Fiber-Reinforcement Optimization Using a Soil Approach

Amir-Faryar, Behzad; Aggour, M S

doi:10.1061/9780784413272.244

Cited by 4 publications

(3 citation statements)

References 4 publications

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“…Furthermore, the damping ratio decreased with the addition of rubber under low confining pressure (σ c = 50 kPa and 100 kPa) and increased with increase of rubber content under high confining pressure [19]. Moreover, various models and methods related to failure criteria, plastic theory and limit analysis under dynamic loading were developed by many researchers to investigate the dynamic behavior of reinforced soil [3,[20][21][22][23][24][25][26][27][28]. On the other hand, soil reinforcement with different types of fiber plays a significant role in mechanical and thermal properties of soil.…”

Section: Introductionmentioning

confidence: 99%

Dynamic behavior of fiber-reinforced soil under freeze-thaw cycles

Niu

Liu

Orakoğlu

2017

Soil Dynamics and Earthquake Engineering

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This research presents the dynamic behavior of fiber-reinforced soil exposed to freeze-thaw cycles. The series of dynamic triaxial tests were conducted on fine-grained soil mixed with different percentages of basalt and glass fibers subjected to freeze-thaw cycles. The results showed that after freeze-thaw cycles, with the addition of basalt and glass fibers, the damping ratio and the shear modulus increased at a constant confining pressure because of the increase of stiffness, but the shear modulus decreased with increasing shear strain. Moreover, the theoretical analytical formulations were developed to define for dynamic shear stress and dynamic shear modulus. The parameters were predicted by Hardin-Drnevich model and Kondner-Zelasko model. The shear modulus was expressed as a function of freeze-thaw cycles, fiber contents, confining pressure and initial water content. Finally, ten coefficients were calibrated by analyzing the experimental results and then employed to describe dynamic shear modulus of the fiber-reinforced soil.

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Section: Introductionmentioning

confidence: 99%

Dynamic behavior of fiber-reinforced soil under freeze-thaw cycles

Niu

Liu

Orakoğlu

2017

Soil Dynamics and Earthquake Engineering

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“…For a fiber content of 0.2% that exceeds the optimum percentage, the improvement extent became marginal in comparison with the compaction characteristics of pure sand. In fact, Amir-Faryar and Aggour (2014) estimated that extra fibers replace soil particles instead of only filling the voids. Hence, the sand grains cannot be close to each other.…”

Section: Resultsmentioning

confidence: 99%

“…The studies have shown that the improvement extent of fiber-reinforced soils really depends on the adopted fiber content. For instance, the engineering properties of the reinforced mixtures change with various fiber contents ( Amir-Faryar and Aggour, 2012 , 2014 ). Furthermore, the effectiveness of fiber inclusion is considerably dependent on the tested soil ( Patel and Singh, 2017 ).…”

Section: Introductionmentioning

confidence: 99%

Improving the compaction properties and shear resistance of a sand reinforced with COVID-19 waste mask fibers

Said¹,

Rahhal²

2022

Heliyon

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Effect of fibre inclusion on dynamic properties of clay

Amir-Faryar

Aggour

2015

Geomechanics and Geoengineering

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One of the causes of heavy damage due to earthquake motions is the role of soft clay in amplifying bedrock ground motions. Improving the soil conditions using polypropylene fibres at a site in order to mitigate earthquake damage could be one of the methods to modify site conditions. In this study, the optimum fibre contents were obtained for mixtures of clay with two different types of fibre. Then the dynamic properties of polypropylene fibre reinforced clay with different fibre contents were determined using resonant column testing. The study showed that the inclusion of fibre at optimum fibre content can improve the dynamic properties of clay at the low shear strains used. Test results indicated that both the shear modulus and damping increased. Hence, the inclusion of fibre in clay can provide a double benefit for the dynamic response of a site by increasing the stiffness of the site and reducing its amplitude of vibration.

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Fiber-Reinforcement Optimization Using a Soil Approach

Cited by 4 publications

References 4 publications

Dynamic behavior of fiber-reinforced soil under freeze-thaw cycles

Dynamic behavior of fiber-reinforced soil under freeze-thaw cycles

Improving the compaction properties and shear resistance of a sand reinforced with COVID-19 waste mask fibers

Effect of fibre inclusion on dynamic properties of clay

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