|Table of Contents|

Experimental Study on Deformation Characteristics of Existing High-speed Railway Subgrade in Coarse Saline Soil Area(PDF)

《建筑科学与工程学报》[ISSN:1673-2049/CN:61-1442/TU]

Issue:
2022年02期
Page:
135-142
Research Field:
基础工程
Publishing date:

Info

Title:
Experimental Study on Deformation Characteristics of Existing High-speed Railway Subgrade in Coarse Saline Soil Area
Author(s):
ZHANG Sha-sha1 LIU Ya-chao1 YANG Xiao-hua1 CHEN Wei-zhi2 JIN Hao-qian1
(1. School of Highway, Chang'an University, Xi'an 710064, Shaanxi, China; 2. China Railway Eryuan Engineering Group Co.Ltd, Chengdu 610031, Sichuan, China)
Keywords:
high-speed railway subgrade engineering collapse characteristic freeze thaw cycle model test
PACS:
TU448
DOI:
10.19815/j.jace.2021.04026
Abstract:
In order to explore the deformation characteristics of an existing high-speed railway subgrade, the basic physical and chemical tests of the subgrade filler were carried out, and the basic engineering properties such as particle size distribution, maximum dry density, optimum moisture content and soluble salt content were obtained. Then, the typical subgrade filler was selected to carry out indoor single cooling salt expansion test, collapse test, freeze-thaw cycle test and field large-scale collapse test. The results show that the maximum salt expansion rate of the subgrade soil in a single cooling test is 0.96%. There is a linear relationship between the maximum salt expansion deformation and the soil sample coefficient of uniformity. The final salt expansion of soil sample depends on the grading of soil sample and the content of sulfate ion to a large extent. The maximum collapse coefficient of soil sample under the most unfavorable condition is 0.012, the final collapse of K87+950 section is the largest, which is 5.67 mm, and the maximum deformation rate is 4.7%. The subgrade deformation of K87+950 section presents a V type downward trend with the change of temperature, and the relative thaw settlement reaches the maximum in the fifth freeze-thaw cycle. The sulfate ion presents a M type distribution along the soil sample height after the seventh freeze-thaw cycle.The moisture content at the top of the soil sample near the refrigeration head increases obviously, while the moisture content at the bottom decreases. The moisture content of the soil sample has no obvious change in the height range of 20-40 cm, and the salt expansion deformation is the largest in the range of 15-30 cm from the top of the soil sample. According to the field collapse test, when the water injection amount reaches 30 mm, the collapse amount of K31+000 test point subgrade can reach 80% of the final collapse amount, and extreme rainfall will not cause large collapse deformation of the subgrade.

References:

[1] 费雪良,李 斌,王家澄.不同密度硫酸盐渍土盐胀规律的试验研究[J].冰川冻土,1994,16(3):245-250.
FEI Xue-liang,LI Bin,WANG Jia-cheng.Experimental Researches on Salt Heaving of Sulphate Treated Soil with Different Dry Densities[J].Journal of Glaciology and Geocryology,1994,16(3):245-250.
[2]张莎莎,杨晓华,戴志仁.基于均匀设计的砾类硫酸盐渍土盐胀特性试验研究[J].公路交通科技,2009,26(5):29-34.
ZHANG Sha-sha,YANG Xiao-hua,DAI Zhi-ren.Experimental Study on Salt Expansion of Gravel Sulfate Salty Soil Based on Uniform Design[J].Journal of Highway and Transportation Research and Development,2009,26(5):29-34.
[3]张莎莎,杨晓华,王 龙.单因素对粗粒盐渍土的盐胀规律影响效果研究[J].水利学报,2015,46(增1):129-134.
ZHANG Sha-sha,YANG Xiao-hua,WANG Long.Research on the Law of Salt Expansion of Crude Coarse Grained Saline Soil with the Changing of Single Factors[J].Journal of Hydraulic Engineering,2015,46(S1):129-134.
[4]张莎莎,谢永利,杨晓华,等.典型天然粗粒盐渍土盐胀微观机制分析[J].岩土力学,2010,31(1):123-127.
ZHANG Sha-sha,XIE Yong-li,YANG Xiao-hua,et al.Research on Microstructure of Crude Coarse Grain Saline Soil Under Freezing and Thawing Cycles[J].Rock and Soil Mechanics,2010,31(1):123-127.
[5]张莎莎,戴志仁,杨晓华,等.上覆荷载对砾砂类硫酸盐渍土路基盐胀的影响[J].中国铁道科学,2019,40(2):1-8.
ZHANG Sha-sha,DAI Zhi-ren,YANG Xiao-hua,et al.Effect of Overburden Load on Salt Expansion of Gravelly Sand Sulfate Saline Soil Subgrade[J].China Railway Science,2019,40(2):1-8.
[6]张莎莎,王旭超,杨晓华,等.含盐施工用水对路基填料工程特性的累加效应[J].交通运输工程学报,2020,20(6):71-81.
ZHANG Sha-sha,WANG Xu-chao,YANG Xiao-hua,et al.Cumulative Effect of Saline Construction Water on Engineering Properties of Subgrade Filling Material[J].Journal of Traffic and Transportation Engineering,2020,20(6):71-81.
[7]ZHANG M Y,ZHANG X Y,LAI Y M,et al.Variations of the Temperatures and Volumetric Unfrozen Water Contents of Fine-grained Soils During a Freezing-thawing Process[J].Acta Geotechnica,2020,15(3):595-601.
[8]LAI Y M,WAN X S,ZHANG M Y.An Experimental Study on the Influence of Cooling Rates on Salt Expansion in Sodium Sulfate Soils[J].Cold Regions Science and Technology,2016,124:67-76.
[9]XIAO Z A,LAI Y M,YOU Z M,et al.The Phase Change Process and Properties of Saline Soil During Cooling[J].Arabian Journal for Science and Engineering,2017,42(9):3923-3932.
[10]包卫星,张莎莎.路用砂类盐渍土盐胀及融陷特性试验研究[J].岩土工程学报,2016,38(4):734-739.
BAO Wei-xing,ZHANG Sha-sha.Experimental Study on Salt Expansion and Thawing Subsidence Properties of Sandy Saline Soil[J].Chinese Journal of Geotechnical Engineering,2016,38(4):734-739.
[11]杨晓华,张志萍,张莎莎.高速公路盐渍土地基溶陷特性离心模型试验[J].长安大学学报(自然科学版),2010,30(2):5-9.
YANG Xiao-hua,ZHANG Zhi-ping,ZHANG Sha-sha.Centrifugalize Model Test on Dissolve Collapse of Saline Soil Under Expressway[J].Journal of Chang'an University(Natural Science Edition),2010,30(2):5-9.
[12]肖泽岸,赖远明.冻融和干湿循环下盐渍土水盐迁移规律研究[J].岩石力学与工程学报,2018,37(增1):3738-3746.
XIAO Ze-an,LAI Yuan-ming.Study on Water and Salt Transfer Mechanism in Saline Soil Under Freezing-thawing and Dry-wet Conditions[J].Chinese Journal of Rock Mechanics and Engineering,2018,37(S1):3738-3746.
[13]肖泽岸,赖远明,尤哲敏.冻融循环作用下含盐量对Na2SO4土体变形特性影响的试验研究[J].岩土工程学报,2017,39(5):953-960.
XIAO Ze-an,LAI Yuan-ming,YOU Zhe-min.Experimental Study on Impact of Salt Content on Deformation Characteristics of Sodium Sulfate Soil Under Freeze-thaw Conditions[J].Chinese Journal of Geotechnical Engineering,2017,39(5):953-960.
[14]ZHANG S S,ZHANG J S,GUI Y L,et al.Deformation Properties of Coarse-grained Sulfate Saline Soil Under the Freeze-thaw-precipitation Cycle[J].Cold Regions Science and Technology,2020,177:103121.
[15]ZHANG S S,YANG X H,XIE S J,et al.Experimental Study on Improving the Engineering Properties of Coarse Grain Sulphate Saline Soils with Inorganic Materials[J].Cold Regions Science and Technology,2020,170:102909.
[16]文 桃,米海珍,马连生,等.硫酸钠盐渍土击实特性与压实度评价试验研究[J].岩土力学,2016,37(12):3455-3462,3471.
WEN Tao,MI Hai-zhen,MA Lian-sheng,et al.Experiment and Evaluation of Compaction Characteristics of Sodium Sulfate Saline Soil[J].Rock and Soil Mechanics,2016,37(12):3455-3462,3471.
[17]张建渊,胡海东,沈 鑫.兰新高速铁路沿线盐渍土地基的溶陷特性[J].铁道建筑,2018,58(3):59-63.
ZHANG Jian-yuan,HU Hai-dong,SHEN Xin.Collapsibility Characteristics of Saline Soil Foundation in Lanzhou-Xinjiang High Speed Railway[J].Railway Engineering,2018,58(3):59-63.
[18]张沛然,黄雪峰,杨校辉,等.盐渍土水-热场耦合效应与盐胀变形试验[J].岩土力学,2018,39(5):1619-1624.
ZHANG Pei-ran,HUANG Xue-feng,YANG Xiao-hui,et al.Experiment on Coupling Effect of Water and Thermal Field and Salt-expansion Deformation of Salty Soil[J].Rock and Soil Mechanics,2018,39(5):1619-1624.
[19]WAN X S,YANG Z H.Pore Water Freezing Characteristic in Saline Soils Based on Pore Size Distribution[J].Cold Regions Science and Technology,2020,173:103030.
[20]周凤玺,周立增,王立业,等.温度梯度作用下非饱和盐渍土水盐迁移及变形特性研究[J].岩石力学与工程学报,2020,39(10):2115-2130.
ZHOU Feng-xi,ZHOU Li-zeng,WANG Li-ye,et al.Study on Water and Salt Migration and Deformation Properties of Unsaturated Saline Soil Under Temperature Gradient[J].Chinese Journal of Rock Mechanics and Engineering,2020,39(10):2115-2130.
[21]许 健,张明辉,李彦锋,等.Na2SO4盐渍原状黄土冻融过程劣化特性试验研究[J].岩土工程学报,2020,42(9):1642-1650.
XU Jian,ZHANG Ming-hui,LI Yan-feng,et al.Experimental Study on Deterioration Behavior of Saline Undisturbed Loess with Sodium Sulphate Under Freeze-thaw Action[J].Chinese Journal of Geotechnical Engineering,2020,42(9):1642-1650.
[22]杨晓华,张莎莎,刘 伟,等.粗颗粒盐渍土工程特性研究进展[J].交通运输工程学报,2020,20(5):22-40.
YANG Xiao-hua,ZHANG Sha-sha,LIU Wei,et al.Research Progress on Engineering Properties of Coarse-grained Saline Soil[J].Journal of Traffic and Transportation Engineering,2020,20(5):22-40.

Memo

Memo:
-
Last Update: 2022-03-20