Основания, фундаменты и механика грунтов

Статья посвящена методам изучения механических свойств грунта нарушенной структуры, искусственно упрочненного цементацией. На основе лабораторных экспериментов исследована прочность на сжатие упрочненного глинистого грунта при различном процентном отношении цемента. Полученная структура искусственного грунтового материала исследована с использованием электронного микроскопа.

Полный текст статьи публикуется в английской версии журнала
«Soil Mechanics and Foundation Engineering”, vol.60, No.6

N. Miura, S. Horpibulsuk, and T. S. Nagaraj, "Engineering behavior of cement stabilized clay at high water content," Soils Found., 41(5), 33-45 (2008).

I. Develioglu, and H. F. Pulat, "Compressibility behaviour of natural and stabilized dredged soils in different organic matter contents," Constr. Build. Mater., 228, 116787 (2019).

N. T. T. Minh, R. Saeed, N. A. Brake, Q. Qin, K. Kyle, H. E. Crochet, O. Soheil, W. Remington, F. Joshua, and B. Brandon, "Stabilization of Silty Clayey Dredged Material," J. Mater. Civil Eng., 30(9), 04018199 (2018).

Y. H. Chen, W. L. Zhang, L. Y. Zhao, and Z. H. Peng, "Field in-situ stabilization of bored pile mud: Engineering properties and application for pavement," Constr. Build. Mater., 165, 541-547 (2018).

Y. H. Huang, C. Dong, C. L. Zhang, and K. Xu, "A dredged material solidification treatment for fill soils in East China: A case history," Mar. Georesour. Geotec., 35(6), 865-872 (2016).

Y. H. Chen, Y. Wang, X. Cheng, L. ;Chen, T. Y. Fu, and L. Ye, "Experimental study of new technologies using in situ stabilization treating dredger fill of coastal reclamation project," J. Hydraul. Eng., 46, 64-69 (2015).

N. C. Consoli, D. Foppa, L. Festugato, and K. S. Heineck, "Key Parameters for Strength Control of Artificially Cemented Soils," J. Geotech. Geoenviron., 133(2), 197-205 (2007).

R. J. Zhang, Y. T. Lu, T. S. Tan, K. K. Phoon, F. ASCE, and A. M. Santoso, "Long-Term Effect of Curing Temperature on the Strength Behavior of Cement-Stabilized Clay," J. Geotech. Geoenviron., 140(8), 1-12 (2019).

N. C. Consoli, G. V. Rotta, and P. D. M. Prietto, "Yielding–compressibility–strength relationship for an artificially cemented soil cured under stress," Geotechnique, 56(1), 69-72 (2006).

K. LEE, D. CHAN, and K. LAM, "Constitutive model for cement treated clay in a critical state framework," Soils Found., 44(3), 69-77 (2004).

A. J. Quiroga, Z. M. Thompson, K. K. Muraleetharan, G. A. Miller, and A. B. Cerato, "Stress–strain behavior of cement-improved clays: testing and modeling," Acta Geotech., 11(5), 1003-1020 (2017).

R. Zhang, J. Zheng, and X. Bian, "Experimental investigation on effect of curing stress on the strength of cement-stabilized clay at high water content," Acta Geotech., 12(4), 921-936 (2016).

W. Zhu, Y. H. Huang, C. L. Zhang, and Q. S. Liu, "Effect of Curing Time on Mechanical Behavior of Crushed Solidified Dredged Material," Constr. Build. Mater., 179, 597-604 (2008).

Y. H. Huang, W. Zhu, X. D. Qian, N. Zhang, and X. Z. Zhou, "Change of mechanical behavior between solidified and remolded solidified dredged materials," Eng. Geol., 119(3-4), 112-119 (2011).

A. Diambra, E. Ibraim, A. Peccin, N. C. Consoli, and L. Festugato, "Theoretical Derivation of Artificially Cemented Granular Soil Strength," J. Geotech. Geoenviron., 143(5), 1-9 (2017).

Z. Zhao, J. Xu, Y. Chen, G. Chen, B. Wang, and B. Li, "Experimental study on influence of compaction period on strength of solidified soil," J. Hohai Univ., 44(6), 531-535 (2016).