Effect of Friedel's salt on strength enhancement of stabilized chloride saline soil

In the field of soil stabilization, only calcium silicate hydrate(CSH) and ettringite(AFt) as hydration products have been reported to directly contribute to the strength enhancement of the soil. A chloride dredger fill, an artificial chloride saline soil, and a non-saline soil were stabilized by Portland cement(PC) and PC with Ca(OH)_2(CH) with different contents. A series of unconfined compressive strength(UCS) tests of stabilized soil specimen after curing for 7 d and 28 d were carried out, and the hydration products and microstructure of the specimens were observed by X-ray diffractometry(XRD), scanning electronic microscopy(SEM), and energy-dispersive X-ray analysis(EDXA). The results showed that the strengths of PC+CH-stabilized chloride saline soils were much higher than those of PC-stabilized soils. A new hydration product of calcium aluminate chloride hydrate, also known as Friedel's salt, appeared in the PC+CH-stabilized chloride saline soils. The solid-phase volume of Friedel's salt expanded during the formation of the hydrate; this volume filled the pores in the stabilized soil. This pore-filling effect was the most important contribution to the significantly enhanced strength of the PC+CH-stabilized chloride saline soils. On the basis of this understanding, a new optimized stabilizer was designed according to the concept that the chloride in saline soil could be utilized as a component of the stabilizer. The strength of the chloride saline soils stabilized by the optimized stabilizer was even further increased compared with that of the PC+CH-stabilized soils.

Influences of soil moisture and salt content on loess shear strength in the Xining Basin, northeastern Qinghai-Tibet Plateau

Moisture and salt content of soil are the two predominant factors influencing its shear strength. This study aims to investigate the effects of these two factors on shear strength behavior of loess in the Xining Basin of Northeast Qinghai-Tibet Plateau, where such geological hazards as soil erosion, landslides collapse and debris flows are widespread due to the highly erodible loess. Salinized loess soil collected from the test site was desalinized through salt-leaching in the laboratory. The desalinized and oven-dried loess samples were also artificially moisturized and salinized in order to examine how soil salinity affects its shear strength at different moisture levels. Soil samples prepared in different ways(moisturizing, salt-leaching, and salinized) were measured to determine soil cohesion and internal friction angle. The results show that salt-leaching up to 18 rounds almost completely removed the salt content and considerably changed the physical components of loess, but the soil type remained unchanged. As salt content increases from 0.00% to 12.00%, both the cohesion and internal friction angle exhibit an initial decrease and then increase with salt content. As moisture content is 12.00%, the salt content threshold value for both cohesion and internal friction angle is identified as 3.00%. As the moisture content rises to 16.0% and 20.00%, the salt content threshold value for cohesion is still 6.00%, but 3.00% for internal friction angle. At these thresholds soil shear strength is the lowest, below which it is inversely related to soil salinity. Beyond the thresholds, however, the relationship is positive. Dissimilar to salinity, soil moisture content exerts an adverse effect on shear strength of loess. The findings of this study can provide a valuable guidance on stabilizing the engineering properties of salinized loess to prevent slope failures during heavy rainfall events.

Influence of Salt-Lime Stabilization on Soil Strength for Construction on Soft Clay

Construction on soft soil is one of the most challenging situations faced by geotechnical engineers. The heterogeneous and complex nature of soil, especially those containing organic clay, often makes it impossible for the construction specification to be addressed properly. Generally, clay exhibits low strength, high compressibility, and strength reduction when subjected to mechanical disturbance. This means that construction on clay soil is vulnerable to bearing capacity failure induced by low inherent shear strength. All these properties can be improved by the effective stabilization of soil. This study analyzed the effectiveness of incorporating salt-lime mixtures at various dosages in improving the strength increment of the soil. The results indicate that among different combinations of salt and lime, the best performance in terms of strength increase was achieved by adding 10% NaCl with 3% lime in the soil. The outcome of this study focuses on enhancing the ultimate strength of soil and its implementation in the field of foundation engineering.

Influencing factors of compressive strength of solidified inshore saline soil using SH lime-ash

Through unconfined compressive strength test,influencing factors on compressive strength of solidified inshore saline soil with SH lime-ash,ratio of lime-ash(1-K),quantity of lime-ash,age,degree of compression and salt content were studied.The results show that because inshore saline soil has special engineering characteristic,more influencing factors must be considered compared with ordinary soil for the perfect effect of solidifying.

Titrimetric Study of the Solubility and Dissociation of Benzoic Acid in Water: Effect of Ionic Strength and Temperature

The apparent acid dissociation constant (Kc) of benzoic acid in water has been determined ti-trimetrically under ionic strength values between 0.00 and 0.50 mol·L﹣1 at a range of temperatures between 16°C and 41°C. The thermodynamic dissociation constant (as pKa) of benzoic acid was determined as 4.176 at 25°C. No regular correlation between pKa of benzoic acid and the temperature in the range was used. The values of pKa are inversely proportional to temperatures between 16°C and 30°C. In this range of temperature, the values of thermodynamic quantities () for the dissociation process of benzoic acid in water were calculated by using Van’t Hoff plot. For this case the dissociation was not favoured through entropy and enthalpy changes. The values of pKa are directly proportional to temperatures between 30°C and 41°C.

水盐含量及电阻率对盐渍土抗剪强度的影响

为了研究盐渍土的水盐含量及电阻率对其抗剪强度的影响,对长岭县的盐渍土进行室内试验,测量了不同深度土壤的含水率、含盐量、电阻率和抗剪强度,研究了电阻率和抗剪强度与含水率含盐量的关系。结果表明:盐渍土的电阻率随含盐量和含水率的增加而逐渐降低;经三轴剪切试验可得,内摩擦角和黏聚力均随含盐量的增加而减小,与含水率呈负相关;盐渍土的抗剪强度与电阻率之间具有良好的线性关系,抗剪强度随电阻率的增大而逐渐增大,构建盐渍土抗剪强度与电阻率之间的相关拟合公式,对实际工程应用有理论参考意义。

路用蓄盐除冰纤维配比设计及除冰性能确定

为解决道路凝冰问题,基于环保、经济、实用等原则,针对适用于沥青路面主动抗凝冰的蓄盐纤维填料的配合比进行设计,并对其相关性能展开研究。通过基于单纯形重心设计的融冰试验和电导率试验对蓄盐除冰材料配比进行探究,并基于融冰试验和冻粘剪切试验分析其除冰性能。试验结果表明:选用乙酸钠∶乙酸钾∶甲酸钠=7∶2∶1、复合有机盐∶纤维=3∶1为蓄盐纤维各种成分的最佳配合比;在融冰试验中,蓄盐纤维替换率为66%的除冰材料在较高负温下融冰速率能达到1022 g·(h·m 2)-1,表明其融冰性能良好;凝冰后,蓄盐纤维沥青混合料表面冻粘强度比普通沥青混合料下降33%,能够有效降低冻粘强度。基于最佳配合比,新型路用环保蓄盐除冰材料具有良好的融冰能力和除冰降粘功效。

盐蚀/冻融环境下环氧树脂结构胶强度降解机理

为探究盐蚀/冻融循环作用对环氧树脂胶黏剂材料的拉伸、剪切性能的影响,分别开展了40个胶黏剂和40个单搭接接头的盐蚀/冻融循环试验和力学性能试验,分析其力学性能随环境作用时间的变化规律.研究表明,随环境作用时间增加,所有胶黏剂试件失效模式未发生变化,而单搭接接头由内聚破坏和界面脱黏的混合失效模式变为界面脱黏失效模式.胶黏剂试件的拉伸强度总体呈现下降趋势,210次盐蚀/冻融循环后降低了9.2%.水分在单搭接接头界面的扩散速率远大于胶黏剂试件,导致了单搭接接头剪切强度相对于胶黏剂拉伸强度下降更为显著,210次盐蚀/冻融循环后剪切强度降低了60.9%.此外,盐蚀/冻融循环2160次后,胶黏剂拉伸强度保留率约为31.1%,而单搭接接头已失效.

蓄盐沥青混合料与冰层粘结程度评价方法探究

为了能更精确地评价蓄盐沥青混合料与冰层的粘结程度,通过对拉拔头、冰层冻结方式、拉拔方式等方面进行改进,采用粘结强度和残冰率作为蓄盐沥青混合料与冰层粘结程度的评价指标,开发出一种基于马歇尔试件全断面的试验方法。试验结果表明,试件与冰层之间的粘结强度及残冰率随温度降低而增加,蓄盐沥青混合料在-10℃以内能降低试件与冰层的粘结强度30%以上,-7℃的粘结强度相比于普通沥青混合料减小约50%,-9℃以内残冰率减小比例均大于50%。冰层与试件粘结强度的测量准确度随残冰率的增大而降低,建议在-10℃内采用本试验方法。开发的评价试件与冰层粘结程度的试验方法区分度较高,试验的变异系数在10%以内,稳定性较好。

超硫酸盐渍土固化强度及冻融特性试验研究

地基强度不足和盐–冻胀破坏是导致盐渍土地区渠道衬砌结构发生破坏的主要原因。为解决盐渍土强度不足的问题,降低盐渍土对环境温度的敏感性,首先,开展联合固化剂对超硫酸盐渍土强度的影响研究,并结合微观测试结果分析,构建联合固化剂掺量与强度之间的关系,对固化效果作出评价;其次,借助压汞试验对微观孔结构进行分析;最后,通过冻融循环试验揭示盐–冻胀力及盐–冻胀量的变化规律。结果表明:固化盐渍土强度增长效果显著,水化产物增强了盐渍土颗粒间的胶结作用。当联合固化剂掺量从0增加至30%时,固化盐渍土的孔隙率逐渐降低,孔径从超大孔向中小微孔演变;模型计算得到的分形维数逐渐增大,其中,Menger海绵模型与Neimark模型表现为多尺度分形,在中孔隙(0.1μm≤孔径<1.0μm)范围分形特征不明显,由热力学模型计算得到的分形维数DT在合理区间2.824~2.849变化,很好地表征了孔隙表面的分形特征。冻融循环10次后,相较未固化盐渍土,固化盐渍土盐–冻胀量削减了117%;盐渍土盐–冻胀力波动范围随冻融次数的增加而逐渐增加,固化盐渍土盐–冻胀力转变为周期性衰减,掺入的联合固化剂有效弱化了盐渍土盐–冻胀力。结合工程实际,建议渠道地基加固中水泥∶粉煤灰∶硅灰∶脱硫石膏质量比为1.00∶1.67∶0.83∶1.00,联合固化剂掺量为30%。

含盐量及冻融条件对冻融氯盐粉质黏土静动强度特性影响研究

沿海地区隧道建设中人工冻结法加固越来越多,而冻融氯盐粉质黏土静动强度及弹性模量特征是人工冻结法加固解冻融沉预测与稳定性设计的重要依据。为深入研究氯盐粉质黏土静动强度及弹性模量变化规律,开展了冻融前后、不同含盐量及冻融温度的固结不排水静三轴试验和动三轴试验。研究结果表明:不同试验条件下静三轴应力-应变曲线及动三轴骨干曲线均呈现应变硬化特征;冻融前试样曲线初始线性阶段更明显。静强度随含盐量增加先降后升,存在一对应最低强度的临界含盐量为1%;-10℃冻融后,含盐量≤3%时动强度无明显变化,含盐量为4%时动强度显著增大至其余含盐量试样的1.8倍;含盐量增加使弹性模量增加1.1~2.0倍。对弹性模量进行E/E_(max)归一化处理,并可用双曲线模型进行描述。冻融后,2%含盐量试样静、动强度损伤率分别为52%~66%、69%~78%,峰值静、动弹性模量损伤率为90%、81%。冻融温度对静、动强度及弹性模量影响不明显。研究结果可为人工冻结法在海相含盐地层应用、预测与控制工后融沉提供理论依据,保证隧道安全运营。

海相淤泥质固化土强度劣化规律试验研究

针对海相淤泥质软土中水泥搅拌桩成桩效果不佳的问题,选取天津地区某地铁工程施工现场海相淤泥质黏土,通过室内水泥土无侧限抗压强度试验,研究了可溶性盐和有机质含量对海相淤泥固化的无侧限抗压强度(UCS)的影响,并通过扫描电镜(SEM)和X射线衍射(XRD)对其微观结构和物相特征进行分析。结果表明:土壤水泥的强度随可溶性盐和有机质含量的增加而降低,其主要通过破坏和抑制水泥水化产物的形成,进而降低水化产物的胶凝性能,破坏了水泥土结构,导致强度降低。该研究结果对解释海相淤泥质软土固化效果不佳的现象具有重要的意义。

盐冻循环作用下水泥稳定碎石混合料的宏细观性能

为研究盐分和冻融循环耦合侵蚀作用下水泥稳定碎石混合料的力学性能、疲劳特性及微细观空隙结构衰减规律,在冻融条件下对不同初始含盐量的水泥稳定碎石混合料开展无侧限抗压强度试验、弯拉强度试验、动态压缩模量试验和三分点加载疲劳试验。基于工业CT无损检测技术研究了盐冻耦合作用下水泥稳定碎石混合料微细观空隙结构衰减规律;提出了盐冻循环次数与盐溶液浓度对水泥稳定碎石混合料力学性能、疲劳性能和微细观空隙直径期望值的衰减公式;建立了微细观空隙结构与宏观力学性能、疲劳性能之间的拟合关系。结果表明:盐冻耦合侵蚀作用加速了水泥稳定碎石混合料力学性能与疲劳特性衰减,随着盐冻循环次数增加,水泥稳定碎石混合料的无侧限抗压强度与动态回弹模量呈指数模型衰减,弯拉强度与疲劳寿命呈三次函数模型衰减;盐冻损伤主要集中在集料边缘的原生空隙部位,微细观等效空隙直径期望值和空隙级配中小于0.1 mm3的空隙数量随着盐冻耦合侵蚀作用次数增加而增大;硫酸钠盐溶液浓度越大,经历相同盐冻循环后水泥稳定碎石混合料力学性能和疲劳性能损伤度越高,微细观等效空隙直径期望值随着硫酸钠盐溶液浓度增大呈线性关系增大;随着等效空隙直径期望值增大,水泥稳定碎石混合料的动态回弹模量、无侧限抗压强度和弯拉强度均呈线性关系减小,同时疲劳寿命呈指数函数关系降低;盐冻耦合侵蚀作用改变了水泥稳定碎石内部微细观空隙结构,是盐冻耦合侵蚀作用导致水泥稳定碎石混合料力学性能和疲劳性能下降的原因之一。

硫酸盐作用下掺纳米SiO_(2)/CuO混凝土强度及质量变化研究

为了研究硫酸盐侵蚀下掺纳米材料混凝土的强度及质量变化问题,开展2种纳米材料(纳米CuO和纳米SiO_(2))及质量百分浓度分别为纳米材料1.0%、5.0%、10.0%的硫酸盐溶液侵蚀下的混凝土盐侵蚀试验。结果表明:随侵蚀时间增加,混凝土试件表面逐渐剥落,抗压强度先升高后下降。混凝土中掺入一定量纳米材料能有效提高其抗压强度,但随着纳米材料掺量的增大,纳米材料会团聚而降低活性,进而导致混凝土抗压强度降低。此外,硫酸盐浓度也会影响混凝土的抗压强度。硫酸盐浓度为10.0%时,掺入0.1%的纳米CuO或0.1%的纳米SiO_(2)均能提高混凝土抗硫酸盐侵蚀性能;相较于纳米CuO,纳米SiO_(2)对于提高混凝土抗硫酸盐侵蚀性能更佳。

盐穴储能库固井工艺

压缩空气储能技术(CAES)利用压缩空气储能,是一种规模大、灵活、低碳的储能技术。云应储能库注采井普遍具有地层温度低、井眼尺寸大、漏失风险未知、注采周期频繁、井筒长期封隔要求高等固井难点,固井难度大。故开展了湖北应城压缩空气储能固井工艺研究,结合紧密堆积设计理论、晶相结构诱导设计,研发了1套适用于盐穴储能库注采井固井的低温抗盐韧性水泥浆,并形成了相关配套固井工艺。水泥浆密度范围为1.88~1.93 g/cm^(3),稠化时间易调,沉降密度差为0,游离液为0,API失水量不大于50 mL,抗盐达半饱和,7 d弹性模量小于6.13 GPa,低温30℃下起强度时间小于10 h,24 h抗压强度大于14 MPa。该项技术成功应用于湖北云应盆地压缩空气储能项目注采井表层套管及生产套管固井,固井质量合格率为100%,优质率大于95%,同时对盐穴储能库固井提供技术支持和借鉴。

盐穴储气库老井封堵界面胶结强度试验研究

现阶段进行的水泥塞封堵界面胶结强度测试研究未考虑高温高压对其测试的影响,且大多数开展的是常温常压下水泥塞的剪切胶结强度测试。为此,设计了盐穴储气库老井封堵水泥塞综合胶结强度原位测试装置,并在80℃、15 MPa的模拟条件下,开展了不同界面、不同水泥塞长度和直径及水泥浆体系条件下的水泥塞胶结强度测试试验,明确了不同因素对胶结强度的影响规律。试验结果表明:水泥塞-岩石/套管界面的胶结强度受水泥浆体系影响较大,盐层水泥浆体系下的界面胶结强度大于盖层水泥浆体系下的界面胶结强度;水泥塞-岩石界面胶结强度略大于水泥塞-套管界面胶结强度;水泥塞-岩石/套管界面的拉伸胶结强度低于剪切胶结强度,且两者之比为0.41~0.45。研究成果可为盐穴储气库老井封堵界面密封失效的预测提供重要的理论支撑。

冻融循环作用下硫酸盐盐渍土物理力学特性试验研究

为研究硫酸盐盐渍土在冻融循环作用下的力学特性,结合京沈高速铁路朝阳段的工程实际,利用三轴不固结不排水试验对不同冻融循环次数(最多50次)、盐质量分数(0%、2%和5%)和围压(100 kPa、200 kPa、300 kPa和400 kPa)下的硫酸盐盐渍土进行研究,分析不同试验条件下硫酸盐盐渍土的抗剪强度特性及强度劣化机理。研究结果表明:随着冻融循环次数、盐质量分数和围压的逐渐增加,硫酸盐盐渍土的应力-应变曲线逐渐由应变软化向应变硬化转变;抗剪强度随冻融循环和盐质量分数的增加而逐渐降低;对于盐质量分数0%的试样,内摩擦角受冻融循环影响不明显,在30°~34°之间;在短期冻融循环(1~9次)作用下,黏聚力呈上升趋势,在冻融循环9~20次过程中,黏聚力急剧下降,当冻融循环大于20次后,黏聚力逐渐趋于稳定;对于盐质量分数2%和5%的试样,短期冻融循环(小于9次)对内摩擦角影响不显著,而在冻融循环20次后,内摩擦角急剧减小;在冻融循环1~20次过程中,试样的黏聚力逐渐减小,在冻融循环20次时,黏聚力达到最小值;土样在反复冻融循环作用后,土体颗粒大量分解,粒度逐渐变细,细颗粒占比逐渐增大。研究结果可为类似工程提供理论指导。

沙化盐碱地成库论证及防渗对策研究

昆都仑河水库整个库坝区覆盖层皆为沙化盐碱地层,透水性、腐蚀性和盐胀性皆较强,且厚度大而难以换填,导致其成库论证及防渗处置极其复杂,而两者成功与否是水库修建的决定性因素。本文基于地质调查、地质钻探和室内外试验成果,探索沙化盐碱地岩土体物理及化学特性,以求为成库论证及防渗对策研究奠定基础。结果表明:库坝区上部地层皆为强透水性,存在库区、坝肩和坝基渗漏,不具备成库蓄水天然地质条件。库坝区表层厚度约2.0m为沙化盐碱土,具有较强的腐蚀性和盐胀性,但皆随埋深增加而逐渐变弱。坝基全—强风化泥岩皆呈弱透水性,防渗性较好,为天然库底隔水层,其抗压强度及坝基承载力皆随埋深增加和风化程度减弱逐渐提高。推荐库坝区采用砼防渗面板铺盖方案,且砼必须具备抗硫酸盐、高密实性、高强度等特性,且严控施工和养护质量,可实现成库蓄水。

锂盐对水泥基快速修补材料性能的影响研究

研究了锂盐种类和添加量对硫铝酸盐水泥凝结时间、抗压强度、耐划伤性能、邵氏硬度的影响规律,并利用扫描电镜揭示了锂盐种类和添加量对硫铝酸盐水泥水化产物微观形貌的作用机制。结果表明:氯化锂、碳酸锂、磷酸锂、硫酸锂4种锂盐的添加均可加速硫铝酸盐水泥的水化过程,其促进效果分别为氯化锂>碳酸锂≈硫酸锂>磷酸锂,且当Li^(+)添加量为0.1×10^(-4)mol/g时,4种锂盐对硫铝酸盐水泥早期强度的提升幅度最高。

酸性盐雾腐蚀对铝硅聚苯酯可磨耗封严涂层组织结构与力学性能影响

为研究铝硅聚苯酯(AlSi-PHB)可磨耗封严涂层在海洋环境下的腐蚀行为及腐蚀对涂层性能的影响,在TC4基体上利用等离子喷涂技术制备AlSi-PHB涂层可磨耗封严涂层,利用扫描电子显微镜(SEM)、X射线衍射(XRD)等测试方法,开展192 h酸性盐雾试验、硬度试验、结合强度试验,对涂层腐蚀前后的腐蚀形貌及腐蚀机理、涂层结合强度和硬度的变化进行研究。结果表明,经酸性盐雾试验后,涂层表面结构被完全破坏,涂层内部出现了较大的横向裂纹及腐蚀区域,主要腐蚀产物为Al(OH)_(3)。涂层内部孔隙的存在为腐蚀行为发生提供了场所,腐蚀介质Cl-通过孔隙侵入到涂层的内部,在“闭塞电池”的作用下,涂层内部发生更加剧烈的腐蚀。腐蚀前后,涂层的平均硬度从(65.2±10.7)HR15Y下降到(59.6±8.5)HR15Y,平均结合强度从(11.3±1.1)MPa下降到(1.7±0.6)MPa,对涂层服役可靠性产生了影响。