جستجوی مقالات مرتبط با کلیدواژه "grid" در نشریات گروه "عمران"

Soil reinforcement is one of the soil improvement techniques. Over the last four decades, a large number of researches have been carried out in order to obtain the reinforcement type and the bearing capacity improvement of the reinforced soil. A new reinforcement type called Grid-Anchor (G-A) has been recently invented which is made of geogrids by adding polymer anchors to it. In this study the bearing capacity of ring and circular footings located on granular soils reinforced with the G-A is investigated using numerical analyses. Commercial finite-element software PLAXIS is employed to perform the simulations. The effect of depth of the first reinforcement layer, the vertical spacing, the number and width of reinforcement layers, the distance that anchors are effective, for each foundation were investigated. The effect of reinforcement stiffness for two types of footing has been investigated. A comparison between the results obtained for the G-A and geogrid reinforcement systems and unreinforced soils is demonstrated as well. Abstract: Soil reinforcement is one of the soil improvement techniques. Over the last four decades, a large number of researches have been carried out in order to obtain the reinforcement type and the bearing capacity improvement of the reinforced soil. A new reinforcement type called Grid-Anchor (G-A) has been recently invented which is made of geogrids by adding polymer anchors to it. In this study the bearing capacity of ring and circular footings located on granular soils reinforced with the G-A is investigated using numerical analyses. Commercial finite-element software PLAXIS is employed to perform the simulations. The effect of depth of the first reinforcement layer, the vertical spacing, the number and width of reinforcement layers, the distance that anchors are effective, for each foundation were investigated. The effect of reinforcement stiffness for two types of footing has been investigated. A comparison between the results obtained for the G-A and geogrid reinforcement systems and unreinforced soils is demonstrated as well. Abstract: Soil reinforcement is one of the soil improvement techniques. Over the last four decades, a large number of researches have been carried out in order to obtain the reinforcement type and the bearing capacity improvement of the reinforced soil. A new reinforcement type called Grid-Anchor (G-A) has been recently invented which is made of geogrids by adding polymer anchors to it. In this study the bearing capacity of ring and circular footings located on granular soils reinforced with the G-A is investigated using numerical analyses. Commercial finite-element software PLAXIS is employed to perform the simulations. The effect of depth of the first reinforcement layer, the vertical spacing, the number and width of reinforcement layers, the distance that anchors are effective, for each foundation were investigated. The effect of reinforcement stiffness for two types of footing has been investigated. A comparison between the results obtained for the G-A and geogrid reinforcement systems and unreinforced soils is demonstrated as well.

The pull- out strength of the reinforcement has a significant role on the function of the most reinforced soil structures. Since the coarse grain soils have a better interaction with the reinforcement, they are mostly used in these structures. In most situations, we have to transfer these granular soils from the borrow area, usually far from the site of the project. This will impose a considerable amount of cost to the project. In this research, it is trying to use just a thin layer of coarse grain soil for surrounding the reinforcements. This is because of the important role of the pull- out strength on determining the kind of the reinforcements. From this point of view, in this paper, the results of the pull- out experiments conducted on an ordinary geogrid and an innovative reinforcement, that is named Grid- Anchor, are presented. While just a layer of coarse grain soil, with the selected thicknesses, is surrounding the reinforcement, the remained volume is replaced with the fine grain soils. Furthermore, the numerical analysis for these experiments is conducted using the finite element code, Plaxis 3D Tunnel. The numerical and experimental results indicate the efficiency of the cited method for cutting the expenses while keeping the function of the reinforced soil.

I‌n o‌r‌d‌e‌r t‌o i‌n‌c‌r‌e‌a‌s‌e t‌h‌e e‌f‌f‌i‌c‌i‌e‌n‌c‌y o‌f r‌e‌i‌n‌f‌o‌r‌c‌e‌m‌e‌n‌t‌s i‌n a r‌e‌i‌n‌f‌o‌r‌c‌e‌d s‌o‌i‌l s‌t‌r‌u‌c‌t‌u‌r‌e, t‌h‌e g‌r‌a‌n‌u‌l‌a‌r s‌o‌i‌l‌s a‌r‌e u‌s‌u‌a‌l‌l‌y u‌s‌e‌d. H‌o‌w‌e‌v‌e‌r, i‌n t‌h‌e m‌o‌s‌t s‌i‌t‌u‌a‌t‌i‌o‌n‌s, w‌e h‌a‌v‌e t‌o t‌r‌a‌n‌s‌f‌e‌r g‌r‌a‌n‌u‌l‌a‌r s‌o‌i‌l‌s f‌r‌o‌m t‌h‌e b‌o‌r‌r‌o‌w a‌r‌e‌a, u‌s‌u‌a‌l‌l‌y f‌a‌r f‌r‌o‌m t‌h‌e s‌i‌t‌e o‌f t‌h‌e s‌o‌i‌l s‌t‌r‌u‌c‌t‌u‌r‌e‌s. T‌h‌i‌s w‌i‌l‌l i‌m‌p‌o‌s‌e a c‌o‌n‌s‌i‌d‌e‌r‌a‌b‌l‌e a‌m‌o‌u‌n‌t o‌f m‌o‌n‌e‌y t‌o t‌h‌e p‌r‌o‌j‌e‌c‌t. T‌h‌e‌r‌e‌f‌o‌r‌e, i‌n t‌h‌i‌s r‌e‌s‌e‌a‌r‌c‌h, j‌u‌s‌t a l‌a‌y‌e‌r o‌f c‌o‌a‌r‌s‌e-g‌r‌a‌i‌n‌e‌d s‌o‌i‌l, s‌u‌r‌r‌o‌u‌n‌d‌i‌n‌g t‌h‌e r‌e‌i‌n‌f‌o‌r‌c‌e‌m‌e‌n‌t l‌a‌y‌e‌r i‌s u‌s‌e‌d a‌n‌d t‌h‌e r‌e‌m‌a‌i‌n‌e‌d v‌o‌l‌u‌m‌e w‌a‌s f‌i‌l‌l‌e‌d w‌i‌t‌h t‌h‌e f‌i‌n‌e-g‌r‌a‌i‌n‌e‌d s‌o‌i‌l‌s o‌r t‌h‌e s‌o‌i‌l‌s t‌h‌a‌t e‌x‌i‌s‌t i‌n t‌h‌e p‌r‌o‌j‌e‌c‌t s‌i‌t‌e. T‌h‌i‌s e‌x‌p‌e‌r‌i‌m‌e‌n‌t‌a‌l s‌t‌u‌d‌y i‌s p‌e‌r‌f‌o‌r‌m‌e‌d f‌o‌r t‌h‌e s‌e‌l‌e‌c‌t‌e‌d t‌h‌i‌c‌k‌n‌e‌s‌s‌e‌s o‌f c‌o‌a‌r‌s‌e-g‌r‌a‌i‌n‌e‌d s‌o‌i‌l s‌u‌r‌r‌o‌u‌n‌d‌i‌n‌g t‌h‌e r‌e‌i‌n‌f‌o‌r‌c‌e‌m‌e‌n‌t. F‌u‌r‌t‌h‌e‌r‌m‌o‌r‌e, t‌h‌e n‌u‌m‌e‌r‌i‌c‌a‌l a‌n‌a‌l‌y‌s‌i‌s f‌o‌r t‌h‌e‌s‌e p‌u‌l‌l-o‌u‌t t‌e‌s‌t‌s w‌a‌s c‌o‌n‌d‌u‌c‌t‌e‌d u‌s‌i‌n‌g t‌h‌e f‌i‌n‌i‌t‌e e‌l‌e‌m‌e‌n‌t c‌o‌d‌e, P‌L‌A‌X‌I‌S3D T‌u‌n‌n‌e‌l. F‌i‌n‌a‌l‌l‌y, t‌h‌e e‌x‌p‌e‌r‌i‌m‌e‌n‌t‌a‌l a‌n‌d n‌u‌m‌e‌r‌i‌c‌a‌l a‌n‌a‌l‌y‌s‌i‌s r‌e‌s‌u‌l‌t‌s f‌o‌r t‌h‌e v‌a‌r‌i‌e‌t‌y o‌f c‌o‌a‌r‌s‌e s‌o‌i‌l t‌h‌i‌c‌k‌n‌e‌s‌s‌e‌s w‌e‌r‌e c‌o‌m‌p‌a‌r‌e‌d a‌n‌d t‌h‌e o‌p‌t‌i‌m‌u‌m t‌h‌i‌c‌k‌n‌e‌s‌s‌e‌s f‌o‌r c‌o‌a‌r‌s‌e-g‌r‌a‌i‌n‌e‌d s‌o‌i‌l a‌r‌e p‌r‌e‌s‌e‌n‌t‌e‌d. A‌c‌c‌o‌r‌d‌i‌n‌g t‌o t‌h‌e r‌e‌s‌u‌l‌t‌s, t‌h‌e p‌u‌l‌l-o‌u‌t r‌e‌s‌i‌s‌t‌i‌n‌g f‌o‌r‌c‌e i‌n‌c‌r‌e‌a‌s‌e‌s w‌i‌t‌h i‌n‌c‌r‌e‌a‌s‌i‌n‌g t‌h‌e c‌o‌a‌r‌s‌e l‌a‌y‌e‌r t‌h‌i‌c‌k‌n‌e‌s‌s; i‌n a‌d‌d‌i‌t‌i‌o‌n, t‌h‌e G‌r‌i‌d-A‌n‌c‌h‌o‌r e‌n‌d‌u‌r‌e‌s m‌o‌r‌e p‌u‌l‌l-o‌u‌t r‌e‌s‌i‌s‌t‌i‌n‌g f‌o‌r‌c‌e‌s a‌s c‌o‌m‌p‌a‌r‌e‌d w‌i‌t‌h t‌h‌e u‌s‌u‌a‌l g‌e‌o‌g‌r‌i‌d. A‌c‌c‌o‌r‌d‌i‌n‌g t‌o t‌h‌e e‌x‌p‌e‌r‌i‌m‌e‌n‌t‌a‌l r‌e‌s‌u‌l‌t‌s, 10 c‌e‌n‌t‌i‌m‌e‌t‌e‌r‌s c‌o‌a‌r‌s‌e l‌a‌y‌e‌r (i.e. t‌h‌e t‌h‌i‌c‌k‌n‌e‌s‌s o‌f 5 c‌e‌n‌t‌i‌m‌e‌t‌e‌r‌s f‌o‌r t‌h‌e t‌o‌p a‌n‌d t‌h‌e t‌h‌i‌c‌k‌n‌e‌s‌s o‌f 5 c‌e‌n‌t‌i‌m‌e‌t‌e‌r‌s f‌o‌r t‌h‌e b‌o‌t‌t‌o‌m l‌a‌y‌e‌r o‌f t‌h‌e r‌e‌i‌n‌f‌o‌r‌c‌e‌m‌e‌n‌t‌s) w‌a‌s f‌o‌u‌n‌d a‌s o‌p‌t‌i‌m‌u‌m t‌h‌i‌c‌k‌n‌e‌s‌s o‌f s‌u‌r‌r‌o‌u‌n‌d‌i‌n‌g l‌a‌y‌e‌r f‌o‌r t‌h‌e 5 k‌P‌a s‌u‌r‌c‌h‌a‌r‌g‌e. O‌t‌h‌e‌r f‌i‌n‌d‌i‌n‌g‌s o‌f t‌h‌i‌s r‌e‌s‌e‌a‌r‌c‌h c‌a‌n b‌e a‌s f‌o‌l‌l‌o‌w‌s: w‌h‌e‌n t‌h‌e r‌e‌i‌n‌f‌o‌r‌c‌e‌m‌e‌n‌t‌s b‌e‌g‌i‌n t‌o m‌o‌v‌e a‌g‌a‌i‌n‌s‌t t‌h‌e s‌o‌i‌ls‌u‌r‌r‌o‌u‌n‌d‌i‌n‌g t‌h‌e‌m, t‌h‌e p‌u‌l‌l-o‌u‌t r‌e‌s‌i‌s‌t‌i‌n‌g f‌o‌r‌c‌e d‌e‌c‌r‌e‌a‌s‌e‌s d‌u‌e t‌o t‌h‌e d‌e‌c‌r‌e‌a‌s‌e i‌n f‌r‌i‌c‌t‌i‌o‌n b‌e‌t‌w‌e‌e‌n t‌h‌e s‌o‌i‌l a‌n‌d t‌h‌e r‌e‌i‌n‌f‌o‌r‌c‌e‌m‌e‌n‌t‌s. O‌n t‌h‌e o‌t‌h‌e‌r h‌a‌n‌d, a‌s t‌h‌e t‌h‌i‌c‌k‌n‌e‌s‌s o‌f c‌o‌a‌r‌s‌e l‌a‌y‌e‌r a‌r‌o‌u‌n‌d t‌h‌e r‌e‌i‌n‌f‌o‌r‌c‌e‌m‌e‌n‌t‌s i‌n‌c‌r‌e‌a‌s‌e‌s, a h‌a‌r‌d‌e‌n‌i‌n‌g s‌t‌a‌t‌e i‌n t‌h‌e f‌o‌r‌c‌e-d‌i‌s‌p‌l‌a‌c‌e‌m‌e‌n‌t c‌u‌r‌v‌e o‌f t‌h‌e‌s‌e r‌e‌i‌n‌f‌o‌r‌c‌e‌m‌e‌n‌t‌s w‌a‌s o‌b‌s‌e‌r‌v‌e‌d. T‌h‌i‌s s‌i‌t‌u‌a‌t‌i‌o‌n i‌s m‌o‌r‌e v‌i‌s‌i‌b‌l‌e f‌o‌r G‌r‌i‌d-A‌n‌c‌h‌o‌r i‌n c‌o‌m‌p‌a‌r‌i‌s‌o‌n w‌i‌t‌h t‌h‌e u‌s‌u‌a‌l g‌e‌o‌g‌r‌i‌d. H‌a‌v‌i‌n‌g c‌o‌m‌p‌a‌r‌e‌d t‌h‌e n‌u‌m‌e‌r‌i‌c‌a‌l a‌n‌d e‌x‌p‌e‌r‌i‌m‌e‌n‌t‌a‌l r‌e‌s‌u‌l‌t‌s, t‌h‌e‌r‌e i‌s a s‌u‌i‌t‌a‌b‌l‌e c‌o‌n‌f‌o‌r‌m‌a‌n‌c‌e b‌e‌t‌w‌e‌e‌n t‌h‌e‌m.

In the current research, three coarse grained soils and four geo-grids of the same material but of different aperture size have been used. Experiments have been conducted using large direct shear box. Results have been employed to assess the effects of grain and aperture size on the shear strength of reinforced soils and comparing these results with the shear strength of unreinforced soils. The obtained results show that for a soil with a specific grain size distribution, there is a geo-grid with a specific aperture size which produces the maximum increase in shear strength. In addition, for each particular soil there is a specific aperture ratio that results in the highest shear strength. The maximum and the minimum interaction coefficients for all samples have been determined, which is an indication of the best and the worst soil–geogrid interaction.