Dynamic characteristics of lime-treated expansive soil under cyclic loading

To better understand the dynamic properties of expansive clay treated with lime, a series of laboratory tests were conducted using a dynamic triaxial test system. The influential factors, including moisture content, confining pressure, vibration frequency, consolidation ratio, and cycle number on the dynamic characteristics were discussed. Experimental results indicate that specimens at low moisture contents tend to damage along the 30~ shear plane and they present brittle failure, while saturated specimens show swelling phenomenon and plastic failure. A redtiction in cohesion has been observed for unsaturated samples at large number of cycles, while it is opposite for the internal friction angle. For the saturated specimens, both the cohesion and internal friction angle decrease with increasing number of cycles.

Sugarcane press mud modification of expansive soil stabilized at optimum lime content:Strength,mineralogy and microstructural investigation

This study attempted to investigate the potential of sugarcane press mud(PM) as a secondary additive in conjunction with lime for the stabilization of an expansive soil.The physico-mechanical properties of an expansive soil,such as plasticity,shrink-swell behavior,unconfined compressive strength(UCS),mineralogical and microstructural characteristics were investigated.The expansive soil was stabilized at its optimum lime content(7%) for producing maximum strength,and was modified with four different quantities of PM in small dosages(0.25%-2%).Cylindrical soil samples,38 mm in diameter and 76 mm in height,were cast and cured for varying periods to evaluate the strength of the amended soil.The spent samples after strength tests were further used for determination of other properties.The test results revealed that PM modification led to a substantial improvement in 7-d strength and noticeable increase in 28-d strength of the lime-stabilized soil(LSS).The addition of PM does not cause any detrimental changes to the shrink-swell properties as well as plasticity nature of the stabilized soil,despite being a material of organic origin.Mineralogical investigation revealed that the formation of calcium silicate hydrate(CSH) minerals,similar to that of pure lime stabilization with only the type of mineral varying due to the modification of PM addition,does not significantly alter the microstructure of the LSS except for superficial changes being noticed.

Stabilization of Expansive Soil by Lime and Fly Ash

An experimental program was undertaken to study the individual and admixed effects of lime and fly ash on the geotechnical characteristics of expansive soil.Lime and fly ash were added to the expansive soil at 4%-6% and 40%-50% by dry weight of soil,respectively.Testing specimens were determined and examined in chemical composition,grain size distribution,consistency limits,compaction,CBR,free swell and swell capacity.The effect of lime and fly ash addition on reducing the swelling potential of an expansive soil is presented.It is revealed that a change of expansive soil texture takes place when lime and fly ash are mixed with expansive soil.Plastic limit increases by mixing lime and liquid limit decreases by mixing fly ash,which decreases plasticity index.As the amount of lime and fly ash is increased,there are an apparent reduction in maximum dry density,free swell and swelling capacity under 50 kPa pressure,and a corresponding increase in the percentage of coarse particles,optimum moisture content and CBR value.Based on the results,it can be concluded that the expansive soil can be successfully stabilized by lime and fly ash.

Stabilization of expansive soils using chemical additives: A review

Volume instability of expansive soils due to moisture fluctuations is often disastrous,causing severe damages and distortions in the supported structures.It is,therefore,necessary to adequately improve the performance of such soils that they can favorably fulfil the post-construction stability requirements.This can be achieved through chemical stabilization using additives such as lime,cement and fly ash.In this paper,suitability of such additives under various conditions and their mechanisms are reviewed in detail.It is observed that the stabilization process primarily involves hydration,cation exchange,flocculation and pozzolanic reactions.The degree of stabilization is controlled by several factors such as additive type,additive content,soil type,soil mineralogy,curing period,curing temperature,delay in compaction,pH of soil matrix,and molding water content,including presence of nano-silica,organic matter and sulfate compounds.Provision of nano-silica not only improves soil packing but also accelerates the pozzolanic reaction.However,presence of deleterious compounds such as sulfate or organic matter can turn the treated soils unfavorable at times even worser than the unstabilized ones.

石灰-高炉矿渣改良膨胀土强度特性试验研究

因膨胀土具有吸水膨胀、失水收缩等不稳定性特征,使用高炉矿渣作为新型固化剂,并与无机材料石灰组合对膨胀土进行改良。对改良膨胀土开展自由膨胀率、液塑限、无侧限抗压强度和抗剪强度等指标的研究,探讨并分析了石灰-高炉矿渣(L-BLS)改良膨胀土在不同养护龄期以及不同改良剂掺量下的无侧限抗压强度变化规律。结果表明:使用L-BLS改良膨胀土能够显著提高膨胀土的早期强度;改良膨胀土的强度随养护龄期及改良剂掺量的增加而增强;当掺入6%石灰及9%高炉矿渣时,对应龄期的无侧限抗压强度最大,材料的有效利用率最佳。

石灰与水泥改性加固膨胀土对比试验研究

为探究石灰和水泥改性两种方法加固膨胀土的效果,以蒙-华铁路三荆段为例,采用现场采样和室内试验,对膨胀土样品的颗粒分布和力学特性进行了分析,研究了两种改性加固方法不同掺和比例的加固效果,分析内摩擦角、黏聚力、剪切强度等指标的变化规律,对两种加固方案的效果进行了比较,并通过电镜扫描分析了加固后的微观结构,揭示加固机理。结果表明:MHTJ-19和MHTJ-21两个区段的膨胀土在黏性矿物成分、颗粒级配和力学参数方面一致性良好,不存在系统差异。石灰和水泥改性显著提升了膨胀土的黏聚力、内摩擦角和抗剪强度,其中水泥改性效果更佳。电镜扫描图像分析显示,这两种改性方法通过颗粒凝聚作用提高了膨胀土的力学性能和降低了膨胀性。研究成果可为重载铁路工程路基设计和维护提供参考依据。

水泥/石灰和土壤固化剂复合改良膨胀土试验研究

采用水泥/石灰和BJ-W土壤固化剂对安徽地区膨胀土进行了改良试验研究。依据液限、塑限和自由膨胀率试验初步选定改良膨胀土的配合比范围,并通过胀缩总率、无侧限抗压强度和稳定性试验,进一步分析了改良膨胀土的性能变化规律。试验结果表明,掺入水泥/石灰和BJ-W土壤固化剂复合改良中、弱膨胀土时,液限逐渐减小,塑限逐渐增大,自由膨胀率降低到40%以下,且胀缩总率低于0.7%;无侧限抗压强度和稳定性试验中,改良膨胀土的强度和水稳系数(>80%)显著增加,且经过5次干湿循环后,改良膨胀土的强度衰减率小于20%,膨胀土的反复胀缩特性显著改善。综合考虑改良膨胀土的胀缩和强度特性,采用水泥和BJ-W土壤固化剂复合改良膨胀土效果最佳,中膨胀土最优配合比为7%水泥和0.02%BJ-W土壤固化剂,弱膨胀土最优配合比为6%水泥和0.02%BJ-W土壤固化剂。

老路扩建高液限土路基改良方案优选

为进一步提高路基的安全性稳定性,以京杭大运河西路为例,通过有限元数值计算软件ABAQUS对石灰改良土路基的沉降效果进行分析。进行了路基分别在原状土、掺入4%石灰(以质量分数计,后同)、掺入6%石灰、掺入8%石灰、掺入10%石灰5种工况下的沉降分析,并与工程实测数据进行对比。研究结果表明:与原状土相比,掺入不同含量的石灰后,路基整体沉降都有所减小,说明高液限土掺入石灰后能改善土体性能,减小结构整体沉降;工程实测沉降量均在数值模拟数据值(33.64 cm)上下浮动,幅度不超过5.78%。由此看出,工程实测数据与数值模拟数据基本一致,相差不大。综上,改良土掺8%石灰为最合理掺量。该研究结果可为类似工程提供参考。

隧道车站基坑用粘度时变填料改良设计及应用监测

在地铁车站隧道的开挖过程中,会出现没有合格的填料来填筑站场挖方段。在实际过程中通过改良技术来制备合格的填料。研究当施工隧道挖方段没有可以直接利用的合格填料,则可以利用弃方段的弱-中膨胀土进行填筑。采用路拌法掺6%石灰改良后作为填料进行填筑,填筑后压实系数、无侧限抗压强度均有明显改善和大幅提升,并根据现场监测得出填筑后的基坑满足设计要求。方案不仅解决了远运借合格填料填筑和弃方运输产生的费用较大的问题以及环保问题,还节约了项目资金。

石灰掺量对膨胀土力学及膨胀性能的动力学研究

文章选取6个自由膨胀率40%以上的膨胀梯度黏性土作为研究对象,分别进行了石灰掺量4%,5%,6%,7%和8%的击实试验,研究了石灰掺量对最大干密度和最优含水率的影响;并进行了不同石灰掺量下的饱和无侧限强度、天然无侧限强度和无荷膨胀率试验,对不同石灰掺量下的上述试验结果进行了拟合。研究结果表明:随着石灰掺量增加,最大干密度、饱和及天然无侧限强度均逐渐增大,拟合结果显示均大致呈线性关系;随着石灰掺量增加,最优含水率和无荷膨胀率均逐渐减少,拟合结果显示均大致呈线性关系,为石灰改良膨胀土工程实践提供参考。

高炉矿渣—石灰复合改良膨胀土工程特性试验研究

针对传统石灰改良膨胀土能耗高、污染大的缺点,应用工业固体废物高炉矿渣替代部分石灰对河北地区膨胀土进行改良。通过击实试验及无侧限抗压强度试验分析高炉矿渣-石灰改良土的击实特性、水敏特性、力学特性和水稳特性,并将其与相同掺量的石灰改良膨胀土进行对比。结果表明:相同击实功下,改良土的最大干密度随高炉矿渣占比的增加呈上升趋势,最优含水率呈下降趋势;改良土未浸水和浸水无侧限抗压强度、弹性模量随高炉矿渣占比的增加呈先增后减趋势,高炉矿渣占比为0.75时达到最大值。高炉矿渣占比为0.25,0.5,0.75时,改良土未浸水和浸水无侧限抗压强度、弹性模量均高于石灰改良土。改良土水稳系数随高炉矿渣占比的增加而呈下降趋势。

高速公路膨胀土路基填筑技术研究

为研究高速公路膨胀土路基填筑技术,提高路基整体质量和稳定,论文结合实际工程,围绕膨胀土路基的工程特性展开研究,重点分析了膨胀土路基的施工技术要点,并对其施工质量进行评价研究。结果表明,采用石灰改良技术进行膨胀土路基填筑施工可有效提高路基的整体稳定性和强度。

高速公路石灰改良膨胀土路基施工技术研究

为研究高速公路石灰改良膨胀土路基施工技术,提高路基施工效率和质量,论文结合实际工程,对石灰改良膨胀土工程特性进行阐述,即对其改良内部反应特征进行探究,重点分析了石灰改良膨胀土路基施工技术要点。研究结果表明,采用高速公路石灰改良膨胀土路基施工技术可减少路基填料的采购、运输和储存,节约施工成本,并可有效提高路基整体施工质量。

初始含水率对石灰改性黏土强度的影响及微观机理研究

为研究不同初始含水率下石灰改性黏土的无侧限抗压强度随时间的发展规律,基于击实试验确定的最佳含水率,制备不同含水率的石灰改性黏土试件进行无侧限抗压强度试验,分析初始含水率对石灰改性黏土的影响及机理。结果表明:无侧限抗压强度峰值点对应的含水率为23%,与击实试验确定的黏土最佳含水率20%不一致,较最佳含水率高3%左右;不同初始含水率下,石灰改性黏土的无侧限抗压强度受到黏结强化与水膜弱化的双重影响,且黏结强化与养护时间有关,随着养护时间的增加大致呈现为增强趋势;从微观结构来看,掺加石灰后,黏土的微观颗粒与微观孔隙均变小,颗粒黏结增强;与含水率20%石灰改性黏土相比,含水率23%的石灰改性红黏团聚体数量变多,石灰与黏土矿物的反应更为充分。

膨胀土工程特性及其石灰改性试验研究

系统地开展了弱、中膨胀土及石灰稳定土的物理力学试验。试验表明:中膨胀土具有较强的吸水膨胀软化特性,其 CBR 值低于3%,不能满足路基对填料的强度要求,用作路基填料必须改性;当压实含水量控制得当,弱膨胀土 CBR 可满足规范要求,其压实含水量宜按最优含水量加3%～4%控制;用石灰对中膨胀土改性效果显著,能有效抑制其胀缩潜势和提高土体强度,满足路堤填筑的要求。中膨胀土石灰改性的质量掺合比宜按5%控制。

石灰稳定膨胀土的效用及其施工质量控制

膨胀土的胀缩性可引起地基的变形,甚至危及构筑物的安全。对于膨胀土路段,路基的稳定是工程建设成功的关键。在论述石灰稳定土加固机理的基础上,结合工程实例,论述了膨胀土路段石灰稳定的施工要点及石灰稳定膨胀土路段的施工质量控制。

改良膨胀土筑堤技术研究

利用改良膨胀土作为高速公路路堤填筑材料是宁淮高速公路需要解决的主要问题。尽管室内试验论证可以用石灰改良膨胀土性质,但现场石灰改良土施工还要解决三大问题:石灰拌和均匀性和石灰含量的检测问题、现场压实方法和压实度控制问题、现场压实改良土的胀缩性和强度是否满足高等级公路路床和路基的要求问题。结合宁淮高速公路先导段施工,设计了试验段进行现场试验。试验结果表明,通过合理的施工工艺、有力的质量控制,改良膨胀土能够满足设计要求。改良土已经不具有膨胀土性质,胀缩性低,CBR 强度高,是良好的路堤填筑材料。

荆门非饱和膨胀土的变形与强度特性试验研究

通过压力板试验,对比分析了荆门原状膨胀土与石灰改良土持水特征的差异性;应用非饱和土三轴仪,开展了原状膨胀土、石灰改良膨胀土与重塑膨胀土的变形及强度特性试验。结果表明:①石灰改良膨胀土与原状膨胀土相比,其进气值有显著降低,残余含水率显著升高,土-水特征曲线两个特征点的斜率较为平缓,说明其水稳定性较好,土体性状更为稳定;②原状膨胀土和石灰改良膨胀土在非饱和与饱和状态的应力-应变关系曲线均呈应变软化型,随净围压的增大,应变软化的程度趋缓;随含水率的减小,峰值应力增大,应力峰值点有所提前,应变软化现象更加显著。饱和重塑膨胀土的应力-应变关系呈应变强化型,非饱和重塑膨胀土则呈现为应变软化型,但其应变软化的程度较前两类土大为趋缓;③经石灰改性后,膨胀土强度参数值有大幅度提高,即使在湿化饱和后,石灰改良膨胀土仍保持了相对稳定的力学性质和较高的抗剪强度参数值。相比之下,无论是重塑膨胀土,还是原状膨胀土,对湿化作用均十分敏感,其强度参数值或波动较大,或整体水平较低。

电阻率法评价膨胀土改良的物化过程

掺石灰、粉煤灰是工程中通常采用的改良膨胀土的方法。土电阻率是土的基本物理指标之一,其变化可反映土的其他物理性质指标的变化。通过掺灰改良膨胀土不同养护龄期下的电阻率测试以及膨胀量、膨胀力及无侧限抗压强度等试验研究,探讨了掺灰改良膨胀土养护过程中的物理化学反应过程。根据养护过程中的电阻率随龄期的变化规律,可将改良膨胀土的物理化学反应过程划分为瞬时反应阶段、主体反应阶段、残余反应阶段和稳定阶段4个不同阶段。针对改良膨胀土质量控制和评价体系中存在的不足,提出了基于电阻率指标的改性膨胀土的质量评价方法,通过试验证实了该方法的有效性和实用性。

消石灰对膨胀土团粒化作用的研究

用消石灰作为外掺剂,进行了两种不同的膨胀土的对比试验。研究了不同灰剂量和龄期对膨胀土"团粒化"作用效果的影响。对于消石灰改性膨胀土而言,不同性质膨胀土界限含水率的改性效果不尽相同。强膨胀土的改性效果相对较为明显,而弱膨胀土的改性效果相对较差,其改性效果存在一个下限。在膨胀土路基的施工中,二次掺灰工艺的闷料周期可以相对缩短。这样不仅有利于加快施工进度,同时对提高石灰改良土碾压质量和加固效果十分有利。