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dc.contributor.advisorSivakumar Babu, G L
dc.contributor.authorBasha, B Munwar
dc.date.accessioned2010-10-14T09:14:03Z
dc.date.accessioned2018-07-31T05:42:37Z
dc.date.available2010-10-14T09:14:03Z
dc.date.available2018-07-31T05:42:37Z
dc.date.issued2010-10-14
dc.date.submitted2008
dc.identifier.urihttps://etd.iisc.ac.in/handle/2005/914
dc.description.abstractDesign of retaining structures depends upon the load which is transferred from backfill soil as well as external loads and also the resisting capacity of the structure. The traditional safety factor approach of the design of retaining structures does not address the variability of soils and loads. The properties of backfill soil are inherently variable and influence the design decisions considerably. A rational procedure for the design of retaining structures needs to explicitly consider variability, as they may cause significant changes in the performance and stability assessment. Reliability based design enables identification and separation of different variabilities in loading and resistance and recommends reliability indices to ensure the margin of safety based on probability theory. Detailed studies in this area are limited and the work presented in the dissertation on the Optimum design of retaining structures under static and seismic conditions: A reliability based approach is an attempt in this direction. This thesis contains ten chapters including Chapter 1 which provides a general introduction regarding the contents of the thesis and Chapter 2 presents a detailed review of literature regarding static and seismic design of retaining structures and highlights the importance of consideration of variability in the optimum design and leads to scope of the investigation. Targeted stability is formulated as optimization problem in the framework of target reliability based design optimization (TRBDO) and presented in Chapter 3. In Chapter 4, TRBDO approach for cantilever sheet pile walls and anchored cantilever sheet pile walls penetrating sandy and clayey soils is developed. Design penetration depth and section modulus for the various anchor pulls are obtained considering the failure criteria (rotational, sliding, and flexural failure modes) as well as variability in the back fill soil properties, soil-steel pile interface friction angle, depth of the water table, total depth of embedment, yield strength of steel, section modulus of sheet pile and anchor pull. The stability of reinforced concrete gravity, cantilever and L-shaped retaining walls in static conditions is examined in the context of reliability based design optimization and results are presented in Chapter 5 considering failure modes viz. overturning, sliding, eccentricity, bearing, shear and moment failures in the base slab and stem of wall. Optimum wall proportions are proposed for different coefficients of variation of friction angle of the backfill soil and cohesion of the foundation soil corresponding to different values of component as well as lower bounds of system reliability indices. Chapter 6 presents an approach to obtain seismic passive resistance behind gravity walls using composite curved rupture surface considering limit equilibrium method of analysis with the pseudo-dynamic approach. The study is extended to obtain the rotational and sliding displacements of gravity retaining walls under passive condition when subjected to sinusoidal nature of earthquake loading. Chapter 7 focuses on the reliability based design of gravity retaining wall when subjected to passive condition during earthquakes. Reliability analysis is performed for two modes of failure namely rotation of the wall about its heel and sliding of the wall on its base are considering variabilities associated with characteristics of earthquake ground motions, geometric proportions of wall, backfill soil and foundation soil properties. The studies reported in Chapter 8 and Chapter 9 present a method to evaluate reliability for external as well as internal stability of reinforced soil structures (RSS) using reliability based design optimization in the framework of pseudo static and pseudo dynamic methods respectively. The optimum length of reinforcement needed to maintain the stability against four modes of failure (sliding, overturning, eccentricity and bearing) by taking into account the variabilities associated with the properties of reinforced backfill, retained backfill, foundation soil, tensile strength and length of the geosynthetic reinforcement by targeting various component and system reliability indices is computed. Finally, Chapter 10 contains the important conclusions, along with scope for further work in the area. It is hoped that the methodology and conclusions presented in this study will be beneficial to the geotechnical engineering community in particular and society as a whole.en_US
dc.language.isoen_USen_US
dc.relation.ispartofseriesG22892en_US
dc.subjectSeismic Engineeringen_US
dc.subjectSeismic Loadingen_US
dc.subjectConventional Retaining Wallsen_US
dc.subjectCantilever Sheet Pile Wallsen_US
dc.subjectReinforced Soil Structures - Seismic Designen_US
dc.subjectTarget Reliability Based Design Optimizationen_US
dc.subjectGravity Walls - Seismic Designen_US
dc.subjectGravity Retaining Wallsen_US
dc.subjectEarth Retaining Structures - Designen_US
dc.subjectRetaining Structuresen_US
dc.subjectRetaining Wallsen_US
dc.subjectPseudo Dynamic Methoden_US
dc.subjectPseudo-dynamic Methoden_US
dc.subjectCantilever Retaining Wallsen_US
dc.subjectReinforced Soil Wallsen_US
dc.subjectSeismic Stabilityen_US
dc.subject.classificationStructural Engineeringen_US
dc.titleOptimum Design Of Retaining Structures Under Static And Seismic Loading : A Reliability Based Approachen_US
dc.typeThesisen_US
dc.degree.namePhDen_US
dc.degree.levelDoctoralen_US
dc.degree.disciplineFaculty of Engineeringen_US


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