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含水合物黏土的力学性质试验研究
Experimental study of mechanical properties of hydrate clay

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王淑云 1 *   罗大双 1   张旭辉 1   鲁晓兵 1   石要红 2  
文摘 基于含四氢呋喃水合物黏土样品在不同水合物饱和度、围压及水合物分解前后的高压三轴剪切试验和超声波测量数据,分析了含水合物黏土的应力-应变关系和强度特性.试验结果表明:(1)含水合物黏土的应力-应变曲线展现出弹性、塑性变形以及应变硬化三个阶段(在应变低于1.5%时近似为弹性,在应变2%~6%范围内表现为塑性,在大于6%后呈现明显的应变硬化特性),与不含水合物黏土的应力-应变关系有明显不同;(2)含水合物黏土在水合物分解前后的应力-应变关系存在明显的不同,水合物分解后比水合物分解前的不排水强度值降低程度最大为50%;(3)含水合物黏土的不排水抗剪强度随水合物饱和度和围压的增加而增大,并比不含水合物黏土的强度提高1~6倍.上述结果表明水合物的存在增强了黏土颗粒之间的连结或胶结作用.
其他语种文摘 Based on a series of high compression static tri-axial shear experiment and ultrasonic wave measurement data of tetrahydrofuran hydrate clay samples under the condition of different hydrate saturation, confining pressure and before and after hydrate decomposition, the stress-strain relation and strength characteristics of hydrate clay were analyzed. Experimental results show that (1) the stress-strain curve of hydrate clay presents three stages, i.e. approximately elastic stage (when strain is less than 1.5%), plastic deformation stage (when strain is in a range of 2% and 6%) and obvious strain hardening stage (when strain is greater than 6%), which indicate obvious difference of stress-strain relation compared with that of clay without hydrate; (2)there is a distinct difference in stress strain relationship of hydrate clay before and after hydrate decomposition, compared with the clay before hydrate decomposition, the maximum reduction of undrained strength of hydrate clay after hydrate decomposition is 50%; (3)the undrained shear strength of hydrate clay increases with the increase of hydrate saturation and confining pressure, and the strength of hydrate clay is 1~6 times higher than that of clay without hydrate. Above results demonstrate that the presence of hydrate enhances the bonding or cementation among clay particles.
来源 实验力学 ,2018,33(2):245-252 【核心库】
DOI 10.7520/1001-4888-16-220
关键词 四氢呋喃水合物 ; 黏土 ; 含水合物黏土 ; 应力-应变 ; 强度
地址

1. 中国科学院力学研究所, 中国科学院流固耦合系统力学重点实验室, 北京, 100190  

2. 广州海洋地质调查局, 广州, 510075

语种 中文
文献类型 研究性论文
ISSN 1001-4888
学科 建筑科学
基金 国家自然科学基金 ;  国土资源部中国地质调查局项目 ;  中石油-中科院高端战略联盟计划
文献收藏号 CSCD:6229728

参考文献 共 22 共2页

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引证文献 6

1 杨柳 含水合物粉质黏土压裂成缝特征实验研究 力学学报,2020,52(1):224-234
被引 8

2 李淑霞 天然气水合物开发多物理场特征及耦合渗流研究进展与建议 力学学报,2020,52(3):828-842
被引 3

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