Rock and Soil Mechanics ›› 2020, Vol. 41 ›› Issue (4): 1203-1210.doi: 10.16285/j.rsm.2019.0740

• Fundamental Theroy and Experimental Research • Previous Articles     Next Articles

Optimization of requirement for two kinds of ash solidified materials used in oil contaminated saline soil considering temperature sensitivity

LI Min1, 2,MENG De-jiao3,YAO Xin-yu1   

  1. 1. School of Civil Engineering, Hebei University of Technology, Tianjin 300401, China; 2. Hebei Research Center of Civil Engineering Technology, Hebei University of Technology, Tianjin 300401, China; 3. Tianjin Chenchuang Environment Engineering Science & Technology Co., Ltd., Tianjin 300400, China
  • Received:2019-04-24 Revised:2019-06-26 Online:2020-04-11 Published:2020-07-01
  • Supported by:
    This work was supported by the National Natural Science Foundation of China (51978235), the Natural Science Foundation of Hebei Province (E2018202274) and the Natural Science Foundation of Tianjin (17JCZDJC39200).

PDF (Chinese)

133

Abstract: Temperature is an important factor that affects properties of oil contaminated soil. This study considered the special characteristics of the climate environment in the coastal area and used unconfined compressive strength and stress-strain distribution to optimize the requirement for two kinds of ash solidified materials, and the temperature sensitivity was used as an evaluation criterion. Results indicate that the compressive strength of the oil contaminated soil significantly fluctuates, and it is up to two times in the temperature range of -20?40 °C. However, the fluctuation reduces to 10%?20% after soil solidification with two kinds of ash. Solidified materials can adsorb and enclose the temperature sensitive substances (oil, water and salt) in the gel body and even outside, and then it can enhance the resistance to the variation of environmental temperature. The unconfined compressive strengths of oil contaminated soil and solidified soil decrease first and then increase with the increasing of temperature, and 10 °C is the turning point, which is the lowest point. The results suggest that this temperature should be of particular concern in practical engineering. Under the action of temperature, the failure mode of solidified oil contaminated soil is strain-softening. With the increase of temperature and the contaminated level, the plastic deformation stage is prolonged, and the axial strain gradually increases. Finally, the surrounding layered damage occurs. The contaminated level of soil itself affects the solidified effect, and the fluctuation of compressive strength under a high level of contamination is about 40%. Therefore, in actual engineering, the solidified requirement should be adjusted according to the contaminated level. As to the soil with low contamination, the solidified requirement is only slightly higher than that of the uncontaminated soil, and too much solidification for the soil with low contamination is often counterproductive. Lime has more contribution than fly ash to soil stability under the same additive to soil ratio. As to the oil-contaminated saline soil with 6% contamination, the optional solidified condition is 10% lime +20% fly ash.

Key words: temperature sensitivity, solidified oil contaminated soil, unconfined compressive strength, stress-strain curve

CLC Number: 

  • TU 43
[1] WU Jun, ZHENG Xi-yao, YANG Ai-wu, LI Yan-bo. Experimental study on the compressive strength of muddy clay solidified by the one-part slag-fly ash based geopolymer [J]. Rock and Soil Mechanics, 2021, 42(3): 647-655.
[2] LIU Hai-feng, ZHENG Kun, ZHU Chang-qi, MENG Qing-shan, WU Wen-juan. Brittleness evaluation of coral reef limestone base on stress-strain curve [J]. Rock and Soil Mechanics, 2021, 42(3): 673-680.
[3] GAO Yun-chang, GAO Meng, YIN Shi, . Experiments on static characteristics of sea sand solidified by polyurethane [J]. Rock and Soil Mechanics, 2019, 40(S1): 231-236.
[4] SHEN Tai-yu, WANG Shi-ji, XUE Le, LI Xian, HE Bing-hui, . An experimental study of sandy clayey purple soil enhanced through microbial-induced calcite precipitation [J]. Rock and Soil Mechanics, 2019, 40(8): 3115-3124.
[5] WANG Juan-juan, HAO Yan-zhou, WANG Tie-hang. Experimental study of structural characteristics of unsaturated compacted loess [J]. Rock and Soil Mechanics, 2019, 40(4): 1351-1357.
[6] ZHA Fu-sheng, LIU Jing-jing, XU Long, DENG Yong-feng, YANG Cheng-bin, CHU Cheng-fu, . Electrical resistivity of heavy metal contaminated soils solidified/stabilized with cement-fly ash [J]. Rock and Soil Mechanics, 2019, 40(12): 4573-4580.
[7] YANG Ai-wu, HU Yao, YANG Shao-kun, . New solidification technology and mechanical properties of municipal sludge [J]. Rock and Soil Mechanics, 2019, 40(11): 4439-4449.
[8] SONG Hong-qiang, ZUO Jian-ping, CHEN Yan, LI Li-yun, HONG Zi-jie, . Revised energy drop coefficient based on energy characteristics in whole process of rock failure [J]. Rock and Soil Mechanics, 2019, 40(1): 91-98.
[9] FANG Xiang-wei, LI Jing-xin, LI Jie, SHEN Chun-ni,. Study of triaxial compression test and damage constitutive model of biocemented coral sand columns [J]. , 2018, 39(S1): 1-8.
[10] HUANG Zheng-hong, DENG Shou-chun, LI Hai-bo, YU Chong,. Tensile tests on plate specimens with bilateral asymmetric cracks [J]. , 2018, 39(S1): 267-274.
[11] ZHANG Ting-ting, WANG Ping, LI Jiang-shan, WAN Yong, XUE Qiang, WANG Shi-quan, . Effect of curing time and lead concentration on mechanical properties of lead-contaminated soils stabilized by magnesium phosphate cement [J]. , 2018, 39(6): 2115-2123.
[12] CHEN Wei-chang, WANG Si-jing, LI Li, ZHANG Xiao-ping, WANG Yan-bing, . Test on mechanical characteristics of modified ginger nut [J]. , 2018, 39(5): 1796-1804.
[13] ZHANG Ding-wen, XIANG Lian, CAO Zhi-guo, . Effect of CaO on ettringite stabilization/solidification of lead-contaminated soil [J]. , 2018, 39(1): 29-35.
[14] JIA Jun, XIAO Ben-lin, KE Chang-ren. Simulation of three-dimensional homogeneous rock constitutive relation based on virtual internal bond model [J]. , 2017, 38(3): 740-746.
[15] LIU Jin-ming, OU Zhong-wen, XIAO Han-bing, MO Jin-chuan, YANG Kang-hui. Early strength of stabilized soil affected by functional components [J]. , 2017, 38(3): 755-761.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
[1] SHI Yu-ling, MEN Yu-ming, PENG Jian-bing, HUANG Qiang-bing, LIU Hong-jia. Damage test study of different types structures of bridge decks by ground-fissure[J]. , 2009, 30(10): 2917 -2922 .
[2] ZHANG Li-ting, QI Qing-lan, WEI Jing HUO Qian, ZHOU Guo-bin. Variation of void ratio in course of consolidation of warping clay[J]. , 2009, 30(10): 2935 -2939 .
[3] ZHANG Qi-yi. Study of failure patterns of foundation under combined loading[J]. , 2009, 30(10): 2940 -2944 .
[4] ZHANG Ming-yi, LIU Jun-wei, YU Xiu-xia. Field test study of time effect on ultimate bearing capacity of jacked pipe pile in soft clay[J]. , 2009, 30(10): 3005 -3008 .
[5] WU Liang, ZHONG Dong-wang, LU Wen-bo. Study of concrete damage under blast loading of air-decking[J]. , 2009, 30(10): 3109 -3114 .
[6] ZHOU Xiao-jie, JIE Yu-xin, LI Guang-xin. Numerical simulation of piping based on coupling seepage and pipe flow[J]. , 2009, 30(10): 3154 -3158 .
[7] WU Chang-yu, ZHANG Wei, LI Si-shen, ZHU Guo-sheng. Research on mechanical clogging mechanism of releaf well and its control method[J]. , 2009, 30(10): 3181 -3187 .
[8] CUI Hao-dong, ZHU Yue-ming. Back analysis of seepage field of Ertan high arch dam foundation[J]. , 2009, 30(10): 3194 -3199 .
[9] JIA Yu-feng,CHI Shi-chun,LIN Gao. Constitutive model for coarse granular aggregates incorporating particle breakage[J]. , 2009, 30(11): 3261 -3266 .
[10] NI Xiao-hui,ZHU Zhen-de,ZHAO Jie,LI Dao-wei,FENG Xia-ting. Meso-damage mechanical digitalization test of complete process of rock failure[J]. , 2009, 30(11): 3283 -3290 .
Copyright © Rock and Soil Mechanics, All Rights Reserved.
Tel: 027-87198484, 87199252, 87199253, 87198752 E-mail: ytlx@whrsm.ac.cn
Powered by Beijing Magtech Co. Ltd