Assessing Stabilization Effectiveness of Combined Cement Kiln Dust and Quarry Fines on Pavement Subgrades Dominated by Black Cotton Soil

In developing technically viable and economically sustainable methods of improving soil properties to suit the requirements of engineering structures, designers/engineers are to take into consideration the availability and cost effectiveness of materials required for such improvement scheme. In line with this, the present study evaluates stabilization effectiveness of combined quarry fines (QF) and cement kiln dust (CKD) on subgrades dominated by black cotton soil (BC soil). The experimental programme included Atterberg limits, compaction and California bearing ratio (CBR) tests on soil mixtures prepared with a representative BC soil at constant dosage of 10 % QF and 0, 4, 8, 12 and 16 % CKD. Prior to testing, soil mixtures for CBR test prepared at optimum moistures and compacted with British standard light compaction effort were soaked for 96 h after curing for 28 days. Test data show that the addition of QF and CKD together reduced the plasticity index that resulted in rapid textural changes and eventual improvement in constructability, led to an increase in the optimum moisture content and a decrease in the maximum dry unit weight. Furthermore, the coupled effects of QF and CKD resulted in substantial increase in CBR strength of the composite specimens. Overall, mixtures created using the proposed QF and CKD ratios rendered the soil physically and mechanically stable producing results that are compatible with desired values for engineering performance typically required by various user agencies for pavement subgrades. This improvement scheme is not only cost effective, but it is capable of lessening the demand on non renewable resources thereby reducing the footprint of road construction projects in the environment.     

Assessment of Cement Kiln Dust-Treated Expansive Soil for the Construction of Flexible Pavements

An expansive soil (black cotton soil) treated with up to 10 % cement kiln dust (CKD), a waste obtained from the manufacture of cement, was evaluated for use as a flexible pavement construction material. Laboratory tests were carried out on specimens compacted with British Standard light, British Standard light or standard Proctor (relative compaction = 100 %) energy. Results obtained show that the index properties of the soil improved with CKD treatment. Peak unconfined compressive strength of 357.07 kN/m² and California bearing ratio (CBR) of 7 % as well as resistance to loss in strength of 44 % were recorded at 10 % CKD treatment. Reduction in the particle sizes with curing period was observed when samples were viewed through the scanning electron microscope. The study showed that CKD can be beneficially used to improve the subgrade of lightly trafficked roads and as admixture in lime stabilization during construction of flexible pavements over expansive soil.     

Desiccation-Induced Volumetric Shrinkage of Compacted Foundry Sand Treated with Cement Kiln Dust

Foundry sand, an industrial waste, was treated with up to 12 % cement kiln dust content at comparative energy levels of British standard light, West African standard or “intermediate” (WAS) and British standard heavy (BSH) efforts at molding water contents ?2, 0, 2, 4 and 6 % of optimum moisture content. Samples were extruded from the compaction molds and allowed to air dry in the laboratory in order to assess the effect of desiccation-induced shrinkage on the material for use as a hydraulic barrier in waste containment application. Results recorded show that volumetric shrinkage strain (VSS) values were large within the first 5 days of drying; VSS values increased with higher molding water content, water content relative to the optimum moisture content. VSS generally increased with higher initial degree of saturation for all compactive efforts, irrespective of the level of cement kiln dust (CKD) treatment. A compaction plane of acceptable zones for VSS based on the regulatory value is ≤4 %. The influence of CKD treatment generally showed a decrease in the desiccation-induced volumetric shrinkage strain with increasing CKD content. This is largely due to the pozzolanic input of CKD. Finally, only the BSH compactive effort gave successful results of volumetric shrinkage strain at CKD treatment content of between 4 and 8 %, while 12 % CKD content produced successful volumetric shrinkage strain results at WAS and BSH compactive effort, respectively.     

Potential Application of Lateritic Soil Stabilized with Cement Kiln Dust (CKD) as Liner in Waste Containment Structures

This study evaluates the applicability of residually derived lateritic soil stabilized with cement kiln dust (CKD), a waste product from the cement manufacturing process as liner in waste repositories. Lateritic soil sample mixed with 0–16 % CKD (by dry weight of the soil) was compacted with the British Standard Light, West African Standard and British Standard Heavy compaction efforts at water contents ranging from the dry to wet of optimum moistures. Geotechnical parameters such as Atterberg limits, compaction characteristics, hydraulic conductivity, unconfined compressive strength and volumetric shrinkage strain were determined. Results indicate that the plasticity index, the maximum dry unit weight and hydraulic conductivity together with the volumetric shrinkage decreased with increased amount of CKD while the optimum moisture content and unconfined compressive strength increased with higher CKD content for all the efforts. When measured properties were compared with standard specifications adopted by most environmental regulatory agencies for the construction of barrier systems in waste containment structures, the resulting values showed substantial compliance. Besides developing an economically sustainable liner material, the present study demonstrated effective utilization of an industrial by-product otherwise considered as waste by the producers, in addition to a systematic expansion in the use of the lateritic soil for geotechnical works.     

Use of Cement Kiln Dust on the Engineering Modification of Soil Materials,Nile Delta,Egypt

Cement kiln dust (CKD) is the by-product generated from the manufacture of Portland cement. Disposal quantities of CKD in construction project are required to protect the environment. In the recent construction experience in the area of study at the last years showed that, ground and underground engineering on the soft soil are susceptible to various types of cracking in buildings and roads. The improvement of engineering properties of two disturbed soils by using CKD in different percentages (5, 10 and 20 %) was discussed in this paper. The results indicated that CKD additives increased the pH values and decreased the plasticity index in both types of soils under investigation. The maximum dry density (MDD) decreased and optimum moisture content (OMC) increased with increasing the percentage of CKD in soil A. In soil B the MDD and OMC decreased.     

Stabilization of a Clayey Soil with Fly Ash and Lime: A Micro Level Investigation

Pavement structures on poor soil sub grades show early distresses causing the premature failure of the pavement. Clayey soils usually have the potential to demonstrate undesirable engineering behavior, such as low bearing capacity, high shrinkage and swell characteristics and high moisture susceptibility. Stabilization of these soils is a usual practice for improving the strength. This study reports the improvement in the strength of a locally available cohesive soil by addition of both fly ash and lime. Analysis using X-ray diffraction, scanning electron microscopy, coupled with energy dispersive spectroscopy, thermal gravimetric analysis, zeta potential and pH value test was carried out in order to elucidate the stabilization mechanism. The micro level analysis confirmed the breaking of montmorrillonite structure present in the untreated clay after stabilization. In the analysis, it was also confirmed that in the stabilization process, pozzolanic reaction dominated over the cation exchange capacity.     

Magnetic Influences of Cement Dust on Soil in Industrial Area and Its Environmental Implications

To monitor environmental implications of cement dust on soil in industrial area, magnetic parameters and mineral compositions were measured by the samples of the cement dust, cement factory dustfall, cement, coal ash, topsoil of green space in the factory and topsoil outside the factory. Results showed that the major magnetic minerals in the samples were magnetite, the magnetic mineral particle size of cement dust, dustfall, cement and coal ash was coarse Multi-Domian (MD) and Pseudo-Single-Domain (PSD). As topsoil of green space in the factory and topsoil outside the factory were polluted by cement dust, their magnetic properties had been obviously changed; the concentration of magnetic minerals elevated and particle size became coarser. The magnetic parameters (χ_fd,χ_ARM/χ,χ_ARM/SIRM) value can reflect the pollution level of the soil, the lower its value was, the more serious soil was polluted. X-ray diffraction results showed that the mineral compositions of the topsoil of green space in the factory and topsoil outside the factory were quartz and calcite, which were the same as cement dust. Magnetic parameters combination characteristics of topsoil can monitor the soil environmental changes in cement industry area.     

Consolidation and Drainage Characteristics of Expansive Soil Stabilized with Fly Ash and Dolochar

Expansive soils undergo alternate swelling and shrinkage due to cyclic wetting and drying when left to nature. This property of Expansive soil affects its strength and stiffness characteristics thereby causing damage and distress to structures built on them. Industrial wastes can be added scientifically to these soils in modifying and reducing their swelling and shrinkage behaviour and increasing their strength and stiffness. In this technical article, an attempt has been made to study the compressibility and drainage characteristics of these soils using economic and ecofriendly industrial wastes such as Fly Ash and Dolochar as stabilizers. This paper also focuses on many other improved engineering properties of base soil like liquid limit, plasticity index, differential free swell, compaction and consolidation characteristics of Expansive (BC) soil stabilized with Fly Ash and Dolochar in different proportions. The virgin Expansive soil has been collected from eastern part of India (Odisha) and different percentages of Fly Ash (5, 10, 15, 20, 25 and 30 %) and Dolochar (5, 10, 15, 20, 25 and 30 %) were added to it, to predict the influence of these additives on compaction and consolidation characteristics of Expansive soil. Addition of both Fly Ash and Dolochar were found to decrease the index properties such as liquid limit, plastic limit, plasticity index, swelling index and enhancing the consolidation as well as drainage characteristics of Expansive soil. However, the maximum dry density of soil was found to decrease with addition of Fly Ash and increase with addition of Dolochar.     

关于测流断面水位级划分方法的探讨

通过数理统计方法划分水位级发现的问题,结合实际,考虑当地水文特性、测站测洪能力和测洪方案及影响水位的各种因素,探讨了合理划分水位级的方法.提出了确定一个水位级为参照值,采用与历年最低水位变幅的适当比例划分其它水位级的方法.     

土的组成、结构与固化技术

在对土的组成及其结构进行深入分析的基础上 ,认为土固化基本原理就是强化土颗粒间结构连结 ,改善颗粒接触 ,提出由化学作用而形成的同相接触是提高粘土体系强度的关键技术 ,并总结了土固化的几个重要技术途径。对目前采用最多的土固化方法———土壤固化剂法进行了分析 ,对几类土壤固化剂及其机理进行了阐述。对固化土收缩开裂、水稳定性和抗冻性等几个影响固化土耐久性的主要因素进行了分析探讨     

Stabilization of Expansive Clays Using Granulated Blast Furnace Slag (GBFS) and GBFS-Cement

Expansive clays undergo swelling when subjected to water. This can cause damage, especially to light weight structures, water conveyance canals, lined reservoirs, highways, and airport runways unless appropriate measures are taken. In this study, granulated blast furnace slag (GBFS) and GBFS-cement (GBFSC) were utilized to overcome or to limit the expansion of an artificially prepared expansive soil sample (sample A). GBFS and GBFSC were added to sample A in proportions of 5–25% by weight. The effects of these stabilizers on grain size distribution, Atterberg limits, swelling percentage and rate of swell of soil samples were determined. GBFS and GBFSC were shown to successfully decreasing the total amount of swell while increasing the rate of swell.     

CFG桩加固的效应及其应用

对CFG桩单柱承载力和CFG桩复合地基承载力及其沉降进行了分析，讲座了CFG桩复合加固效应，以工程实例说明了CFG复合地基在工程中的应用。     

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.     

膨胀土的强度与含水量的关系

膨胀土的强度与含水量密切相关。针对这问题进行了相应的试验研究。结果表明,膨胀土的含水量对其峰值强度、稳态强度都有着强烈影响,这对工程设计和工程安全检测非常重要。     

某水泥粉磨站CFG桩复合地基的设计与施工

结合工程实例，根据场区工程地质条件和结构设计要求，对采用CFG桩复合地基技术进行地基加固处理的设计、施工与检测进行了介绍，对加固处理效果进行了评价。     

纤维对石灰改良膨胀土性质的影响分析

首先对膨胀土基本性质做了试验分析,通过天然膨胀土和掺人纤维前后的石灰土的击实试验,得出了掺人少量纤维对石灰土的最优含水率和最大干密度影响很小.通过有荷膨胀率试验,得出了纤维能够抑制石灰土的膨胀性,纤维掺人量在0.05%～0.1%之间时,线膨胀率随纤维掺人量的增多而降低显著,在0.1%～0.2%之间时降低幅度减小.由无侧...     

采用扁铲侧胀试验估算土的侧向基床系数的探讨

根据双曲线拟合压缩试验和载荷试验形态，拟合扁铲侧胀试验形态，从小应变的扁铲侧胀试验推导出在工程上实用的大应变的土的侧向基床系数。     

带放坡的水泥土墙体厚度计算方法研究

以亚洲铝业（中国）有限公司40万t铝板带工程深基坑支护为例，以水泥土墙截水挡土，基坑内紧贴搅拌桩土体按1：1放坡．设计时考虑放坡土体的剪应力对土压力的抵抗作用，从而大大减小了水泥土墙的厚度。通过基坑开挖后检验，表明该计算方法是经济合理的。     

冻融循环下初始含水率对非饱和膨胀土剪切特性试验

为探究冻融循环条件下初始含水率对膨胀土偏应力-应变关系和剪切特性的影响,本文对不同初始含水率的非饱和膨胀土进行了不固结不排水三轴剪切试验。结果表明：1）非饱和膨胀土的偏应力-应变曲线的形式随含水率增大由应变软化逐渐转变为应变硬化,偏应力峰值随含水率增大而降低;2）非饱和膨胀土的抗剪强度随初始含水率的增加呈线性下降趋势;3）非饱和膨胀土在第1次冻融循环后偏应力及抗剪强度大幅度下降,在3~7次冻融循环后达到稳定。初始含水率是影响非饱和膨胀土力学性质的主要原因。