70.
- [5] Coyle, H.M, Reese, L.C. (1966). Load transfer for axially loaded piles in clay. Journal of the Soil Mechanics and Foundation Division. ASCE., 92, 1–26.
- [6] Dung, N.T., Kim, S.R. (2007). Comparative study between design methods and pile load tests for bearing capacity of driven PHC piles in Nakdong river delta. Journal of the Korean Geotechnical Society, 23(3), 61–75.
- [7] Gwizdała, K. (2010). Fundamenty Palowe (Pile foundations). Warszawa: Państwowe Wydawnictwo Naukowe.
- [8] Meyer, Z., Kowalow, M. (2010). Model krzywej aproksymującej wyniki testów statycznych pali (Model of curve approximating static load test results). Inżynieria Morska i Geotechnika, 3, 438–446.
- [9] Szmechel, G. (2014). Określenie nośności granicznej pali na podstawie próbnych obciążeń statycznych w ograniczonym zakresie (Determination of the pile maximum bearing capaciy based on static load tests in limited range) (PhD thesis, West Pomeranian University of Technology in Szczecin). Poland, Szczecin.
- [10] Meyer, Z., Wasiluk, A. (2019). Weryfikacja krzywej Meyera-Kowalowa w oparciu o wyniki eksperymentalne oraz kolejny etap analizy niedokładności pomiarów testu statycznego pala (Verification of Meyer-Kowalow curve based on experimental test results and the next stage of the analysis of the inaccuracy of the pile static load tests). Inżynieria Morska i Geotechnika, 6, 315–323.
- [11] Meyer, Z., Stachecki, K. (2020). Analysis of static load test referred to limit the bearing capacity of a pile. IOP Conference Series: Materials Science and Engineering doi: 10.1088/1757-899X/960/2/022101.Otwórz DOI
- [12] Meyer, Z. (2017). Wykorzystanie wyników testu statycznego pala do określenia mobilizacji oporu podstawy i pobocznicy (Using static load test results to determine mobilization of base and skin resistance) XXXII Warsztaty Pracy Projektanta Konstrukcji, 315–323.
- [13] Meyer, Z., Żarkiewicz, K. (2018). Skin and toe resistance mobilization of pile during laboratory static load test. Studia Geotechnica et Mechanica, 40(1), 1–5.
- [14] Żarkiewicz, K. (2017). Analiza formowania się oporu pobocznicy pala w gruntach niespoistych na podstawie modelowych badań laboratoryjnych (Analysis of pile skin resistance formation in non-cohesive soils based on model laboratory tests) (PhD thesis, West Pomeranian University of Technology in Szczecin). Poland, Szczecin.
- [15] Meyer, Z., Stachecki, K. (2018). Static load test curve (Q-s) conversion in to pile of differnet size. Annals of Warsaw University of Life Sciences, 50(2), 171–182.
- [16] Meyer, Z., Stachecki, K. (2021). Analiza konwesrji krzywej próbnego statycznego obciążenia pala przy zmianie średnicy oraz długości (Analysis of static load test curve convesrion for a changed length and diameter). Mosty, 3, 22/25.
- [17] Meyer, Z., Siemaszko, P. (2019). Static load test curve analysis based on soil field investigations. Bulletin of Polish Academy of Sciences. Technical Sciences, 67(2), 329–337.
- [18] Dembicki, E. (1988). Fundamentowanie. Projektowanie i wykonawstwo. Tom 2. Posadowienie budowli (Foundations. Design and execution. Vol. 2. Foundation of buildings), Arkady.
- [19] Stachecki, K. (2020). Analiza nośności granicznej pala z wykorzystaniem wyników tesów statycznych (Analysis of pile maximum bearing capacity based on static load test results) Współczesne zagadnienia z Inżynierii lądowej, Wydawnictwo Politechniki Śląskiej, 197–203.
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Bibliografia
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