改性石灰粘土固化剂的研究

通过运用正交试验和XRD等方法,研究了改性石灰粘土固化剂的最佳配比及各种外加剂的增强机理,试验表明：对于最佳含水量的土壤,改性石灰粘土固化剂的最佳配比为：生石灰84％,石膏3％,硫酸钠5％,硫酸铝8％。用它固化的土壤州抗压强度比同一条件下用生石灰固化的土壤提高56．9％。外加剂的作用机理在于使稳定土早期形成较多的钙矾石。     

石灰及其外加剂固化天津滨海软土的试验研究

天津滨海软土力学性质较差,不能直接满足工程需要,在软土中加入固化剂能有效提高软土的工程力学性能,但若在固化剂中再添加适量外加剂,又能再次提高固化土的强度。本文以石灰作为主剂,水泥、石膏作为辅剂改良天津滨海软土,以无侧限抗压强度作为固化效果判断标准,同时进行相应的微观结构测试,并对破坏后的试样进行抗压试验。试验结果表明:水泥的最佳掺量仅随石灰掺量不同而变化,如12%的石灰固化土中,水泥掺量不超过3%可以最好地提高石灰固化土强度; 石膏则不能改善土体强度,并且会使土体水稳定性差,遇水开裂。纯石灰固化土及掺外加剂的石灰固化土都是低压缩性土,各种力学性质都得到明显提高,其破坏形式为脆性破坏,破坏后强度很低且不能恢复,在实践中值得重视。微观结构分析表明:固化土中有CSH网状胶凝(水化硅酸钙)、针状钙矾石、无定形文石(CaCO3)、Ca(OH)2晶体等能够填充孔隙、胶结颗粒的物质生成,有效、适量的生成物有利于固化土强度的提高。土体中总孔隙个数及总颗粒个数都随荷载的增加而增多,孔隙面积、孔隙等效直径及颗粒等效直径都随荷载的增加而减少。     

GT型土壤固化剂改良土的工程特性研究

GT型土壤固化剂是一种新型的土壤改性加固材料,以高钙灰和脱硫石膏两种工业废料为主要原料,辅以生石灰、水泥、熟石膏、硫酸铝及明矾石等次要成分,采用生石灰消解法除去脱硫石膏中的自由水,按全粉料配料的方法研制而成。按一定掺量向土中掺入石灰和GT型土壤固化剂制成石灰改良土样和固化剂改良土样并进行养护、浸水,对土样进行击实试验、直剪试验、压缩试验和渗透试验。试验结果表明固化剂改良土的击实效果、抗剪强度、压缩性、抗渗透性等工程特性明显优于石灰改良土。分析了GT型土壤固化剂加固土的机理,为进一步的研究和工程应用提供参考。     

工业废渣加固土强度特性

工业废渣的资源化是解决工业废渣环境污染的有效途径之一。以粉煤灰和高炉矿渣为固化剂,石灰为碱性激发剂,对黏土进行加固。通过室内试验的方法,分析固化剂掺入量、养护龄期等对固化土无侧限抗压强度、pH值和饱和度等发展规律的影响。试验结果表明,固化土的无侧限抗压强度随固化剂掺入量的增加而增大,随养护龄期的增加而增大,提出一个综合反映固化剂掺入量、养护龄期和压实度等因素对固化土强度影响规律的综合影响因子,固化土强度与综合影响因子呈负指数函数关系;粉煤灰+石灰和高炉矿渣+石灰可有效改良土体无侧限抗压强度特性;石灰是一种有效的碱性激发剂,可提供工业废渣发生火山灰反应的高碱性环境。试验成果为工业废渣改良不良土质的设计提供试验依据。     

石膏矿采空区充填加固技术的试验研究

石膏矿采空区的处理是一项技术难度大、不确定因素多、工艺复杂的工程,本文通过深入调查研究、总结前期加固处理经验及大量的室内试验,确定了以粘土、石膏、水泥、水玻璃为固化剂的充填加固方案,固化浆液分自流式充填浆液和接顶时的充填浆液,其粘土浆液浓度分别为57．59％和56．7％,室内试验确定的固化剂的最佳配方均为：水泥占7．5％,石膏占7．5％,水玻璃占3．0％,并结合固化剂类型确定了固化充填技术方案。     

新型GS固化土与水泥土的力学特性对比研究

GS(Gypsum-Slag)土体硬化剂是一种由水泥、钢渣、矿渣和脱硫石膏及其他外加剂组成的新型土体固化材料。将GS土体硬化剂和水泥两种固化剂固化土作为研究对象,通过室内无侧限抗压强度试验和电镜扫描试验,研究固化土的应力-应变曲线以及土质、固化剂掺量、龄期对固化土力学性能的影响,观察其微观结构,进而对比分析GS土体硬化剂和水泥的特性,并进行现场试验加以验证。研究结果表明:相比水泥土,GS固化土应力-应变曲线存在明显峰值;GS固化土和水泥土的强度均随着掺量和龄期正增长,且GS固化土的长期强度更高;GS固化土和水泥土变形模量分别是其抗压强度的31.11~77.24倍和23.24~71.62倍;GS固化土现场成桩的完整性优于水泥土。相比水泥土,GS固化土具有强度增长快、后期强度高、经济效益好的特点,可较好满足地下工程和路基工程等土体加固应用需求。     

地质钻探废弃冲洗液固化处理技术研究及应用

在地质钻探废弃冲洗液无害化处理过程中,经固液分离后的废弃固相主要由大量磨细的岩粉和细砂构成,但含水率较高,还含有大量的有机物和重金属离子等有害物质。针对地质岩心钻探废弃固相的固化问题,首先从P.O42.5普通硅酸盐水泥、粉煤灰和石灰3种固化主剂中优选了水泥作为主剂,而后通过正交实验确定了固化剂基础配方为：25% P.O42.5普通硅酸盐水泥+2% PF-3型促凝剂+3% RES-1型复合早强剂,并通过极差分析进行了验证,然后进行了支撑剂加量的确定,7%支撑剂加量既能有效增加固化强度,又不会增加搅拌难度。最后将固化剂配方应用于YK11-2井废弃冲洗液处理野外试验中,固化后的固化体抗压强度达1.41 MPa,各项污染指标和重金属离子符合国家二级排放标准,取得了较好的处理效果。     

CaO对钙矾石固化/稳定化重金属铅污染土的影响

为研究CaO的赋存形态及含量对钙矾石固化/稳定化重金属铅污染土效果的影响,采用高铝水泥提供AlO2-,纯石膏或磷石膏提供SO42-,高铝水泥、石膏、普通硅酸盐水泥或生石灰提供CaO,制备不同组分固化剂配比的固化土,测试试样强度和孔隙溶液pH值等宏观物理力学指标,通过醋酸缓冲溶液法测试试样的铅溶出量,对比分析不同固化剂固化土的矿物成分与微观结构特征。结果表明,钙矾石固化/稳定化重金属铅污染土效果显著;钙矾石对孔隙的填充作用带来的增强效果不能代替水化硅酸钙胶结土颗粒的胶结作用,普通硅酸盐水泥对试样的强度更有利,但其后期强度增幅不大,而生石灰有利于固化土强度的持续增长;生石灰较普通硅酸盐水泥对钙矾石的形成、稳定和重金属Pb2+的固化/稳定化更有利;磷石膏和纯石膏对试样的pH值、无侧限抗压强度及钙矾石固化/稳定化重金属Pb2+的效果影响较小;固化土体微观结构特征表明,CaO含量对钙矾石生成形态及作用效果影响显著。当CaO含量较低时,早期生成的钙矾石将向单硫型硫铝酸钙转化。研究成果可丰富重金属污染场地原位处理技术,具有重要的理论意义和工程应用价值。     

水玻璃基淤泥固化土力学性质试验研究

为解决淤泥固化及其资源化利用的问题,以宁波地区淤泥为研究对象,利用水玻璃基淤泥固化剂制备固化土,通过室内试验、固化机理分析和现场试验研究固化土的力学性质。室内试验给出了无侧限抗压强度和压缩模量随固化剂掺入比改变的规律,并指出存在最佳掺入比为7%;固化机理分析表明随着固化剂掺入比增加,固化土颗粒由鳞片状或条块状向团块状变化,团块体积呈增大趋势,固化土孔隙率小幅增大,中值孔径亦小幅增大,固化土由黏性土向粉土化转变;现场试验取心土样无侧限抗压强度约为室内试验值的70%。结果表明,水玻璃基淤泥固化剂加固淤泥土方案切实可行。     

水泥-矿渣-粉煤灰固化淤泥的水分转化规律及其固化机理研究

为研究石膏激发的水泥-矿渣-粉煤灰固化淤泥的力学强度与水分转化过程的演变规律,从本质上揭示水泥-矿渣-粉煤灰对淤泥的固化机理,通过无侧限抗压强度、抗剪强度试验探究水泥/矿渣/粉煤灰配比、固化剂掺量、养护龄期对固化淤泥土强度的影响,结合核磁共振弛豫分析(NMR)、矿物成分分析(XRD)、微观结构分析(SEM)探究结合水量、水化物种类、微观形貌随养护龄期的变化规律,并建立无侧限抗压强度q_u、抗剪强度参数c、tan φ与结合水量C_w的函数关系。结果表明：14 d龄期内较高水泥配比(20%)的固化土强度显著高于低水泥配比(5%)固化土,其早强效应归功于水化物的大量生成,结合水量大幅提高,14 d龄期后5%水泥配比固化土强度增长迅速并超过20%水泥配比固化土强度。从宏观力学强度看,较高水泥配比(20%)固化土q_u、c、tan φ均与龄期对数lg t呈线性增长关系,低水泥配比(5%)固化土则呈幂型函数关系;从微观水分转化角度分析,高低水泥配比固化土的结合水量与抗压强度、抗剪强度参数的函数关系相同,即q_u-C     

Gypsum Induced Strength Behaviour of Fly Ash-Lime Stabilized Expansive Soil

Physical and engineering properties of soil are improved with various binders and binder combinations. Fly ash and lime are commonly used to improve the properties of expansive soils. An attempt has been made, in this paper, to examine the role of gypsum on the physical and strength behaviour of fly ash-lime stabilized soil. The change in strength behaviour is studied at different curing periods up to 90 days, and the mechanism is elucidated through pH, mineralogical, microstructural and chemical composition study. The strength of soil-fly ash mixture has improved marginally with the addition of lime up to 4 % lime and with curing period for 28 day. Significant increase in strength has been observed with 6 % lime and enhanced significantly after curing for 90 days. The variations in the strength of soil with curing period is due to cation exchange and flocculation initially, and binding of particles with cementitious compounds formed after curing. With addition of 1 % gypsum to soil-fly ash-lime, the strength gain is accelerated as seen at 14 day curing. The accelerated strength early is due to formation of compacted structure with growth of ettringite needles within voids. However, strength at curing for 28 day has been declined due to annoyance of clay matrix with the increase in size of ettringite needle; and again increased after curing for 90 days. The rearrangement of clay matrix and suppression of sulphate effects with formation of cementitious compounds are observed and found to be the main responsible factors for strength recovered.     

泥水盾构隧道废弃泥浆改性固化及强度特性试验

泥水盾构隧道施工产生大量的废弃泥浆,可能带来环境污染、侵占土地等问题,影响城市的正常运转。本文以厦门市某隧道施工现场产生的废弃泥浆为研究对象,采用化学固化技术处置泥浆,测试不同影响因素（固化剂种类、固化剂掺入比、泥浆初始含水率）对改性固化后泥浆抗压强度、pH值、含水率等特性的影响,分析固化机理并解释相关现象,获取最优固化剂种类、掺入比、泥浆初始含水率。对比试验结果表明最优固化剂种类为CERSM泥浆固化剂Ⅱ,掺入比为10%,泥浆初始含水率为100%。在此基础上,本文进一步探讨改性固化后泥浆的强度特性,28 d后固化泥浆抗压强度可达1.5 MPa,是普通水泥固化泥浆强度的4倍,可用做建筑填料,解决环境污染问题,并实现废弃泥浆的资源化利用。     

Compressive and Tensile Behavior of Polymer Treated Sulfate Contaminated CL Soil

In this study, the compressive and tensile behavior of polymer treated sulfate contaminated CL soil was investigated. Based on the information in the literature, a field soil was contaminated with up to 4 % (40,000 ppm) of calcium sulfate in this study. In addition to characterizing the behavior of sulfate contaminated CL soil, the effect of treating the soil with a polymer solution was investigated and the performance was compared to 6 % lime treated soil. In treating the soil, acrylamide polymer solution (15 g of polymer dissolved in 85 g of water) content was varied up to 15 % (by dry soil weight). Addition of 4 % calcium sulfate to the soil decreased the compressive and tensile strengths of the compacted soils by 22 and 33 % respectively with the formation of calcium silicate sulfate [ternesite Ca₅(SiO₄)₂SO₄)], magnesium silicate sulfate (Mg₅(SiO₄)₂SO₄) and calcium-magnesium silicate (merwinite Ca₃Mg(SiO₄)₂). With the polymer treatment the strength properties of sulfate contaminated CL soil was substantially improved. Polymer treated sulfate soils had higher compressive and tensile strengths and enhanced compressive stress–strain relationships compared to the lime treated soils. Also polymer treated soils gained strength more rapidly than lime treated soil. With 10 % of polymer solution treatment, the maximum unconfined compressive and splitting tensile strengths for 4 % of calcium sulfate soil were 625 kPa (91 psi) and 131 kPa (19 psi) respectively in 1 day of curing. Similar improvement in the compressive modulus was observed with polymer treated sulfate contaminated CL soil. The variation of the compacted compressive strength and tensile strength with calcium sulfate concentrations for the treated soils were quantified and the parameters were related to calcium sulfate content in the soil and polymer content. Compressive stress–strain relationships of the sulfate soil, with and without lime and polymer treatment, have been quantified using two nonlinear constitutive models. The constitutive model parameters were sensitive to the calcium sulfate content and the type of treatment.     

Effect of Pozzolanic Reactivity on Compressibility Characteristics of Stabilised Low Lime Fly Ashes

This paper presents the effects of addition of lime and lime along with gypsum on the compressibility behavior of two class F fly ashes. Since the fly ashes develop strength and exhibit lower compression, consolidation testing with conventional duration of load increment may not be appropriate. Hence, an attempt has been made to assess the minimum duration of load increment necessary to study the compressibility characteristics of such materials. Thus compressibility behavior of fly ashes with additives has been studied using conventional consolidation test with different durations of load increments varying from 30 min to 48 h. The results obtained indicated that 30 min of duration of load increment can be used to assess the compressibility behavior of such materials. The effect of lime which reduces the compression is seen to be maximum from the results obtained with the duration of load increment of 30 min but gradually reduces with higher durations of load increment. It has also been observed that the rate of decrease in the compressibility is maximum up to 2.5% lime and gradual thereafter. The compressibility of lime treated fly ashes further reduces when gypsum is incorporated, the optimum gypsum percentage being 2.5. This reduction in the compressibility of fly ashes enhanced by incorporating lime and gypsum makes them versatile in the construction of embankments and for structural fills, particularly reducing the time required in between laying of each lift.     

基于响应面法的淤泥质土固化配方优化研究

选择掺入生石膏、生石灰、碳酸钠来消除有机质对水泥固化淤泥质土的不利影响。以生石膏、生石灰和碳酸钠的掺量作为3个影响因子,以固化淤泥质土7 d和90 d的无侧限抗压强度为响应值,采用旋转中心组合设计安排试验。利用响应面法对这3种外加剂的配比进行优化,并通过单因子效应分析和交互作用分析分别考察各影响因子单独变化对强度响应值的影响以及3种添加剂的交互作用效应。结果表明：强度响应对生石膏和生石灰掺量变化的敏感程度随龄期的增大而增大,而对于碳酸钠,情况则相反。7 d时,生石灰与碳酸钠的交互作用显著;而90 d时,则生石膏与碳酸钠的交互作用显著。最终得出在腐植酸掺量6%和水泥掺量15%前提下,3种外加剂在7 d和90 d的最佳配比。在最优配方的掺加下,对于7 d和90 d龄期固化淤泥质土的实际强度可以分别达到623、1 213 kPa。     

Deformation Modulus of Fly Ash Modified with Lime and Gypsum

Deformation modulus of fly ash is one of the most important mechanical properties generally used in different design problems and also as an input parameter to sophisticated numerical techniques employed to assess the response of different structures resting on fly ash fill or embankment made of fly ash. Deformation modulus is usually expressed in terms of compressive strength. This paper presents the deformation modulus of fly ash modified with lime alone or in combination with gypsum at different strain levels. The values of deformation modulus obtained from both unconfined compression test and unconsolidated undrained triaxial test results are presented herein. The specimens for unconfined compression test and for undrained triaxial tests were cured up to 90 and 28 days, respectively. The effects of addition of lime (4–10%) and gypsum (0.5 and 1.0%) on the deformation modulus of class F fly ash are highlighted. With addition of lime and gypsum, the class F fly ash achieved the deformation modulus in the range of 190 MPa in UCS test and up to 300 MPa in triaxial test specimens tested under all round pressure of 0.4 MPa. Based on the present test results empirical relationships are developed to estimate deformation modulus of modified fly ash from unconfined compressive strength and relationships between initial tangent modulus and secant modulus at different strain levels are also developed.     

Stabilization of Tropical Peat Soil from Sarawak with Different Stabilizing Agents

This paper describes a study on tropical peat soil stabilization to improve its physical properties by using different stabilizing agents. The samples were collected from six different locations of Sarawak, Malaysia, to evaluate their physical or index properties. Out of them, sample having the highest percentage of organic content has been selected for stabilization purposes. In this study, ordinary portland cement (OPC), quick lime (QL), and class F fly ash (FA) were used as stabilizer. The amount of OPC, QL, and FA added to the peat soil sample, as percentage of dry soil mass, were in the range of 5–20%; 5–20% and 2–8%, respectively for the curing periods of 7, 14, and 28 days. The Unconfined Compressive Strength (UCS) test was carried out on treated/stabilized samples with the above mentioned percentages of the stabilizer and the result shows that the UCS value increases significantly with the increase of all stabilizing agent used and also with curing periods. However, in case of FA and QL, the UCS value increases up to 15 and 6%, respectively with a curing period of 28 days but decreases rather steady beyond this percentage. Some UCS tests have been conducted with a mixture of FA and QL to study the combined effect of the stabilizer. In addition, Scanning Electron Microscope (SEM) study was carried out on original peat soil and FA, as well as some treated samples in order to study their microstructures.