含管状孔隙黏性土渗透性试验研究
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摘要
黏性土在水利工程建设中常被认为是不透水层或隔水层,其渗透性多为弱透水或微透水,若黏性土发育有较多管状孔隙,其土体结构将会发生变化,渗透性也会改变。含管状孔隙黏性土常发育在山前洪积扇的前缘。受目前钻孔内取土样设备所限,土样采取时对管状孔隙结构破坏严重,室内制环刀样时容易对管状孔隙造成破坏或堵塞,不能得到含管状孔隙黏性土真正的渗透系数。为正确认识含管状孔隙黏性土的渗透性,采取了多种室内和室外渗透试验手段,并经过反复对比分析,观察到其渗透性等级多为中等透水,明显大于一般意义上的黏性土,并且其渗透具有方向性,经抽水试验分析验证,在垂直方向的渗透性要远大于水平方向的渗透性。
Cohesive soil is often considered to be impervious or a water-proof layer in the construction of water conservancy projects. Its permeability is mostly weak or slightly. Cohesive soil containing tubular pores develops at the leading edge of the piedmont alluvial fan. Due to the current equipment for taking soil samples, the structural damage of the tubular pores is serious when the soil samples are taken and the tubular pores are easily broken or blocked during the indoor ring-making process and the true permeability coefficient of the cohesive soil containing tubular pores cannot be obtained. If there are more tubular pores in the cohesive soil, the soil structure will be changed and the permeability will also be changed. In order to confirm the permeability of cohesive soil containing tubular pores, some indoor and outdoor permeability test methods were adopted. Through repeated comparison and analysis, it was observed that the permeability grade was mostly medium, which was obviously larger than that in the general sense. Its permeability had directionality. The results of pumping test show that the permeability in vertical direction is much greater than that in horizontal direction.
Cohesive soil is often considered to be impervious or a water-proof layer in the construction of water conservancy projects. Its permeability is mostly weak or slightly. Cohesive soil containing tubular pores develops at the leading edge of the piedmont alluvial fan. Due to the current equipment for taking soil samples, the structural damage of the tubular pores is serious when the soil samples are taken and the tubular pores are easily broken or blocked during the indoor ring-making process and the true permeability coefficient of the cohesive soil containing tubular pores cannot be obtained. If there are more tubular pores in the cohesive soil, the soil structure will be changed and the permeability will also be changed. In order to confirm the permeability of cohesive soil containing tubular pores, some indoor and outdoor permeability test methods were adopted. Through repeated comparison and analysis, it was observed that the permeability grade was mostly medium, which was obviously larger than that in the general sense. Its permeability had directionality. The results of pumping test show that the permeability in vertical direction is much greater than that in horizontal direction.
引文
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[12] 雷继威.钻孔注水试验方法及其指标值与室内渗透试验值的对比分析[J].岩土工程技术,1995(2):46-48.
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[15] 常士骠,张苏民.工程地质手册[M].4版.北京:中国建筑工业出版社,2007:996-1003.
[2] 刘海伟.考虑孔隙微细观特征的黏性土渗透机理研究[D].西安:西安理工大学,2016:1-12.
[3] 叶正强,李爱群,杨国华,等.粘性土的渗透规律性研究[J].东南大学学报,1999,29(5):121-125.
[4] 张瑛玲,朱敬毅.粘性土渗透系数的室内测定方法初探[J].地质科技情报,1991(1):74-78.
[5] 刘小龙.土的不同渗透试验方法应用与研究[J].勘察科学技术,2011(3):36-39.
[6] 魏惠文,刘鲁娜,张尚芳.土的渗透试验关键技术[J].山东水利,2007(3):25-25.
[7] 王秀艳,刘长礼.对粘性土孔隙水渗流规律本质的新认识[J].地球学报,2003,24(1):91-95.
[8] 陈崇希,林敏.地下水动力学[M].武汉:中国地质大学出版社,1999:122-123.
[9] 宿青山,段淑娟.对饱和粘性土渗透规律的新认识及其应用[J].长春地质学院学报,1994(1):50-56.
[10] 中华人民共和国水利部.水利水电工程注水试验规程:SL 345—2007[S].北京:中国水利水电出版社,2008:4-10.
[11] 张书林.土的原位注水法渗透试验两种渗透系数计算公式差异研究[J].治淮,2016(7):12-13.
[12] 雷继威.钻孔注水试验方法及其指标值与室内渗透试验值的对比分析[J].岩土工程技术,1995(2):46-48.
[13] 杨利超,王旭升,焦赳赳,等.粘性土层井孔抽水试验的参数识别[J].工程勘察,2011(6):32-35.
[14] 中华人民共和国水利部.水利水电工程钻孔抽水试验规程:SL 320—2005[S].北京:中国水利水电出版社,2005:9-15.
[15] 常士骠,张苏民.工程地质手册[M].4版.北京:中国建筑工业出版社,2007:996-1003.
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