Performance of geosynthetic reinforced/stabilized paved roads built over soft soil under cyclic plate loads

Abu-Farsakh, Murad; Hanandeh, Shadi; Mohammad, Louay N.; Chen, Qiming

doi:10.1016/j.geotexmem.2016.06.009

Cited by 70 publications

(25 citation statements)

References 9 publications

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“…The load amplitude value was supported by previous studies. Most of the researchers used single wheel load between 108 kPa to 800 kPa with frequency ranging from 0.33 Hz to 2 Hz to simulate traffic loading (Faragher et al, 2000;Tafreshi and Khalaj, 2008;Tafreshi and Dawson, 2010;Cao et al, 2016;Abu-Farsakh et al, 2016;Khalaj et al, 2017;Wang et al, 2018). To apply the load uniformly, the ballsocket arrangement was used.…”

Section: Preparation Of Test Bed and Proceduresmentioning

confidence: 99%

“…Repetitive load application causes large settlements in substructure, which ultimately causes failure in the structure. Reinforcing weak soils with geosynthetics and metallic strips are very much acceptable in current construction practices (Gabr and Han, 2005;El Sawwaf and Nazir, 2010;Chen and Abu-Farsakh, 2015;Abu-Farsakh et al, 2016;Sahu et al, 2018). Planar geotextiles (woven and non-woven), geogrids, and three-dimensional geocell reinforcements are used to strengthen the weak subgrades.…”

Section: Introductionmentioning

confidence: 99%

“…This deformation of subgrade layer generally caused due to the wheel load. Many researchers have highlighted the beneficial effects of geosynthetic reinforcements in foundation applications under static and dynamic loadings (Tafreshi and Dawson, 2010;Asakereh et al, 2013;Hegde and Sitharam, 2013;Abu-Farsakh et al, 2013;Elsaied et al, 2015;Chen and Abu-Farsakh, 2015;Saride et al, 2015;Abu-Farsakh et al, 2016;Hegde and Sitharam, 2016;Suku et al, 2016;Elleboudy et al, 2017;Sahu et al, 2018). However, the behavior of reinforced pavement sections under repeated wheel loads was studied by very few researchers.…”

Section: Introductionmentioning

confidence: 99%

“…However, the behavior of reinforced pavement sections under repeated wheel loads was studied by very few researchers. The dynamic loadings with varying amplitudes and frequency cause permanent deformations in subgrades (Leng and Gabr, 2002;Saride et al, 2015;Abu-Farsakh et al, 2016;Suku et al, 2016;Elleboudy et al, 2017). Thus, the subgrade soils should be tested under cyclic loads before construction of pavement.…”

Section: Introductionmentioning

confidence: 99%

“…The use of geocell mattress as a reinforcement decreased the accumulation of plastic strain in subgrade. Abu-Farsakh et al (2016) conducted model tests on reinforced pavement sections using triaxial geogrid and woven geotextile under repeated loading. The study showed that the use of geosynthetic at base-subgrade interface increased the traffic benefit ratio (TBR) beyond 1.5.…”

Section: Introductionmentioning

confidence: 99%

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Performance of Geosynthetics Reinforced Subgrade Subjected to Repeated Vehicle Loads: Experimental and Numerical Studies

Hegde

Palsule

2020

Front. Built Environ.

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Use of the geosynthetics to strengthen the soil is one of the highly desirable techniques under static and dynamic loads. The present study describes the experimental and numerical studies performed on the geosynthetic reinforced subgrade subjected to repeated vehicle loads. The cyclic plate load tests were conducted on the sand subgrade reinforced with planar and 3D geosynthetic reinforcements. The vehicle load was simulated by applying a repeated load of magnitude 275 kPa with 1 Hz frequency on the reinforced subgrade. Results of the experimental investigations revealed that the performance of the subgrade soil improved significantly in the presence of reinforcements. The estimated parameters illustrated the three-fold reduction in settlement of the subgrade in the presence of reinforcement. Further, the heaving of the subgrade soil was found completely arrested with the use of geosynthetic reinforcement. The three-dimensional geocell reinforcement performed effectively as compared to planar geogrids under dynamic load. The measured pressure values at different depth demonstrated a significant reduction in the pressure in the presence of reinforcements. Besides, numerical simulations were performed using PLAXIS 2D to understand pressure and settlement distribution patterns in the reinforced subgrade. In overall, a good agreement was observed between numerical and experimental results.Abbreviations: B, width of geocell mattress (mm); C, cohesion of unreinforced sand (kPa); C c , coefficient of curvature (dimensionless); C r , increased apparent cohesion (kPa); C u , uniformity coefficient (dimensionless); C , total apparent cohesion (kPa); d 0 , equivalent geocell pocket diameter (mm); D, width of loading plate (mm); D 10 , effective particle size (mm); δ, soil surface settlement (mm); e min , minimum void ratio (dimensionless); e max , maximum void ratio (dimensionless); E, young's modulus of elasticity (kPa); ε a , axial strain (dimensionless); G, shear modulus (kPa); G s , specific gravity of sand (dimensionless); γ d , dry unit weight (kN/m 3 ); h, height of geocell (mm); H, height of sand bed (mm); k p , coefficient of passive earth pressure (dimensionless); M, secant modulus of geocell material (kPa); N r , number of loading cycles for reinforced case (dimensionless); N u , number of loading cycles for unreinforced case (dimensionless); r, radial distance from the center of loading plate (mm); S 0 , settlement of unreinforced subgrade (mm); S r , settlement of reinforced subgrade (mm); σ n , horizontal stress increment (kPa); σ ' yy , vertical effective stress (kPa); w, specific weight (kN/m/m); W, width of the sand bed (mm); µ, poisson's ratio (dimensionless); z, depth of geocell (mm); α/β, rayleigh damping parameters (dimensionless); φ, angle of internal friction (degrees); ψ, dilatancy angle (degrees).Frontiers in Built Environment | www.frontiersin.org 1 February 2020 | Volume 6 | Article 15

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