Your search keyword '"RAHMANI, IRAJ"' showing total 14 results

1. Effect of Smear Zone Characteristics on PVD-Improved Soft Soils Using Field Data and Numerical Simulations

Author

Maleki, Mohammad, Alielahi, Hamid, and Rahmani, Iraj

Published

2022

2. A Laboratory Study on the Flexural and Shear Behavior of RC Beams Retrofitted with Steel Fiber-Reinforced Self-compacting Concrete Jacket

Author

Rahmani, Iraj, Maleki, Ahmad, and Lotfollahi-Yaghin, Mohammad Ali

Published

2021

3. Model-Selection Tests for Complex Survey Samples

Author

Rahmani, Iraj, primary and Wooldridge, Jeffrey M., additional

Published

2019

4. Error distribution and correction of the predicted wave characteristics over the Persian Gulf

Author

Moeini, Mohammad Hadi, Etemad-Shahidi, Amir, Chegini, Vahid, Rahmani, Iraj, and Moghaddam, Mona

Published

2014

5. Response of a group of piles to liquefaction-induced lateral spreading by large scale shake table testing

Author

Haeri, S. Mohsen, Kavand, Ali, Rahmani, Iraj, and Torabi, Hooman

Published

2012

6. Wave data assimilation using a hybrid approach in the Persian Gulf

Author

Moeini, Mohammad Hadi, Etemad-Shahidi, Amir, Chegini, Vahid, and Rahmani, Iraj

Published

2012

7. Considerations on seismic microzonation in areas with two-dimensional hills

Author

Kamalian, Mohsen, Sohrabi-Bidar, Abdollah, Razmkhah, Arash, Taghavi, Amirata, and Rahmani, Iraj

Published

2008

8. A Laboratory Study on the Flexural and Shear Behavior of RC Beams Retrofitted with Steel Fiber-Reinforced Self-compacting Concrete Jacket

Author

Rahmani, Iraj, primary, Maleki, Ahmad, additional, and Lotfollahi-Yaghin, Mohammad Ali, additional

Published

2020

9. Determination of Multilayer Soil Strength Parameters Using Genetic Algorithm

Author

Hashemi, Seyyed Mohammad, primary and Rahmani, Iraj, additional

Published

2018

10. Numerical Comparison of the Performance of Genetic Algorithm and Particle Swarm Optimization in Excavations

Author

Hashemi, Seyyed Mohammad, primary and Rahmani, Iraj, additional

Published

2018

11. Uniform openness of multiplication in Orlicz spaces

Author

Akbarbaglu, Ibrahim, primary, Maghsoudi, Saeid, additional, and Rahmani, Iraj, additional

Published

2016

12. Advances in constitutive modelling of jointed roxk hydro mechanical interactions at laboratory scale

Author

Lopez, Philippe, Thoraval, Alain, Buzzi, Olivier, Rahmani, Iraj, Boulon, Marc, Laboratoire Environnement Géomécanique et Ouvrages (LAEGO), Institut National Polytechnique de Lorraine (INPL), Institut National de l'Environnement Industriel et des Risques (INERIS), Laboratoire sols, solides, structures - risques [Grenoble] (3SR), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Université Joseph Fourier - Grenoble 1 (UJF)-Institut National Polytechnique de Grenoble (INPG)-Centre National de la Recherche Scientifique (CNRS), Civs, Gestionnaire, Service irevues, irevues, Association Française de Mécanique, University of Newcastle, Newcastle University [Newcastle], and Transportation Reasearch Institute

Subjects

[SDE] Environmental Sciences, HYDROMECHANICS, Espace des vides, Interactions, [SDE]Environmental Sciences, [SDU.STU] Sciences of the Universe [physics]/Earth Sciences, MORPHOLOGY, [SDU.STU]Sciences of the Universe [physics]/Earth Sciences, [PHYS.MECA]Physics [physics]/Mechanics [physics], [PHYS.MECA] Physics [physics]/Mechanics [physics], Hydromécanique, INTERACTION

Abstract

This study is a part of a wide multi-scale research based on in situ experiments and laboratory tests. The latest, radial water injections in the centre of the lower joint wall are done at constant normal stress ranging from 0 to 110 MPa and at pressures from 0 to 4 MPa. Four hydromechanical tests have been performed in the L3S laboratory on fractured limestone samples (two diaclase and two bedding plane). The measurement analysis shows a relation between the contact surface variations and the flow values inside the fracture. The hydromechanical modelling performed using 3DEC code can be improved compared with the previous analysis due to the modification of the relation between the joint hydraulic opening and the joint mechanical closure. The gap between simulations and measurements can be related to fracture asperity degradation and turbulent flow that have not been taken into account in the modelling., Cette étude s'inscrit dans une recherche multi échelles basée sur des expérimentations in situ et des essais de laboratoire. Les essais, injections radiales d'eau au centre de l'éponte inférieure, sont fait à contrainte normale constante de 0 à 110 MPa et pour des pressions de 0 à 4 MPa. Quatre essais hydromécaniques ont été réalisés au laboratoire L3S sur des échantillons de calcaire fracturé (deux diaclases et deux joints de stratification). L'analyse des mesures montre une corrélation entre les variations de la surface de contact et le débit hydraulique dans la fracture. La modélisation hydromécanique réalisée à l'aide du code 3DEC peut être améliorée à partir de l'analyse précédente à travers la modification de la relation entre l'ouverture hydraulique et la fermeture mécanique du joint. L'écart entre les valeurs mesurées et calculées est lié en particulier à la dégradation des aspérités de la fracture sous forte contrainte et à la turbulence des écoulements non prises en compte dans la modélisation.

Published

2007

13. Comportement Hydromécanique des Joints Rocheux : Expérimentation et Modélisation Constitutive

Author

Rahmani, Iraj, Laboratoire sols, solides, structures - risques [Grenoble] (3SR), Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP )-Université Joseph Fourier - Grenoble 1 (UJF)-Institut National Polytechnique de Grenoble (INPG)-Centre National de la Recherche Scientifique (CNRS), Grenoble 1 UJF - Université Joseph Fourier, and Marc Boulon

Subjects

Rock joints, [SPI]Engineering Sciences [physics], Joint Rocheux, Constitutive modeling, Hydromechanical behavior, Modélisation Constitutif, Experimentation, Comportement Hydromécanique

Abstract

Many applications in civil engineering involving fractured rock masses require precise feasibility studies. These rock masses can exhibit fracturing of various scales. They can contain on the one hand microscopic fractures induced by the disturbance of the stress field due to the construction work, and on the other hand natural fractures of several meters or more. Our aim is to provide additional new information on the hydromechanical behavior of the natural rock joints and on the constitutive modeling of their hydromechanical behavior. The experimental study consisted of a series of hydromechanical simple compression tests with the BCR-3D machine of laboratory 3S in Grenoble. We have presented an original constitutive hydromechanical model, which can be an effective means to model the hydromechanical behavior of the rock joints in compression and shear loading, at the meso-scale, without taking into account the scale effect. The direct Shear Box for Rocks with 3 Dimensions, called BCR3D, was used for the realization of our mechanical and hydromechanical tests on interfaces between geomaterials. This direct shear box has a hydraulic injection system that allows the hydraulic behavior of the rock joints to be studied and also the measurement of hydraulic anisotropy of the flows. Using the modified Divoux model and the approach of Darcy in incremental form, we developed an original hydromechanical nonlinear incremental model. We have presented the formulation of hydraulic transmissivity of the rock joints corresponding to two paths: first of all, evolution of hydraulic transmissivity as function of to the normal stress (and normal specific energy), and then changes of hydraulic transmissivity relating to the shearing path (and tangential specific energy). The performance of the model is discussed through the comparison between experimental results and constitutive modelling. The hydromechanical nonlinear incremental model (LHMIN) for the interface makes it possible to evaluate either the flow, or the hydraulic transmissivity as a function of the level of normal stress, normal energy, the level of shear stress and the energy of shearing imposed on the rock joint. We saw that it is possible to compare schematically by simulation, the flow between various geomaterials with the flow through the mass of these geomaterials acting as a plug to a gallery, we presented the evolution of the hydraulic transmissivity in the event of shearing for four different values of shrinking of the sealing concrete. In this close-to-reality case, the mechanical evolution for the interface of rock and concrete was calculated with the computer code PLAXIS.; De nombreuses applications en génie civil dans les massifs rocheux fracturés exigent des études de faisabilité précises. Ces massifs peuvent présenter des défauts de différentes tailles. Ils peuvent contenir d'une part des microfissures induites par la perturbation du champ de contraintes due à la construction d'un l'ouvrage, et d'autre part des fractures naturelles de plusieurs mètres voire plus. Notre travail est d'apporter des informations supplémentaires nouvelles sur le comportement hydromécanique des joints rocheux naturels et sur la modélisation constitutive de leur comportement hydromécanique. L'étude expérimentale a consisté en une série d'essais hydromécaniques de compression simple avec la machine BCR-3D du laboratoire 3S de Grenoble. Nous avons présenté un modèle hydromécanique constitutif original, qui peut être un moyen efficace pour modéliser le comportement hydromécanique des joints rocheux en compression et en cisaillement, en échelle méso sans prendre en compte l'effet d'échelle. La Boîte de Cisaillement direct pour Roches à 3 Dimensions, appelée BCR3D, a servi à la réalisation de nos essais mécaniques et hydromécaniques sur les interfaces entre géomatériaux. Cette boîte de cisaillement direct particulière a un système d'injection hydraulique afin d'étudier le comportement hydromécanique des joints rocheux et aussi de mesurer l'anisotropie hydraulique des écoulements. A l'aide du modèle de Divoux modifié et de l'approche de Darcy sous forme incrémentale, nous avons mis au point un modèle hydromécanique incrémental non linéaire original. Nous avons présenté la formulation de transmissivité hydraulique des joints rocheux selon deux chemins : tout d'abord, l'évolution de transmissivité en fonction de la contrainte normale (et de l'énergie spécifique normale), et ensuite les changements de transmissivité en fonction du chemin de cisaillement (et de l'énergie spécifique tangentielle). La performance du modèle est discutée à travers la comparaison entre des résultats expérimentaux et les modélisations constitutives. Le modèle hydromécanique incrémental non linéaire (LHMIN) pour l'interface, permet d'évaluer soit le débit, soit la transmissivité fonction du niveau de contrainte normale, de l'énergie normale, du niveau de contrainte de cisaillement et de l'énergie de cisaillement imposés au joint rocheux. Nous avons vu qu'il est possible de comparer schématiquement par simulation, le débit percolant entre divers géomatériaux au débit percolant à travers la masse de ces géomatériaux s'agissant d'un bouchon de galerie, nous avons présenté l'évolution de la transmissivité en cas de cisaillement pour quatre valeurs différentes de retrait du béton de scellement. Dans ce cas proche de la réalité, l'évolution mécanique à l'interface roche béton a été calculée grâce au code de calcul PLAXIS.

Published

2006

14. ADVANCES IN CONSTITUTIVE MODELLING OF JOINTED ROCK HYDROMECHANICAL INTERACTIONS AT LABORATORY SCALE.

Author

LOPEZ, PHILIPPE, THORAVAL, ALAIN, BUZZI, OLIVIER, RAHMANI, IRAJ, and BOULON, MARC

Subjects

COMPUTER simulation, FLUID mechanics, ROCKS, FRACTURE mechanics, LIMESTONE, TURBULENCE

Abstract

This study is a part of a wide multi-scale research based on in situ experiments and laboratory tests. The latest, radial water injections in the centre of the lower joint wall are done at constant normal stress ranging from 0 to 110 MPa and at pressures from 0 to 4 MPa. Four hydromechanical tests have been performed in the L3S laboratory on fractured limestone samples (two diaclase and two bedding plane). The measurement analysis shows a relation between the contact surface variations and the flow values inside the fracture. The hydromechanical modelling performed using 3DEC code can be improved compared with the previous analysis due to the modification of the relation between the joint hydraulic opening and the joint mechanical closure. The gap between simulations and measurements can be related to fracture asperity degradation and turbulent flow that have not been taken into account in the modelling. [ABSTRACT FROM AUTHOR]

Published

2008