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1.
Evangelos I. Stavridakis 《Geotechnical and Geological Engineering》2006,24(2):379-398
Major geotechnical problems in construction involving silty–clayey soils are due to their low strength, durability and high
compressibility of soft soils, and the swell–shrink nature of the overconsolidated swelling soils. Confronted with these problems,
a suitable ground improvement technique is needed, for deep excavations in soft clays, for stability, durability and deformation
control. Cement-stabilization is one of the alternatives. An increase in strength and durability, reduction in deformability
are the main aims of this method. Conventional cement-stabilization methods are used mainly for surface treatment. However,
the use of cement has recently been extended to a greater depth in which cement columns were installed to act as a type of
soil reinforcement (deep cement–soil mixing and cement jet grouting). In situ engineering properties of these silty–clayey soils are often variable and difficult to predict. For this reason cement-stabilization
methods have a basic target to control the aforementioned engineering properties of these clays so that the properties of
a silty–clayey soil become more like the properties of a soft rock such as clayey shale or lightly cemented sandstone. So
cement-stabilization of these soils is essential to control their engineering properties and to predict their engineering
behaviour for construction. In an effort to predict, classify and study the suitability of silty–clayey soils for cement-stabilization
both slaking and unconfined compressive strength tests were carried out on clayey–sand mixtures consisted of two types of
clays, kaolin and bentonite. Finally diagrams were prepared to study the variation of slaking and strength due to compaction,
curing time and cement percentage and also to predict areas of efficient cement-stabilization. 相似文献
2.
巫山县污水处理厂高填方地基湿化变形试验研究 总被引:3,自引:5,他引:3
结合巫山县污水处理厂高填方工程,选取压实粘性土样,在室内进行了接近实际应力路径下的“单线法”湿化变形试验,研究了土样在不同的压实度、固结压力和湿化历史下的湿化机理、湿化前后的应力.应变关系及强度变化规律。取得的湿化变形试验成果表明,湿化使土样的变形模量和强度均有所降低;湿化变形不仅包括湿化体应变,而且包括湿化偏应变;随着压实度的增加,湿化变形减小。试验成果为巫山县污水处理厂高填方地基的填筑设计、控制湿化变形的措施和附加压密措施提供了依据。 相似文献
3.
Hairu Li Gang Liu Ju Gu Hong Chen Hongqiang Shi Mohamed A. M. Abd Elbasit Feinan Hu 《水文研究》2021,35(2):e14060
Aggregate disintegration is a critical process in soil splash erosion. However, the effect of soil organic carbon (SOC) and its fractions on soil aggregates disintegration is still not clear. In this study, five soils with similar clay contents and different contents of SOC have been used. The effects of slaking and mechanical striking on splash erosion were distinguished by using deionized water and 95% ethanol as raindrops. The simulated rainfall experiments were carried out in four heights (0.5, 1.0, 1.5 and 2.0 m). The result indicated that the soil aggregate stability increased with the increases of SOC and light fraction organic carbon (LFOC). The relative slaking and the mechanical striking index increased with the decreases of SOC and LFOC. The reduction of macroaggregates in eroded soil gradually decreased with the increase of SOC and LFOC, especially in alcohol test. The amount of macroaggregates (>0.25 mm) in deionized water tests were significantly less than that in alcohol tests under the same rainfall heights. The contribution of slaking to splash erosion increased with the decrease of heavy fractions organic carbon. The contribution of mechanical striking was dominant when the rainfall kinetic energy increased to a range of threshold between 9 J m−2 mm−1 and 12 m−2 mm−1. This study could provide the scientific basis for deeply understanding the mechanism of soil aggregates disintegration and splash erosion. 相似文献
4.
泥质膨胀岩崩解物粒径分布与膨胀性关系试验研究 总被引:2,自引:0,他引:2
崩解性是膨胀岩最基本的特性之一,但在膨胀岩膨胀性的快速判别指标中少见关于崩解性及崩解物的定量指标。因此,有必要开展膨胀岩崩解物粒径分布特征和崩解性与膨胀性之间关系的研究,以对膨胀岩的快速判别进行补充。以浙江台州黑洞、蛇蟠岛和新疆大阪隧洞泥质岩样品为例,进行了干燥饱和吸水率和干燥饱和崩解试验,并分析了干燥崩解物粒径分布特征、耐崩解性指数及其与基于干燥饱和吸水率的膨胀性判别结果之间的关系。结果表明,膨胀岩膨胀性的强弱与其崩解物的最大含量粒组颗粒粒径、有效粒径和耐崩解性指数呈反相关关系。膨胀岩崩解物粒径分布的差异性对其膨胀性具有一定的指示意义。 相似文献
5.
6.
Clay soils, especially clay soils of high or very high swelling potential often present difficulties in construction operations. However, the engineering properties of these clay soils can be enhanced by the addition of cement, thereby producing an improved construction material. Higher strength loss of cement stabilized clay soils after soaking in water is attributed to water absorbing capacity of the clay fraction (e.g. montmorillonite). Kaolinite and illitic soils are largely inert and resist to water penetration. These clays generally develop satisfactory strengths resulting to low strength reduction [Croft, 1967]. The swelling clays such as bentonite soaked in water, due to environmental conditions, result to volume increase causing macro and micro-fracturing in engineering structures. These fractures accelerate water penetration and consequently cause greater strength loss [Sällfors and Öberg-Högsta, 2002]. The water intrusion during soaking creates swelling and disrupts the cement bonds. The development of internal and external force systems in soil mass, due to soaking conditions, establish the initiation of slaking. Internal force system of a stabilized clayey soil consists of the resultant stresses established by the bonding potential of a cementing agent and the swelling potential of a clay fraction. In an effort to study this influence of soaking conditions and final absorbed water content on the stabilization parameters (cement, compaction, curing time), both unconfined compressive strength and slaking (durability) tests were carried out on two different cement stabilized clayey mixtures consisted of active bentonite, kaolin and sand. 相似文献
7.
采用灰色关联度分析法对红层软岩的矿物成分、化学成分、崩解试验等数据进行了分析。分析表明, 水理特性不稳定的粘土矿物始终是影响软岩崩解的主要因素之一, 而不同的化学成分对红层软岩崩解性的影响程度不同。通过以纯水、MgCl2, FeCl3, NaCl, CaCl2盐溶液作为红层软岩岩块浸泡液的崩解试验, 说明纯水浸泡下软岩的崩解性最强, 而所选3种盐溶液对所选红层软岩样品的崩解性均有抑制作用, 其中又以CaCl2抑制作用最强。在此基础上提出公路施工中填筑前以浇水作为加快红层软岩崩解, 填筑压实中以掺入石灰作为抑制软岩崩解路用控制方法。 相似文献
8.
针对“5·12”地震后,位于北川地区断层破碎带的千枚岩作为路基填料特有的材料,对破碎的千枚岩进行化学成分、物理性质、崩解性等试验。初步认为可以作为路基的底层填料,点荷载强度与多因素有关;破碎千枚岩中的粘土矿物含量与崩解程度有很大关系,压实工程特性与颗粒粗细的相对含量密切相关。根据施工现场试验监测结果表明,通过研究确定的压实工艺可将千枚岩压实到要求的密度,其物理、力学性质得到改善,满足路基要求。 相似文献
9.
The loss of P in overland flow from most cultivated soils is controlled by erosion, and in‐turn soil moisture. We evaluated the effect of soil moisture on erosion and P transport in overland flow by applying rainfall (7 cm h?1) to packed soil boxes (1 m long and 0·15 m wide) and field plots (1 and 10 m long by 1 m wide) of silt loams in a central Pennsylvania (USA) catchment. Flow from packed soil boxes took longer to initiate as antecedent soil moisture decreased from field capacity (2 min) to air dried (8 to 9 min). Even in the more complex field plots (i.e. soil heterogeneity and topography), the wetter site (1 by 10 m plot; 70% field capacity) produced flow more quickly (3 min) and in greater volume (439 L) than the drier site (1 by 10 m plot; 40% field capacity, 15 min, and 214 L, respectively). However, less suspended sediment was transported from wetter soil boxes (1·6 to 2·5 g L?1) and field plots (0·9 g L?1) than drier boxes (2·9 to 4·2 g L?1) and plots (1·2 g L?1). Differences are attributed to their potential for soil aggregate breakdown, slaking and dispersion, which contribute to surface soil sealing and crusting, as dry soils are subject to rapid wetting (by rainfall). During flow, selective erosion and antecedent moisture conditions affected P transport. At field capacity, DRP and PP transport varied little during overland flow. Whereas P transport from previously dry soil decreased rapidly after the initiation of flow (6 to 1·5 mg TP L?1), owing to the greater slaking and dispersion of P‐rich particles into flow at the beginning than end of the flow event. These results indicate that soil moisture fluctuations greatly effect erosion and P transport potential and that management to decrease the potential for loss should consider practices such as conservation tillage and cover crops, particularly on areas where high soil P and erosion coincide. Copyright © 2002 John Wiley & Sons, Ltd. 相似文献
10.
酸雨区泥质岩崩解相对于非酸雨区显著增强,但其机制尚有待进一步研究。以酸雨条件下水化学损伤的形成及其发展特性入手,选取典型酸雨区攀枝花市机场滑坡粉砂质泥岩,进行不同pH值条件下(pH=7、5、3)的耐崩解性试验。通过测定试验后崩解液离子成分变化、观察酸雨作用前后粉砂质泥岩薄片镜下特征、分析试样崩解破坏模式,探究酸雨水化学损伤加剧粉砂质泥岩崩解的细观机制;引入比表面积增量指标表征崩解残留物破碎程度,定量评价酸雨水化学损伤对粉砂质泥岩崩解的加剧效果。研究结果认为,粉砂质泥岩酸雨水化学损伤主要源于特定矿物的溶蚀,为其崩解劣化提供额外路径;随着崩解液pH值降低,粉砂质泥岩水化学损伤增强,崩解路径增多,崩解破坏模式发生转化,崩解残留物愈发破碎;采用比表面积增量指标可良好反映崩解残留物的破碎程度,崩解残留物愈破碎,比表面积增量指标值越大,粉砂质泥岩崩解程度越高。结论可为酸雨地区岩土体工程性质评价及加固设计提供理论参考。 相似文献