A Comparative Evaluation of Cement and By-Product Petrit T in Soil Stabilization

Abstract: This study presents a comparison between the effectiveness of adding low binder amounts of industrial by-product Petrit T as well as cement to modify and improve fine-grained soil. Binder amount was added by soil dry weight; cement at 1%, 2%, 4% and 7% and Petrit T at 2%, 4% and 7%. The unconfined compressive strength (UCS) was used as an indicator of soil strength. In addition, the consistency limits, laser particle size analysis, and pH tests were also conducted on the treated soil. The samples were cured at… Show more

“…Conversely, the strain decreased from 2.58% for untreated to 2.08%, 1.56%, 1.37%, and 1.19% for 3%, 6%, 9%, and 12% cement content within 7 days curing. The results obtained for the ductility change with increasing cement and curing time in this research were compatible with [2,70,82,100] in that the authors indicated higher brittleness for high cement content and more curing time. Similarly, in the current study, the ductility changes of a specimen mixed with 3% cement, with a curing time, were not considerable, whereas the ductility significantly decreased for 6%, 9%, and 12% cement.…”

“…demonstrate that compressive strength was enhanced with cement content and curing time, the effectiveness of 3% cement was not significant. This behavior could be attributed to the low pH value, whereby the cement could not improve soil strength effectively at a pH value smaller than 12.4 [82]. The UCS results in Figure 7 show that the 6% cement was adequate for stabilizing the lateritic soil to achieve a minimum UCS of 0.8 MPa, according to Malaysia Public Works Department (MPWD) standards.…”

“…demonstrate that compressive strength was enhanced with cement content and curing time, the effectiveness of 3% cement was not significant. This behavior could be attributed to the low pH value, whereby the cement could not improve soil strength effectively at a pH value smaller than 12.4 [82].…”

“…In regard to Table 4, the obtained equation for E50 in this study was within the range of previous studies, particularly the study carried out by Rashid et al [2] in Malaysia. [82] Cement-admixed (5-20%) Bangkok clay in Thailand E 50 = 150 q u [102] Cement-stabilized (10%) and cement kiln dust-stabilized (10-13%) high-plasticity soft Bangkok clay in Thailand E 50 = 113 q u [103] Cement-stabilized (10-20%) marine clay in China E 50 = (150-275) q u [104] Cement-treated (3-9%) laterite soil in Cameroon E = 117.39 q u − 36.812 [86] 3.5. Durability…”

“…In this regard, one can refer to [43] for more detail. Therefore, OPC could still be considered an effective stabilizer agent in the construction of transportation infrastructure, as Al-Jabban et al [81] stated, based on their research that cement was more effective in improving the engineering properties of fine-grained soil compared to Petrit-T, a by-product obtained from sponge iron manufacturing [82]. Although some studies have been conducted in determining the optimum OPC for low-volume roads according to MPWD standards, the small number of studies and discrepancies between obtained results motivated the conducting of this research.…”

Strength and Durability of Cement-Treated Lateritic Soil

“…Conversely, the strain decreased from 2.58% for untreated to 2.08%, 1.56%, 1.37%, and 1.19% for 3%, 6%, 9%, and 12% cement content within 7 days curing. The results obtained for the ductility change with increasing cement and curing time in this research were compatible with [2,70,82,100] in that the authors indicated higher brittleness for high cement content and more curing time. Similarly, in the current study, the ductility changes of a specimen mixed with 3% cement, with a curing time, were not considerable, whereas the ductility significantly decreased for 6%, 9%, and 12% cement.…”

“…demonstrate that compressive strength was enhanced with cement content and curing time, the effectiveness of 3% cement was not significant. This behavior could be attributed to the low pH value, whereby the cement could not improve soil strength effectively at a pH value smaller than 12.4 [82]. The UCS results in Figure 7 show that the 6% cement was adequate for stabilizing the lateritic soil to achieve a minimum UCS of 0.8 MPa, according to Malaysia Public Works Department (MPWD) standards.…”

“…demonstrate that compressive strength was enhanced with cement content and curing time, the effectiveness of 3% cement was not significant. This behavior could be attributed to the low pH value, whereby the cement could not improve soil strength effectively at a pH value smaller than 12.4 [82].…”

“…In regard to Table 4, the obtained equation for E50 in this study was within the range of previous studies, particularly the study carried out by Rashid et al [2] in Malaysia. [82] Cement-admixed (5-20%) Bangkok clay in Thailand E 50 = 150 q u [102] Cement-stabilized (10%) and cement kiln dust-stabilized (10-13%) high-plasticity soft Bangkok clay in Thailand E 50 = 113 q u [103] Cement-stabilized (10-20%) marine clay in China E 50 = (150-275) q u [104] Cement-treated (3-9%) laterite soil in Cameroon E = 117.39 q u − 36.812 [86] 3.5. Durability…”

“…In this regard, one can refer to [43] for more detail. Therefore, OPC could still be considered an effective stabilizer agent in the construction of transportation infrastructure, as Al-Jabban et al [81] stated, based on their research that cement was more effective in improving the engineering properties of fine-grained soil compared to Petrit-T, a by-product obtained from sponge iron manufacturing [82]. Although some studies have been conducted in determining the optimum OPC for low-volume roads according to MPWD standards, the small number of studies and discrepancies between obtained results motivated the conducting of this research.…”

Strength and Durability of Cement-Treated Lateritic Soil

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