Τοίχοι οπλισμένου εδάφους υπό σεισμική φόρτιση – αριθμητική ανάλυση συμπεριφοράς / Reinforced soil segmental retaining walls under seismic loading – parametric numerical analyses

Ράπτη, Δέσποινα

30 July 2007

Η ΒΥΠ διαθέτει αντίτυπο της διατριβής σε έντυπη μορφή στο βιβλιοστάσιο διδακτορικών διατριβών που βρίσκεται στο ισόγειο του κτιρίου της. / Εκτελώντας δυναμικές αναλύσεις με χρήση πεπερασμένων στοιχείων, αναλύεται η σεισμική απόκριση τεσσάρων τοίχων αντιστήριξης οπλισμένου εδάφους στην Ταϊβάν με στοιχεία πρόσοψης κυβόλιθους. Οι τοίχοι, των οποίων τα ύψη κυμαίνονται από 3.20 m έως 5.60 m και έχουν ως οπλισμούς στρώσεις γεωπλέγματος, υποβλήθηκαν στο σεισμό Chi-Chi (1999) και η συμπεριφορά τους κρίθηκε από επιτυχής έως ανεπιτυχής: δύο από αυτούς κατέρρευσαν, ένας υπέστη μόνο ελαφρές βλάβες, ενώ ο τέταρτος τοίχος παρέμεινε πρακτικά ανέπαφος. Η μη-γραμμική ανάλυση βασίσθηκε στα γνωστά γεωμετρικά και μηχανικά χαρακτηριστικά του κάθε τοίχου, του γεωπλέγματος, των γεωτεχνικών συνθηκών σε κάθε θέση, του είδους και των ιδιοτήτων του υλικού επίχωσης. Η συμπεριφορά του εδαφικού υλικού προσομοιώθηκε κάνοντας χρήση του κριτηρίου Mohr-Coulomb, ενώ ως διέγερση βάσης στις δυναμικές αναλύσεις πεπερασμένων στοιχείων χρησιμοποιήθηκαν τα καταγεγραμμένα επιταχυνσιογραφήματα κοντά στις θέσεις των τοίχων. Τα αποτελέσματα των αναλύσεων (και ειδικά η εκτιμώμενη παραμορφωμένη μορφή των τοίχων) επαλήθευσαν την παρατηρούμενη συμπεριφορά των τοίχων. Βασιζόμενοι στα αποτελέσματα, βρέθηκαν οι λόγοι της ανεπιτυχούς συμπεριφοράς των δύο τοίχων που κατέρρευσαν, ενώ εξηγήθηκε η διαφοροποίηση της συμπεριφοράς των δύο τοίχων που δεν υπέστησαν βλάβες. Επιπροσθέτως, πραγματοποιήθηκαν παραμετρικές αναλύσεις για να ευρεθεί η επίδραση σημαντικών παραμέτρων σχεδιασμού, όπως το βάθος θεμελίωσης του τοίχου, η απόσταση και το μήκος των οπλισμών, η συνεισφορά των ράβδων σύνδεσης στην ευστάθεια των στοιχείων πρόσοψης και η συνεισφορά της ανώτατης στρώσης οπλισμού στην ευστάθεια του τοίχου. Επίσης αναλύθηκε η ευστάθεια των τοίχων χρησιμοποιώντας ένα εμπορικά διαθέσιμο λογισμικό οριακής ισορροπίας, το οποίο βρέθηκε ικανό να προβλέψει την παρατηρούμενη επιτυχή και ανεπιτυχή συμπεριφορά των τεσσάρων τοίχων. / The seismic response of four reinforced soil segmental retaining walls in Taiwan, is analyzed using the dynamic finite element method. The walls – whose heights ranging from 3.20 m to 5.60 m and layers of geogrid reinforcement – were subjected to the Chi-Chi earthquake (1999) and their performance ranged from successful to unsuccessful: two of them were collapsed, one suffered only minor damage whereas the fourth wall remained practically intact. The non-linear analyses were based on the known geometrical and mechanical characteristics of each wall and of the geogrid reinforcement, the geotechnical conditions at each site and the type and properties of backfill material. The soil material behavior was modeled by using the Mohr-Coulomb failure criterion whereas recorded accelerograms in the vicinity of the sites of the walls were used as base excitation in the dynamic finite analyses. The results of the analyses (and especially the estimated deformed shape of the walls) showed a remarkable agreement with the observed performance of the walls. Based on these results the reasons for the unsuccessful performance of the two failed walls were identified whereas the differentiation of the behavior of the two undamaged walls was explained. Furthermore, parametric analyses were conducted to identify the effects of such important design parameters as the depth of the foundation of the wall, the spacing and length of reinforcement, the contribution of connecting pins to the stability of the facing elements as well as the contribution of the top layer of reinforcement to the stability of the wall. The stability of the walls were also analyzed by using a commercially available limit equilibrium software which was found to be able to predict the observed successful and unsuccessful performance of the four walls.

Σεισμική απόκριση

Σεισμός Chi-Chi (1999)

624.164

Seismic response

Chi-Chi earthquake (1999)

Seismic response analysis of linear and nonlinear secondary structures

Kasinos, Stavros

January 2018

Understanding the complex dynamics that underpin the response of structures in the occurrence of earthquakes is of paramount importance in ensuring community resilience. The operational continuity of structures is influenced by the performance of nonstructural components, also known as secondary structures. Inherent vulnerability characteristics, nonlinearities and uncertainties in their properties or in the excitation pose challenges that render their response determination as a non-straightforward task. This dissertation settles in the context of mathematical modelling and response quantification of seismically driven secondary systems. The case of bilinear hysteretic, rigid-plastic and free-standing rocking oscillators is first considered, as a representative class of secondary systems of distinct behaviour excited at a single point in the primary structure. The equations governing their full dynamic interaction with linear primary oscillators are derived with the purpose of assessing the appropriateness of simplified analysis methods where the secondary-primary feedback action is not accounted for. Analyses carried out in presence of pulse-type excitation have shown that the cascade approximation can be considered satisfactory for bilinear systems provided the secondary-primary mass ratio is adequately low and the system does not approach resonance. For the case of sliding and rocking systems, much lighter secondary systems need to be considered if the cascade analysis is to be adopted, with the validity of the approximation dictated by the selection of the input parameters. Based on the premise that decoupling is permitted, new analytical solutions are derived for the pulse driven nonlinear oscillators considered, conveniently expressing the seismic response as a function of the input parameters and the relative effects are quantified. An efficient numerical scheme for a general-type of excitation is also presented and is used in conjunction with an existing nonstationary stochastic far-field ground motion model to determine the seismic response spectra for the secondary oscillators at given site and earthquake characteristics. Prompted by the presence of uncertainty in the primary structure, and in line with the classical modal analysis, a novel approach for directly characterising uncertainty in the modal shapes, frequencies and damping ratios of the primary structure is proposed. A procedure is then presented for the identification of the model parameters and demonstrated with an application to linear steel frames with uncertain semi-rigid connections. It is shown that the proposed approach reduces the number of the uncertain input parameters and the size of the dynamic problem, and is thus particularly appealing for the stochastic assessment of existing structural systems, where partial modal information is available e.g. through operational modal analysis testing. Through a numerical example, the relative effect of stochasticity in a bi-directional seismic input is found to have a more prominent role on the nonlinear response of secondary oscillators when compared to the uncertainty in the primary structure. Further extending the analyses to the case of multi-attached linear secondary systems driven by deterministic seismic excitation, a convenient variant of the component-mode synthesis method is presented, whereby the primary-secondary dynamic interaction is accounted for through the modes of vibration of the two components. The problem of selecting the vibrational modes to be retained in analysis is then addressed for the case of secondary structures, which may possess numerous low frequency modes with negligible mass, and a modal correction method is adopted in view of the application for seismic analysis. The influence of various approaches to build the viscous damping matrix of the primary-secondary assembly is also investigated, and a novel technique based on modal damping superposition is proposed. Numerical applications are demonstrated through a piping secondary system multi-connected on a primary frame exhibiting various irregularities in plan and elevation, as well as a multi-connected flexible secondary system. Overall, this PhD thesis delivers new insights into the determination and understanding of the response of seismically driven secondary structures. The research is deemed to be of academic and professional engineering interest spanning several areas including seismic engineering, extreme events, structural health monitoring, risk mitigation and reliability analysis.

Seismic Performance Analysis of Fill Dams Using Velocity Based Space-Time Finite Element Method / 速度型Space-Time有限要素法によるフィルダム耐震性能照査

Sakai, Kotaro

23 March 2021

京都大学 / 新制・課程博士 / 博士(農学) / 甲第23239号 / 農博第2446号 / 新制||農||1083(附属図書館) / 学位論文||R3||N5329(農学部図書室) / 京都大学大学院農学研究科地域環境科学専攻 / (主査)教授 村上 章, 教授 藤原 正幸, 教授 渦岡 良介 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DGAM

fill dam

seismic performance verification

seismic response analysis

elasto-plastic constitutive model

nonlinear analysis

610

Seismic Response Of Geosynthetic Reinforced Soil Wall Models Using Shaking Table Tests

Adapa, Murali Krishna

02 1900

Use of soil retaining walls for roads, embankments and bridges is increasing with time and reinforced soil retaining walls are found to be very efficient even under critical conditions compared to unreinforced walls. They offer competitive solutions to earth retaining problems associated with less space and more loads posed by tremendous growth in infrastructure, in addition to the advantages in ease and cost of construction compared to conventional retaining wall systems. The study of seismic performance of reinforced soil retaining walls is receiving much attention in the light of lessons learned from past failures of conventional retaining walls. Laboratory model studies on these walls under controlled seismic loading conditions help to understand better how these walls actually behave during earthquakes. The objective of the present study is to investigate the seismic response of geosynthetic reinforced soil wall models through shaking table tests. To achieve this, wrap faced and rigid faced reinforced soil retaining walls of size 750 × 500 mm in plan and 600 mm height are built in rigid and flexible containers and tested under controlled dynamic conditions using a uni-axial shaking table. The effects of frequency and acceleration of the base motion, surcharge pressure on the crest, number of reinforcing layers, container boundary, wall structure and reinforcement layout on the seismic performance of the retaining walls are studied through systematic series of shaking table tests. Results are analyzed to understand the effect of each of the considered parameters on the face displacements, acceleration amplifications and soil pressures on facing at different elevations of the walls. A numerical model is developed to simulate the shaking table tests on wrap faced reinforced soil walls using a computer program FLAC (Fast Lagrangian Analysis of Continua). The experimental data are used to validate the numerical model and parametric studies are carried out on 6 m height full-scale wall using this model. Thus, the study deals with the shaking table tests, dynamic response of reinforced walls and their numerical simulation. The thesis presents detailed description of various features and various parts of the shaking table facility along with the instrumentation and model containers. Methodology adopted for the construction of reinforced soil model walls and testing procedures are briefly described. Scaling and stability issues related to the model wall size and reinforcement strength are also discussed. From the study, it is observed that the displacements are decreasing with the increase in relative density of backfill, increase in surcharge pressure and increase in number of reinforcing layers; In general, accelerations are amplified to the most at the top of the wall; Behaviour of model walls is sensitive to model container boundary. The frequency content is very important parameter affecting the model response. Further, it is noticed that the face displacements are significantly affected by all of the above parameters, while the accelerations are less sensitive to reinforcement parameters. Even very low strength geonet and geotextile are able to reduce the displacements by 75% compared to unreinforced wall. The strain levels in the reinforcing elements are observed to be very low, in the order of ±150 micro strains. A random dynamic event is also used in one of the model tests and the resulted accelerations and displacements are presented. Numerical parametric studies provided important insight into the behaviour of wrap faced walls under various seismic loading conditions and variation in physical parameters.

Earthquake Engineering

Reinforced Soil Wall Models

Shaking Table Tests

Reinforced Soil Retaining Walls

Seismic Loading

Wrap Faced Reinforced Soil Walls

Rigid Faced Reinforced Soil Walls

Reinforced Retaining Walls

Geotechnical Engineering

Seismic Response

Structural Engineering

免震鋼製橋脚のハイブリッド地震応答実験手法の妥当性に関する検討

中島, 大輔, Nakajima, Daisuke, 宇佐美, 勉, Usami, Tsutomu, 葛西, 昭, Kasai, Akira, 金田一, 智章, Kindaichi, Tomoaki

03 1900

No description available.

seismic isolation bearing

免震支承

pseudodynamic test

ハイブリッド地震応答実験

elasto-plastic seismic response analysis

弾塑性地震応答解析

steel bridge pier

鋼製橋脚

Des données accélérométriques au comportement dynamique des bâtiments existants / From accelerometric records to the dynamic behavior of existing buildings

Fernández Lorenzo, Guillermo Wenceslao

17 October 2016

L'objectif de cette thèse est de simuler l'histoire temporelle de la réponse d'un bâtiment de grande hauteur sous sollicitation sismique et de proposer des méthodologies simplifiées qui reproduisent correctement une telle réponse. Initialement, un modèle tridimensionnel par éléments finis est produit afin de valider sa fiabilité pour simuler le comportement réel du bâtiment pendant les mouvements du sol, enregistrés à l'aide d'accéléromètres. Il est proposé d'améliorer la précision du modèle numérique en imposant de multiples excitations, compte-tenu des effets de basculement et de la variabilité spatiale sur la sollicitation d'entrée. L'utilisation de fonctions de Green empiriques est proposée pour simuler la réponse sismique directement à partir d'enregistrements d'événements passés, sans avoir besoin de dessins de construction ni d'étalonnage des paramètres mécaniques. Une méthode de sommation stochastique, déjà utilisée pour prédire les mouvements du sol, est adoptée pour générer des signaux synthétiques à des hauteurs différentes du bâtiment, par extension du chemin de propagation des ondes du sol à la structure. Une représentation simplifiée du bâtiment comme une poutre homogène Timoshenko est proposée pour simuler la réponse sismique directement à partir des enregistrements des vibrations ambiantes. Des paramètres mécaniques équivalents sont identifiés à l'aide de l'interférométrie par déconvolution en termes de dispersion des ondes, de fréquences naturelles et de rapport de vitesse des ondes de cisaillement et de compression dans le milieu / The aim of this thesis is to simulate the time history response of a high rise building under seismic excitation and provide simplified methodologies that properly reproduce such response. Firstly, a detailed three-dimensional finite element model is produced to validate its reliability to simulate the real behavior of the building during ground motions, recorded using accelerometers. It is proposed to improve the accuracy of the numerical model by imposing multiple excitations, considering rocking effect and spatial variability on the input motion. The use of empirical Green's functions is proposed to simulate the seismic response directly from past event records, without the need of construction drawings and mechanical parameters calibration. A stochastic summation scheme, already used to predict ground motions, is adopted to generate synthetic signals at different heights of the building, extending the wave propagation path from the ground to the structure. A simplified representation of the building as a homogeneous Timoshenko beam is proposed to simulate the seismic response directly from ambient vibration records. Equivalent mechanical parameters are identified using deconvolution interferometry in terms of wave dispersion, natural frequencies and shear to compressional wave

Simulation de la réponse sismique

Bâtiment de grande hauteur

Analyse modale opérationnelle

Modélisation par éléments finis

Fonction de Green empirique

Interférométrie par déconvolution

Seismic response simulation

High rise building

Operational modal analysis

Finite element modeling

Empirical Green's function

Deconvolution interferometry

Análisis de la bidireccionalidad sísmica en la respuesta de estructuras de concreto armado con irregularidad de esquina entrante y de piso blando en la ciudad de Lima / Analysis of seismic bidirectionality on response of reinforced concrete structures with irregularities of l-shaped plan and soft story

Sobrado Ortega, Victor Hugo, Yaranga Huamaní, Rogelio

09 December 2020

La Norma E.030 y gran parte de los códigos de diseño sismorresistente consideran el análisis unidireccional para cada uno de los ejes principales de manera independiente. A comparación de ello, en realidad los eventos sísmicos tienen un comportamiento bastante aleatorio. Además, imponen solicitaciones bidireccionales en diferentes orientaciones a las edificaciones. Se realizó el estudio de la respuesta en edificaciones sujetas a solicitaciones de carga sísmica con irregularidades de esquina entrante y de piso blando. Para ello, se ha realizado el análisis tiempo historia lineal (ATHL) de éstas imponiendo solicitaciones sísmicas en dos direcciones ortogonales simultáneas. Así, se obtiene la respuesta estructural con variaciones de ángulos de incidencia de 10° y se compara con la respuesta derivada del análisis unidireccional. Los resultados obtenidos muestran que el análisis tradicional subestima las respuestas de las estructuras. Se obtuvieron variaciones de hasta 50% en el modelo de esquina entrante y hasta 72% en el modelo de piso blando. En las edificaciones con irregularidad de piso blando extremo existen variaciones de hasta el 90%. Estos resultados confirman la necesidad de considerar la bidireccionalidad sísmica en el análisis y diseño sismorresistente. / Standard E.030 and most of the seismic-resistant design codes consider the unidirectional analysis for each of the main axes independently. By comparison, seismic events actually behave quite randomly. In addition, they impose bidirectional solicitations in different orientations to the buildings. The study of the response in structures subjects to earthquake loads with irregularity of l-shaped plan and soft story is carried out. For this, the linear time-story analysis (LTHA) of these has been carried out imposing seismic solicitations in two perpendicular directions at the same time. Thus, the structural response with incidence angle variations of 10° is obtained and compared with the response derived from the unidirectional analysis. Variations of up to 50 were obtained in the l-shaped plan model and up to 72% in the soft story model. In structures with extreme soft story variations of up to 90%. These results confirm the need to consider seismic bidirectionality in earthquake analysis and design. / Tesis

Bidireccionalidad

Ángulo de incidencia

Sismo

Esquina entrante

Piso blando

Respuesta

Bidirectionality

Angle of incidence

Earthquake

Ground motions

l-shaped

Soft story

Seismic response

Análisis comparativo de la respuesta sísmica de una clínica con aislamiento sísmico en Lima bajo las normas NCh 2745 y ASCE SEI 7 con la norma peruana E031

Rosales Villanueva, Aldair Santos, Sandivar Ramirez, Jessica Jhovanna

06 December 2021

El presente estudio de investigación evalúa la respuesta sísmica de una clínica con aislamiento símico en Lima bajo la Norma Peruana de Aislamiento Sísmico E.031. Esta será comparada con la norma la Norma Chilena de Diseño Sísmico de Edificios NCh2745 y la Norma Americana ASCE/SEI 7, dichas normas internacionales han sido diseñadas para soportar eventos sísmicos severos, presentando parámetros rigurosos, con los cuales se podrá destacar las fortalezas y debilidades frente a la nueva Norma Peruana. En los capítulos siguientes se da entendimiento a la información que se debe poseer para analizar las tres normas, conceptos básicos de sismología y dinámica estructural, dentro de cada norma se verán los alcances, factores y parámetros que intervienen en la determinación del espectro de diseño, así como el análisis sísmico dinámico que las normas proponen y el modelamiento de la estructura de la clínica en el software ETABS. Luego se comparan los resultados de la respuesta sísmica, desplazamientos laterales, derivas y fuerzas cortantes, en las que se verán las exigencias que cada norma, llegando a saber si nuestra Norma Peruana en su modificación y mejora de su contenido se proyecta a ser una de las mejores normas de diseño sismorresistente, obteniendo así una perspectiva de nuestra Norma Peruana frente a una norma internacional ya consolidada y avalada por los años frente a sismos severos. / This research study evaluates the seismic response of a clinic with simian isolation in Lima under the draft Peruvian Seismic Isolation Standard E.031. This will be compared with the North American standard ASCE SEI 7-16 and the Chilean Seismic Design Standard for Buildings 2745, these international standards have been designed to withstand severe seismic events, presenting rigorous parameters, with which we can highlight the strengths and weaknesses against the new Peruvian Standard. In the following chapters, understanding is given to the information that must be possessed to analyze the three norms, basic concepts of seismology and structural dynamics, within each norm the scope, factors and parameters that are involved in the determination of the design spectrum will be seen, as well as the dynamic seismic analysis that the standards propose and the modeling of the clinical structure in the ETABS software. Then the results of the seismic response, lateral displacements, drifts and shear forces are compared, in which the requirements of each norm will be seen, getting to know if our Peruvian Standard in its modification and improvement of its content is projected to be one of the best seismic resistant design standards, thus obtaining a perspective of our Peruvian Standard against an international standard already consolidated and endorsed by the years against severe earthquakes. / Tesis

Respuesta sísmica

Aislamiento sísmico

Diseño sismorresistente

Análisis sísmico dinámico

Seismic response

Seismic isolation

Earthquake resistant design

Dynamic seismic analysis

鋼製橋脚ー地盤系の地震応答解析における減衰マトリクスに関する一考察

葛西, 昭, Kasai, Akira, 宇佐美, 勉, Usami, Tsutomu, 能登, 晋也, Noto, Shinya

03 1900

No description available.

steel bridge pier

鋼製橋脚

seismic response analysis

弾塑性地震応答解析

damping matrix

地盤と構造物の動的相互作用

減衰マトリクス

mult-span continuous bridges

多径間連続橋

soil-structure interaction

鋼製橋脚ー基礎ー地盤連成系の大地震時挙動

Usami, Tsutomu, 葛西, 昭, Kasai, Akira, 河村, 康文, Kawamura, Yasufumi, 宇佐美, 勉

03 1900

No description available.

steel bridge pier

鋼製橋脚

soil-structure interaction

構造物と地盤の動的相互作用

equivalent linearization method

等価線形化手法

elastoplastic seismic response analysis

弾塑性地震応答解析