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密实度及有荷干湿循环对土-水特征曲线的影响 被引量:1

Influence of Compaction and Drying-wetting Cycle with Loading on Soil-Water Characteristic Curve
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摘要 鉴于土-水特征曲线在非饱和土的研究中具有重要意义,采用Tempe压力膜仪和多功能土-水特征曲线试验仪,研究了密实度及固结压力下干湿循环对非饱和重塑粘土的土-水特征曲线的影响,并利用Van Genuchten模型对试验结果进行曲线拟合。结果表明,土体密实度越大,所受固结压力越大,则土体的进气值越大,失水速率越小,残余含水率越大;在固结压力下的干湿循环过程中,脱湿曲线失水速率越小,进气值越大,随干湿循环次数的增多,因土体孔隙发生改变,脱湿曲线的进气值呈增大趋势,且回滞环逐渐减小。 Soil-water characteristic curve plays an important role in unsaturated soil research.Tempe instrument and multifunctional soil-water characteristic curve test instrument are used to study the influences of compaction and dryingwetting cycle on SWCC of unsaturated remolded clay.The Van Genuchten model is employed to fit SWCC.It is found that the greater the compactness of consolidation and the higher of consolidation pressure are,the higher air entry value,the smaller loss rate and the greater the residual moisture content are.The smaller loss rate of water in drying curve is,the higher air entry value is in the test of drying-wetting cycles under consolidation pressure.Besides,the air entry value of drying curve gradually increases and the hysteresis loop decreases due to the change of soil pore,with the increasing number of drying-wetting cycle.
作者 杨迎 陈勇 李平 唐杰鑫
机构地区 三峡大学三峡库区地质灾害教育部重点实验室
出处 《水电能源科学》 北大核心 2016年第3期128-131,共4页 Water Resources and Power
基金 湖北省自然科学基金项目(2014CFB267) 国家自然科学基金青年基金项目(51409149)
关键词 土-水特征曲线 密实度 干湿循环 VAN GENUCHTEN模型 soil-water characteristic curve compaction drying-wetting cycle Van Genuchten model
分类号 TU41 [建筑科学—岩土工程]
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  • 1王铁行,陆海红.温度影响下的非饱和黄土水分迁移问题探讨[J].岩土力学,2004,25(7):1081-1084. 被引量:37
  • 2熊承仁,刘宝琛,张家生.重塑粘性土的基质吸力与土水分及密度状态的关系[J].岩石力学与工程学报,2005,24(2):321-327. 被引量:49
  • 3刘国楠,冯满.三轴试验中非饱和土试样吸力的量测[J].岩土工程学报,1994,16(5):11-15. 被引量:6
  • 4赵明华,刘小平,彭文祥.水膜理论在非饱和土中吸力的应用研究[J].岩土力学,2007,28(7):1323-1327. 被引量:31
  • 5MILLER C J. Impact of soil type and compaction conditions on soil water characteristic[J]. Journal of Geoteehnical and Geoenvironmental Engineering, ASCE, 2002, 128(9): 733-742.
  • 6VANAPALLI S K, FREDLUND D G, PUFAHL D E. Relationship between soil-water characteristic curves and the as-compacted water content versus soil for a clay till[C]//Proceedings of Ⅺ Pan-American Conference on Soil Mechanics and Foundation Engineering. Brazil: Iguanzu Falls, 1999:991 -998.
  • 7PEREIRA J H F, FREDLUND D G. Volume change behavior of collapsible compacted gneiss soil[J]. Journal of Geotechnical and Geoenvironmental Engineering. ASCE, 2000, 126(10): 907-916.
  • 8KAWAI K, KARUBE D, KATO S. The model of water retention curve considering effects of void ratio[C]// RAHARDJO H, TOLL D G, LEONG E C. Unsaturated Soils for Asia. Rotterdam: Balkema, 2000: 329-334.
  • 9CHARLES W W NG, PANG Y W. Influence of stress state on soil-water characteristics and slope stability[J]. Journal of Geotechnieal and Geoenvironmental Engineering, ASCE, 2000, 126(2): 157- 166.
  • 10ZHOU Jian, YU Jian-lin. Influences affecting the soil-water characteristics curve[J]. Journal of Zhejiang University Science, 2005, 6A(8): 797-804.

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水电能源科学
2016年 第3期

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