Journal of Jilin University(Engineering and Technology Edition) ›› 2023, Vol. 53 ›› Issue (6): 1809-1818.doi: 10.13229/j.cnki.jdxbgxb.20221376

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Unconfined compression behavior of modified lime stabilized soil under dry wet and freeze⁃thaw cycles

Ping JIANG1,2(),Ye-wen CHEN2,Xian-hua CHEN1(),Wei-qing ZHANG2,3,Na LI2,Wei WANG2   

  1. 1.School of Transportation,Southeast University,Nanjing 210096,China
    2.School of Civil Engineering,Shaoxing University,Shaoxing 312000,China
    3.Guangdong Architectural Design and Research Institute Co. ,Ltd. ,Guangzhou 510010,China
  • Received:2022-10-27 Online:2023-06-01 Published:2023-07-23
  • Contact: Xian-hua CHEN E-mail:jiangping@usx.edu.cn;chenxh@seu.edu.cn

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Abstract:

In order to further improve the applicability and safety of lime stabilized soil in complex environmental engineering, the mechanical properties of lime stabilized soil modified by nano clay and fiber were studied. By analyzing the unconfined compression behavior of modified lime stabilized soil under the action of dry wet cycle and freeze-thaw cycle, the modified effect of nano clay and fiber on lime stabilized soil can be judged. The test results show that fiber and nano clay can improve the compressive strength and residual strength of lime stabilized soil, increase the failure strain and change the failure mode. Especially, under the combined action of fiber and nano clay, nano clay/fiber modified lime soil (NFLS) presents the best unconfined compression behavior, and can delay the internal damage of NFLS caused by dry wet cycle and freeze-thaw cycle.

Key words: road engineering, modified lime stabilized soil, freeze thaw cycle, dry wet cycle, unconfined compression behavior

CLC Number: 

  • TU447

Fig.1

Material object drawing"

Table 1

Experimental scheme of modified lime stabilized soil under different ratio combination"

组号试样序号配比组合冻融循环次数干湿循环次数养护龄期/d
A1~5L60、1、3、5、70、1、3、5、728
B6~10L6-N6
C11~15L6-F0.5
D16~20L6-N4-F0.75

Fig.2

Sample making process"

Fig.3

Stress-strain curves of modified lime soil with different ratio combinations under freeze-thaw cycle"

Fig.4

Unconfined compressive strength of different modified lime soils with the number of freeze-thaw cycles"

Fig.5

Stress-strain curves of modified lime soil"

Fig.6

Variation of unconfined compressive strength of different modified lime stabilized soils with the number of wet-dry cycles"

Fig.7

Residual strength of different modified lime stabilized soil with the number of freeze-thaw cycles"

Table 2

Failure strain in unconfined compressive strength test of different modified lime stabilized soils %"

冻融循环次数L6L6-N6L6-F0.5L6-N4-F0.75
01.892.233.223.89
12.562.563.894.23
34.572.884.904.90
53.222.883.906.23
73.232.882.884.57

Fig.8

Residual strength of different modified lime stabilized soils with dry-wet cycles"

Table 3

Failure strain in unconfined compressive strength test of different modified lime stabilized soils %"

干湿循环次数L6L6-N6L6-F0.5L6-N4-F0.75
01.892.233.223.89
12.562.563.904.23
32.902.224.573.23
52.902.564.904.24
72.562.224.574.23

Table 4

Strain energy density of various lime soils under freeze-thaw cycles"

冻融循环次数L6L6-N6L6-F0.5L6-N4-F0.75
016.5530.8840.1663.13
122.2931.6545.1261.84
331.4225.5237.1841.92
54.5917.3318.7737.58
72.3510.7314.5219.47

Table 5

Strain energy density of various lime soils under dry-wet cycles"

干湿循环次数L6L6-N6L6-F0.5L6-N4-F0.75
016.5530.8840.1663.13
123.5035.1850.1361.84
321.2827.7747.0565.15
514.8324.4638.9654.41
712.6523.5232.2852.42
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