Behavior of geosynthetic-encased stone column reinforced foundation under freeze-thaw cycles

IF 4.7 1区 工程技术 Q1 ENGINEERING, GEOLOGICAL
Zi-Ang Gu , Chungsik Yoo , Jian-Feng Chen
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Abstract

In this paper, an experiment study was carried out to identify the fundamental behavior of geosynthetic-encased stone column (GESC) reinforced foundation under freeze-thaw cycles. Three loading tests under four freeze-thaw cycles were considered. A 10-m thick reinforced foundation unit consisted of four floating GESCs with 2.5-m underlain clay layer, and the foundations were preconsolidated to three different initial degrees of consolidation (U = 1.0, 0.6 and 0.3, respectively). The results showed that soil near GESCs had a larger frozen depth due to the excellent heat transfer ability of GESCs. An extra uneven subsidence of soil also appeared around GESCs. Voids could be found between foundation soil and the loading plate after thawing, which indicated that only GESCs carried the overburden pressure. The GESCs showed outward bending under lower initial degree of consolidation, while inward bending under higher one. A bulging failure was observed on frozen part of GESCs, especially at the connection of encasement in foundation with lower initial degree of consolidation. In the first freezing process, a rapid decrease in frost heave force was noticed, inferring the fracture of frozen soil. The stress on GESC was found to almost have no change until complete freezing, when the soil was freezing and the stress on soil exceeded that on GESC. Negative pore pressure was observed in the foundation soil, and the absolute value decreased with the increasing overburden pressure. Both the peak positive and negative pore pressures were reduced as the foundation was preconsolidated to a higher degree. The freeze-thaw cycles were also found to generate excess pore pressure in soil during thawing. Moisture migration was also analyzed using Electrical Resistivity Tomography (ERT) method, and the results showed that moisture tended to go upwards and outside the reinforced unit from thawing to freezing, while downwards and inside the unit from freezing to thawing.

土工合成材料包裹石柱加固地基在冻融循环下的行为
本文开展了一项实验研究,以确定土工合成材料包裹石柱(GESC)加固地基在冻融循环下的基本行为。研究考虑了四次冻融循环下的三次加载试验。一个 10 米厚的加固地基单元由四根漂浮的土工合成材料包裹石柱和 2.5 米厚的下覆粘土层组成,地基预固结为三种不同的初始固结度(分别为 U = 1.0、0.6 和 0.3)。结果表明,由于 GESC 具有良好的传热能力,因此 GESC 附近土壤的冻结深度较大。GESC 周围的土壤还出现了额外的不均匀沉降。解冻后,地基土与加载板之间出现了空隙,这表明只有 GESC 承载了覆土压力。在初始固结度较低的情况下,GESC 向外弯曲,而在初始固结度较高的情况下,GESC 向内弯曲。在初始固结度较低的情况下,GESC 的冻结部分出现了隆起破坏,尤其是在地基中包层的连接处。在第一次冻结过程中,发现冻胀力迅速减小,推断冻土断裂。在土壤完全冻结之前,GESC 上的应力几乎没有变化,当土壤冻结时,土壤上的应力超过了 GESC 上的应力。在地基土中观察到负孔隙压力,其绝对值随着覆土压力的增加而减小。地基预固结程度越高,正负孔隙压力峰值越小。冻融循环也会在土壤解冻时产生过大的孔隙压力。此外,还使用电阻率断层扫描(ERT)方法分析了湿气迁移情况,结果表明,从解冻到冻结,湿气倾向于向上并流向加固单元外部,而从冻结到解冻,湿气则倾向于向下并流向加固单元内部。
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来源期刊
Geotextiles and Geomembranes
Geotextiles and Geomembranes 地学-地球科学综合
CiteScore
9.50
自引率
21.20%
发文量
111
审稿时长
59 days
期刊介绍: The range of products and their applications has expanded rapidly over the last decade with geotextiles and geomembranes being specified world wide. This rapid growth is paralleled by a virtual explosion of technology. Current reference books and even manufacturers' sponsored publications tend to date very quickly and the need for a vehicle to bring together and discuss the growing body of technology now available has become evident. Geotextiles and Geomembranes fills this need and provides a forum for the dissemination of information amongst research workers, designers, users and manufacturers. By providing a growing fund of information the journal increases general awareness, prompts further research and assists in the establishment of international codes and regulations.
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