J. James, A. Kirubhakaran, R. Balamurukan, V. Jawahar, S. S. Soorya
{"title":"Wetting-Drying Resistance of a Lime Stabilized Soil Amended with Steel Slag and Reinforced with Fibres","authors":"J. James, A. Kirubhakaran, R. Balamurukan, V. Jawahar, S. S. Soorya","doi":"10.15332/iteckne.v18i1.2490","DOIUrl":null,"url":null,"abstract":"The investigation dealt with the stabilization of expansive soil with combinations of lime, steel slag and reinforced with two types of fibres, copper filaments and polypropylene fibres. The investigation began with the characterization of the soil for its geotechnical properties. The initial consumption of lime required for the modification of the soil properties was determined from the Eades and Grim pH test. Cylindrical specimens of soil with dimensions 38 mm x 76 mm were cast using this lime content as a stabilizer along with varying quantities of steel slag for determination of optimum steel slag content. The pure lime stabilized soil as well as lime-steel slag modified soil specimens were reinforced with different proportions of copper filaments for determination of optimum fibre content. One dosage of polypropylene fibres was also adopted as reinforcement in specimen preparation. The optimal combinations identified were then subjected to a maximum of three cycles of wetting and drying followed by determination of unconfined compression strength (UCS). The expansive soil required a minimum of 3% lime for its modification. The optimum dosage of steel slag was identified as 5% and optimum copper filament content as 1%. Polypropylene content of 0.3% was also adopted as one combination. The results of the investigation revealed that lime stabilized fibre-reinforced soil with copper filaments was the most durable combination followed by polypropylene fibres. The introduction of steel slag in the mix could not generate enough beneficial durability to the soil after three cycles of wetting and drying.","PeriodicalId":53892,"journal":{"name":"Revista Iteckne","volume":" ","pages":""},"PeriodicalIF":0.5000,"publicationDate":"2020-12-17","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"2","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Revista Iteckne","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.15332/iteckne.v18i1.2490","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q4","JCRName":"ENGINEERING, MULTIDISCIPLINARY","Score":null,"Total":0}
引用次数: 2
Abstract
The investigation dealt with the stabilization of expansive soil with combinations of lime, steel slag and reinforced with two types of fibres, copper filaments and polypropylene fibres. The investigation began with the characterization of the soil for its geotechnical properties. The initial consumption of lime required for the modification of the soil properties was determined from the Eades and Grim pH test. Cylindrical specimens of soil with dimensions 38 mm x 76 mm were cast using this lime content as a stabilizer along with varying quantities of steel slag for determination of optimum steel slag content. The pure lime stabilized soil as well as lime-steel slag modified soil specimens were reinforced with different proportions of copper filaments for determination of optimum fibre content. One dosage of polypropylene fibres was also adopted as reinforcement in specimen preparation. The optimal combinations identified were then subjected to a maximum of three cycles of wetting and drying followed by determination of unconfined compression strength (UCS). The expansive soil required a minimum of 3% lime for its modification. The optimum dosage of steel slag was identified as 5% and optimum copper filament content as 1%. Polypropylene content of 0.3% was also adopted as one combination. The results of the investigation revealed that lime stabilized fibre-reinforced soil with copper filaments was the most durable combination followed by polypropylene fibres. The introduction of steel slag in the mix could not generate enough beneficial durability to the soil after three cycles of wetting and drying.
研究了石灰、钢渣复合材料和铜丝和聚丙烯纤维两种纤维加固膨胀土的稳定性。调查开始于对土壤的岩土力学特性进行表征。通过Eades和Grim pH试验确定了改良土壤特性所需的石灰的初始消耗量。用这种石灰含量作为稳定剂和不同数量的钢渣一起铸造尺寸为38 mm x 76 mm的圆柱形土壤样品,以确定最佳钢渣含量。采用不同比例的铜丝对纯石灰稳定土和石灰钢渣改性土进行加固,以确定最佳纤维含量。在试样制备中还采用了一种剂量的聚丙烯纤维作为增强剂。确定的最佳组合,然后进行最多三个循环的润湿和干燥,然后确定无侧限抗压强度(UCS)。膨胀土至少需要3%的石灰进行改性。确定钢渣的最佳掺量为5%,铜长丝的最佳掺量为1%。聚丙烯含量0.3%为一种组合。结果表明,铜丝石灰稳定纤维增强土的耐久性最高,其次是聚丙烯纤维增强土。在混合料中加入钢渣,经过三次干湿循环后,不能对土壤产生足够的有益耐久性。