A platform for research: civil engineering, architecture and urbanism
A platform for research: civil engineering, architecture and urbanism
Liquefaction resistance of Babolsar sand reinforced with randomly distributed fibers under cyclic loading
Abstract This research explores the performance of randomly distributed fibers in enhancing the liquefaction resistance and shear modulus of loose and medium dense sand deposits. Thirty stress-controlled cyclic triaxial tests were performed on saturated samples with and without reinforcements under undrained conditions. The effect of parameters such as fiber content, fiber length, relative density and confining pressure on liquefaction behavior of unreinforced and reinforced specimens was studied. Test results indicated that the fiber inclusions significantly increased liquefaction resistance of sand specimens. Upon increasing the fiber content and fiber length, the number of loading cycles leading to liquefaction increased. The reinforcement effect in medium dense samples was found to be more significant than that of looser samples. Further, the confining pressure had a considerable effect in reducing the liquefaction susceptibility. Shear modulus of unreinforced and reinforced samples was also evaluated; the results revealed that the shear modulus increases with increasing fiber content.
Highlights The presence of fibers increases the liquefaction resistance of Babolsar sand. Fiber reinforcement can limit or prevent the occurrence of lateral movement. The effect of reinforcement in medium dense samples was more than that of looser one. The inclusion of fibers increases the shear modulus.
Liquefaction resistance of Babolsar sand reinforced with randomly distributed fibers under cyclic loading
Abstract This research explores the performance of randomly distributed fibers in enhancing the liquefaction resistance and shear modulus of loose and medium dense sand deposits. Thirty stress-controlled cyclic triaxial tests were performed on saturated samples with and without reinforcements under undrained conditions. The effect of parameters such as fiber content, fiber length, relative density and confining pressure on liquefaction behavior of unreinforced and reinforced specimens was studied. Test results indicated that the fiber inclusions significantly increased liquefaction resistance of sand specimens. Upon increasing the fiber content and fiber length, the number of loading cycles leading to liquefaction increased. The reinforcement effect in medium dense samples was found to be more significant than that of looser samples. Further, the confining pressure had a considerable effect in reducing the liquefaction susceptibility. Shear modulus of unreinforced and reinforced samples was also evaluated; the results revealed that the shear modulus increases with increasing fiber content.
Highlights The presence of fibers increases the liquefaction resistance of Babolsar sand. Fiber reinforcement can limit or prevent the occurrence of lateral movement. The effect of reinforcement in medium dense samples was more than that of looser one. The inclusion of fibers increases the shear modulus.
Liquefaction resistance of Babolsar sand reinforced with randomly distributed fibers under cyclic loading
Noorzad, R. (author) / Fardad Amini, P. (author)
Soil Dynamics and Earthquake Engineering ; 66 ; 281-292
2014-07-15
12 pages
Article (Journal)
Electronic Resource
English
Calibration of an Advanced Constitutive Model for Babolsar Sand Accompanied by Liquefaction Analysis
| Taylor & Francis Verlag | 2017
Calibration of an Advanced Constitutive Model for Babolsar Sand Accompanied by Liquefaction Analysis
| Online Contents | 2017
Calibration of an Advanced Constitutive Model for Babolsar Sand Accompanied by Liquefaction Analysis
| Online Contents | 2016
Liquefaction strength of fly ash reinforced with randomly distributed fibers
| British Library Conference Proceedings | 2002