土工布非饱和导水特性试验研究

在干旱半干旱地区,土工布常处于非饱和环境中,其排水能力取决于非饱和导水特性。对两种不同类型的土工布分别进行毛细高度试验、水分特征曲线试验和虹吸试验。分析了土工布的非饱和导水特性,讨论了孔隙特征对毛细高度,水分特征曲线以及非饱和导水系数的影响。结果表明:等效孔径越小的土工布毛细高度越大;土工布的吸力随含水量的增大而减小,等效孔径越小的土工布在较大的吸力范围内具有较好的持水性能;土工布的非饱和导水系数随吸力增大而减小,等效孔径越小的土工布非饱和导水系数对应的吸力范围越大,可在较大的吸力范围内保持良好的导水性。

土壤膨胀性对土壤饱和水分运动参数的影响

膨胀性土壤吸水后易膨胀变形,从而影响到土壤水分的运动参数。为了研究土壤膨胀性对土壤饱和水分运动参数的影响,采用室内土柱试验装置分析了不同土壤厚度(2,4,6,8,10,15,20,25,30,35,40,45,50,55cm)对3种土壤(沙土、黄绵土、娄土)土壤容重、土壤饱和含水量、土壤饱和导水系数的影响,并分别用幂函数、指数函数和对数函数进行了拟合分析。结果表明:①土壤饱和膨胀率、饱和比容积、饱和含水量和饱和导水系数均随土壤厚度增加而减小。②通过3种函数拟合效果对比发现,幂函数具有最佳拟合效果。

基于大地电磁法的水文地质结构及参数推断

大地电磁法已被广泛用于矿产资源勘探和工程勘查,但该方法在水文地质参数定量方面的成果文献尚不多见。以科尔沁沙丘—草甸相间地区巨厚第四系沉积层为研究对象,通过EH-4大地电磁法的测试结合地质钻探试验数据,划定出研究区埋深105 m范围内砂黏土层在空间上的分布;经检验大地电磁法探测总体误差在5.1%~7.2%,其精度足以满足水文地质勘察的需求。然后利用研究区已有的土壤传递函数(Pedo-transfer functions,PTFs)模型对测区埋深105 m范围内的饱和导水系数进行了估算,进而首次利用大地电磁法所得数据建立了视电阻率与饱和导水系数的拟合模型。利用该模型推断出研究区埋深200 m范围内含水层的富水性,刻画出饱和导水系数的空间分布,为研究区提供了更加丰富的水文地质信息,同时也极大地提升了水文地球物理方法在水力参数预测方面的尺度。

海绵城市建设中土水特征曲线对产流的影响

土壤土水特征曲线是海绵城市建设中源头控制阶段的重要参数,是降雨入渗及产流研究的理论基础。针对海绵城市试点庄河市建设的实际情况,对当地3类土壤进行土水特征曲线测定,拟合计算得到土壤基质吸力、非饱和导水系数方程,结合Green-Ampt改进模型计算各类土壤所处区域在不同降雨强度下的雨水入渗及产流情况。结果表明:土壤入渗能力总体呈现为人工回填土>裸露坡地土>耕种土,人工回填土的入渗率是其他土壤的1.1~4.4倍。在降雨强度为大暴雨等级时,人工回填土的延迟产流时间是其他土壤的1.9~5.8倍;在特大暴雨时,3类土壤短时间内均会产生超渗产流,此时在延缓洪峰时间、控制洪峰流量上没有明显作用。

Biochar Effect on Water Evaporation and Hydraulic Conductivity in Sandy Soil

Biochar, as a kind of soil amendment, has important effects on soil water retention. In this research, 4 different kinds of biochars were used to investigate their influences on hydraulic properties and water evaporation in a sandy soil from Hebei Province, China. Biochar had strong absorption ability in the sandy soil. The ratio of water content in the biochar to that in the sandy soil was less than the corresponding ratio of porosity. Because of the different hydraulic properties between the sandy soil and the biochar, the saturated hydraulic conductivity of the sandy soil gradually decreased with the increasing biochar addition. The biochar with larger pore volume and average pore diameter had better water retention. More water was retained in the sandy soil when the biochar was added in a single layer, but not when the biochar was uniformly mixed with soil. Particle size of the added biochar had a significant influence on the hydraulic properties of the mixture of sand and biochar. Grinding the biochar into powder destroyed the pore structure, which simultaneously reduced the water absorption ability and hydraulic conductivity of the biochar. For this reason, adding biochar powder to the sandy soil would not decrease the water evaporation loss of the soil itself.