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11	Etude expérimentale et numérique de la résistance à l'effondrement progressif de sous-assemblages poteaux-poutres en béton armé / Experimental and numerical investigation of the progressive collapse resistance of reinforced concrete beam-column sub-assemblages Zhao, Guoqiang 03 July 2019 (has links) Au cours de leur durée de vie, les bâtiments importants sont susceptibles d’être soumis à des charges accidentelles, telles que des explosions ou des impacts. Evaluer leur stabilité vis-à-vis de charges traditionnelles statiques et sismiques ne suffit pas. Leurs performances structurelles liées à des scénarios d’effondrement progressif doivent également être examinées.L’étude de l’effondrement progressif est un problème dynamique. Malheureusement, les expériences sur le comportement des structures de génie civil dans des conditions dynamiques sont rares car difficiles à réaliser. Dans cette étude, des sous-assemblages poteaux-poutres en béton armé ont été testés sous chargement dynamique. Le chargement a consisté à placer une masse importante jouant le rôle de « charge morte » sur la colonne centrale d’un sous-assemblage simulant la liaison de 3 poteaux avec 2 poutres. Une pièce fusible jouant le rôle de support sous la colonne centrale est brutalement déverrouillée pour simuler la perte de portance soudaine de cette colonne. Le comportement dynamique et les dommages locaux causés à la structure ont été mesurés et étudiés. Le bâti de chargement et les dispositifs de support ont été conçus spécialement pour cet essai. La charge morte supérieure peut être modifiée et appliquées à différents spécimens. Les supports des colonnes latérales ont une rigidité horizontale contrôlée et sont conçus pour limiter la rotation de ces mêmes colonnes. Ainsi, les conditions aux limites des essais réalisés sont supposées être représentatives de situations réalistes. Au cours des essais, un laser a été installé sous la colonne centrale pour mesurer la vitesse de chute. Une caméra numérique rapide a été utilisée pour visualiser l'ensemble du processus de ruine du sous-assemblage. Les images obtenues de la caméra ont été traitées par une technique de DIC (Digital Image Correlation) afin d’obtenir le champs de déplacement et les déformations correspondantes. Grâce à ces mesures dynamiques, des données importantes ont été produites et enregistrées, notamment la période de vibration, la fréquence, la vitesse et le déplacement des différents échantillons testés. Sur la base de ces données expérimentales, l’effet de la section et de la portée des poutres sur la réponse dynamique et sur le mode d’endommagement des sous-assemblages a été discuté. Cette étude montre que les résultats expérimentaux obtenus, en termes de mécanismes structurels, de schéma de fissuration, de mode d'endommagement, peuvent être utilisés pour analyser le comportement de sous-assemblages de structures réelles.De plus, une modélisation numérique des essais a été réalisée pour simuler le processus de ruine de la structure. Une technique appelée «connecteur» a été proposée dans le modèle aux éléments finis du sous-assemblage poteaux-poutres. Cette technique consiste à ajouter une série de ressorts pour étudier le rôle de l’interaction entre les armatures en acier et le béton. Un modèle d'endommagement anisotrope, appelé modèle DFH-KST, a été utilisé pour caractériser l'évolution de la fissuration et l’endommagement du béton.La polyvalence de la méthodologie adoptée permet d’évaluer l’influence du comportement non-linéaire du matériau et celle de la géométrie de la structure testée. Les études numériques de calibration et de validation montrent que le modèle proposé peut reproduire le comportement et la résistance de la structure avec succès. / Important buildings may be subjected to accidental loads, such as explosions or impacts, during their service life. It is, therefore, necessary not only to evaluate their safety under traditional loads and seismic action. The structural performances related to progressive collapse scenarios need to be investigated.The study of progressive collapse involves a dynamic problem, but unfortunately dynamic experiments on the behavior of the civil engineering structures under dynamic conditions are rare. In this research, beam-column sub-assemblage specimens were tested under dynamic load. The loading program consists in placing a large mass, as a dead load, on the top of the middle column of a beam-column sub-assemblage. The support under the middle column is suddenly removed for simulating the sudden loss of a column and the damage that will result in the structure. The loading system and supporting devices were designed specially for this test. The upper dead load can be changed by increasing or decreasing the applied masse to different specimens. The supports for the side column have a controlled rigidity in the horizontal direction and are designed to restrain rotation of the side-column. Thus, the boundary conditions are supposed to be similar to real situations. During the test, a laser was installed under the middle pillar to collect the falling velocity and a high-speed camera was used to visualize the whole process of the component failure process. The images obtained from the camera were processed by Digital Image Correlation (DIC) technology to get the corresponding displacements and strain fields. By these means, all the information of the structure under dynamic loading was captured and recorded, such as the period of vibration, frequency, velocity and displacement. Based on these experimental data, the effect of section and span of the specimen on dynamic response and damage mode was discussed. Time history of resistance force curves was produced. Compared with previous published quasi-static experiments in terms of structural mechanisms, crack patterns, damage mode, it shows the experimental results from beam-column assemblage with the designed support device can be used to analyze the behavior of the local structure in the entire frame.In addition, numerical simulations were developed for simulating the failing process of the structure. A technique named “connector” was proposed into beam-column finite element model by adding a series of springs to investigate the interaction between steel rebars and concrete. A concrete damage model, named DFH-KST model, was used to characterize the development of concrete crack and damage. The versatility of the adopted methodology allows assessing the influence of the material nonlinear behavior and the geometry of the tested structure. Calibration and validation studies show that the proposed model can successfully represent the resistance of structure and behavior. Furthermore, the transverse component effect on the resistance to progressive collapse was discussed. Charge dynamique Effondrement progressif Simulation numérique Progressive collapse Dynamic loads Numerical simulation 530
12	Structural response of steel and composite building frames further to an impact leading to the loss of a column. Luu Nguyen Nam, Hai 15 October 2009 (has links) See appended files. Altervative load path Loading sequence Multi-storey building Robustness Progressive collapse Catenary action Key elements
13	Evaluation Of Punching Shear Strength Design And Modelling Approaches For Slab-column Connections Zorlu, Merve 01 September 2012 (has links) (PDF) Flat plate systems are constructed with slabs directly supported on columns. Since there are no beams in the system, the behavior of connections between the slabs and columns play a crucial role. Due to the sudden and brittle nature of punching shear failures, slab-column connection design must be conducted with proper safety precautions. The first part of this study aims to evaluate the safety level of different design expressions in the codes. Fir this purpose, the ability of ACI 318-11, TS-500 and Eurocode-2 to estimate punching shear strength was examined in light of experimental results compiled from previous research. Interior and exterior connections were examined in the course of the study. In the second part of the study, beam and shell models were calibrated to simulate the load-deformation response of interior slab-column connections in light of experimental results. In the final part of this thesis, a typical floor plan of a flat plate system was analyzed to investigate the possibility of a progressivefailure mechanism after punching failure takes place at a slab-column connection. Minimum post-punching capacity required to avoid progressive punching failure in a floor was estimated. It is believed that, the results of this study can be helpful in guiding engineers in understanding the safety inherent in punching shear design expressions and to take necessary precautions against progressive collapse. TH Building Construction 1-9745
14	Analysis Of Blast Loading Effect On Regular Steel Building Structures Tahmilci, Fatih 01 December 2007 (has links) (PDF) Concern about effect of explosives effect on engineering structures evolved after the damage of Second World War. Beginning from 90&rsquo / s with the event of bombing Alfred P. Murrah Federal building located in Oklahoma City this concern deepened and with the attack to World Trade Center twin towers on September 11, 2001 it is peaked. Recent design codes mainly focus on earthquake resistant design and strengthening of the structures. These code design methodologies may sometimes satisfy current blast resistant design philosophy, but in general code compliant designs may not provide recognizable resistance to blast effect. Therefore designer should carry out earthquake resistant design with the blast resistant design knowledge in mind in order to be able to select the most suitable framing scheme that provide both earthquake and blast resistance. This is only possible if designer deeply understands and interprets the blast phenomenon. In this study, it is intended to introduce blast phenomenon, basic terminology, past studies, blast loading on structures, blast structure interaction, analysis methodologies for blast effect and analysis for blast induced progressive and disproportionate collapse. Final focus is made on a case study that is carried out to determine whether a regular steel structures already designed according to Turkish Earthquake Code 2007 requirements satisfy blast, thus progressive collapse resistance requirements or not.
15	Experimental testing of a steel gravity frame with a composite floor under interior column loss Hull, Lindsay A. 21 November 2013 (has links) Progressive collapse research aims to characterize and quantify the behavior of different structural systems in events of extreme local damage caused by bombings to improve the performance of targeted structures and to protect occupants. The focus of the research program described herein is the performance of steel gravity frame structures with composite floor systems in column loss scenarios. The goal of the project is to contribute to the development of rational design guidelines for progressive collapse resistance and to assess any potential weaknesses in current design standards. This thesis presents the results of a series of tests performed on a steel frame structure with simple framing connections and a composite floor slab under interior column loss. The specimen was designed and constructed in accordance with typical design practices and was subjected to increasing uniform floor loads after static removal of the central column. No significant structural damage was observed up to a load equivalent to the ultimate gravity design load. Further testing was performed after the deliberate reduction of the capacity of the steel framing connections, ultimately resulting in total collapse of the specimen. / text Progressive collapse Disproportionate collapse Column loss Steel gravity frame Composite floor system
16	Διερεύνηση ανθεκτικότητας κατασκευών οπλισμένου σκυροδέματος μέσω μη γραμμικών αναλύσεων μεγάλων παραμορφώσεων Ρόμπολας, Ιωάννης 12 June 2015 (has links) Το ζήτημα της σταδιακής κατάρρευσης ήρθε στο προσκήνιο με την κατάρρευση του κτηρίου Ronan Point Apartment Building στο Ηνωμένο Βασίλειο, το 1968. Με αφορμή το γεγονός αυτό, σχεδόν το σύνολο των κανονισμών οπλισμένου σκυροδέματος ανά τον κόσμο απέκτησε διατάξεις σχετικά με την προστασία κατασκευών από σταδιακή κατάρρευση. Στα πλαίσια αυτού, εξετάζονται δύο διατάξεις πλακολωρίδας δύο ανοιγμάτων υπό το σενάριο της κατάρρευσης της ακραίας στήριξης. Η πρώτη διάταξη είναι οπλισμένη κατά τα συνήθη πρότυπα, ενώ η δεύτερη περιλαμβάνει επιπλέον οπλισμό στο άνω πέλμα των ανοιγμάτων. Οι αναλύσεις διεξάγονται σε περιβάλλον πεπερασμένων στοιχείων ANSYS και συγκρίνονται με αντίστοιχα πειραματικά αποτελέσματα. Συμπεραίνεται ότι οι συνήθεις πλάκες δεν έχουν την δυνατότητα ανάπτυξης μεγάλων μετατοπίσεων και ότι η προσθήκη οπλισμού στο άνω πέλμα των ανοιγμάτων των πλακών προσδίδει σε αυτές την απαραίτητη πλαστιμότητα, ώστε να μπορούν να αναπτύξουν μεγάλεις μετακινήσεις και να αναπτύσσονται δυνάμεις ελκυστήρα. / The issue of progressive collapse came to the foreground with the collapse of the Ronan Point Building in the UK, in 1968. In response to this event, most reinforced concrete codes around the work integrated regulations in regard to protection of buildings against progressive collapse. Two two-span slab assemblies are analysed for the collapse of the outer support. The first assembly is reinforce according to the common practice, while the second has added reinforced to the top end of the spans. The analyses are performed with ANSYS and compared with experimental results. It is concluded that commonly reinforced slabs do not have the ability to withstand large deflections. Additional top end reinforcement gives slabs the necessary plasticity in order for large deflections to be developed and tension (tie) forces to build up in the section. Σταδιακή κατάρρευση Οπλισμένο σκυρόδεμα 624.153 37 ANSYS Large displacement Progressive collapse
17	Novo método para a avaliação do risco de colapso progressivo em edifícios de alvenaria estrutural / New method for assessment the risk of progressive collapse in masonry structural buildings Túlio Raunyr Cândido Felipe 03 February 2017 (has links) O evento do colapso progressivo começou a ser estudado, principalmente, após o acidente do edifício Ronan Point, em 1968, na cidade de Londres. Esse acidente fez o meio técnico rever as considerações normativas, sobretudo de maneira a adicionar recomendações que visem minimizar os danos causados à estrutura quando sujeita a um dano acidental.Entretanto, tais recomendações não realizam a análise do risco da estrutura colapsar. Essas também não conseguem analisar medidas de robustez e vulnerabilidade, e nem determinar qual é o elemento chave para a estrutura. Desse modo, partindo desses questionamentos, o presente trabalho desenvolveu uma nova metodologia nomeada aqui de Risk Analysis of the Progressive Collapse (RAPC). Este procedimento fornece uma medida mais precisa dos riscos, através de uma abordagem que utiliza a Teoria da Confiabilidade Estrutural. Assim, é deduzida uma expressão para a determinação da probabilidade de colapso progressivo, bem como são definidos os coeficientes de importância e vulnerabilidade para identificar o(s) elemento(s) chave. O elemento chave é definido como o que apresenta a maior interseção entre vulnerabilidade e importância para o colapso estrutural. Essas formulações desenvolvidas na metodologia do RAPC são implementadas em Fortran. Para isso, a modelagem do edifício de alvenaria estrutural é feita utilizando o software DIANA®, no qual os esforços solicitantes são obtidos e utilizados como dados de entrada na análise de confiabilidade. Valores de probabilidades de falha individual por elemento, condicional e condicional dupla são calculados pelo First Order Reliability Method (FORM) e Importance Sampling Monte Carlo (ISMC) com auxílio do programa StRAnD. Um algoritmo em Fortran é implementado para acoplamento do DIANA® e StRAnD, além de mapear a probabilidade de falha dos elementos estruturais. Portanto, torna-se evidente que a identificação dos elementos mais vulneráveis, e do elemento chave em particular, é útil para abordagens diretas de concepção estrutural, tais como a melhoria da resistência local. Contudo, os coeficientes propostos também medem os efeitos dos procedimentos de projeto que conduzem à continuidade, ductilidade e redundância. Quando essas medidas trabalham para reduzir as probabilidades de propagação de dano ou colapso, isso se reflete nas vulnerabilidades de elementos eventualmente iniciando esses caminhos de falha. Sendo assim, conclui-se que a formulação do RAPC se mostra como uma ferramenta na determinação do risco do colapso progressivo nas estruturas. / The progressive collapse event began to be studied, mainly, after the accident of the Ronan Point building, at 1968, in the city of London. This accident caused the engineers review their normative considerations, mainly in order to add recommendations aimed at minimizing the damage to structure when subjected to abnormal loading. However, such recommendations do not perform the risk analysis of the structure to collapse. These also fail to analyze measures of robustness and vulnerability, and either determine which is the key element of the structure. Thus, leaving of these questions, the present work to develop a new methodology named here of Risk Analysis of the Progressive Collapse (RAPC). This procedure provides a more accurate measure of risks through an approach that uses Structural Reliability Theory. Thus, an expression is deduced for the determination of the probability of progressive collapse, as well as the importance and vulnerability coefficients are defined to identify the key element (or key elements). The key element is identified as the one presenting the largest intersection between vulnerability and importance to collapse.These formulations developed in the RAPC methodology are implemented in Fortran.For this, the structural masonry building modeling is done using the DIANA® software, in which the requesting efforts are obtained and used as input data in the reliability analysis. Probabilities values individual, conditional, and double conditional are calculated by the First Order Reliability Method (FORM) and Importance Sampling Monte Carlo (ISMC) using the StRAnD software. A Fortran algorithm is implemented for DIANA® and StRAnD coupling, besides mapping the probability of failure of the structural elements. Therefore, it is clear that identification of the most vulnerable elements, and of the key element in particular, is useful for direct design approaches to structural design, such as local resistance enhancements. However, the coefficients proposed herein also measure the effects of design procedures leading to continuity, ductility or redundancy. When these measures work to reduce probabilities of damage propagation or collapse, this is reflected in the vulnerabilities of elements eventually initiating these failure paths. Therefore, it is concluded that the formulation of RAPC is shown as an tool in determining the risk of progressive collapse in structures. Colapso progressivo Confiabilidade estrutural Dano acidental RAPC Abnormal loading Progressive collapse RAPC Structural reliability
18	Robustness of steel framed buildings with pre-cast concrete floor slabs Miratashi Yazdi, Seyed Mansoor January 2014 (has links) Following some incidents in high-rise buildings, such as Ronan Point London 1968, in which collapse of a limited number of structural elements progressed to a failure disproportionate to the initial cause, consideration of robustness was introduced in British Standard. The main method of preventing progressive collapse for providing robustness to steel framed buildings with precast concrete floor slabs focuses on the allowable tying forces that the reinforcement in between the slabs and in hollowcores should carry. However there are uncertainties about the basis of the practical rules associated with this method. This thesis presents the results of numerical and analytical studies of tie connection behaviour between precast concrete floor slabs (PCFS). It is shown that under current design regulations the tie connection is not able to resist the accidental load limit applied on the damaged floor slabs. By establishing the capability of a finite element model to depict and predict the behaviour of concrete members in situations such as arching and catenary action against several experimental tests, an extensive set of parametric studies was conducted in order to identify the effective parameters in enhancing the resistance of the tie connection between PCFSs. These parameters include: tie bar diameter, position, length, yield stress and ultimate strain; the slab’s height, length; and the compressive strength of the grouting concrete in between the slabs that encases the tie bar. Recommendations are made based on the findings of this parametric study in order to increase the resistance of the tie connection. Based on the identified effective parameters in the parametric study a predictive analytical relationship is derived which is capable of determining the maximum vertical displacement and load that the tie connection is able to undergo. This relationship can be used to enable the connection to capture the accidental limit load on a damaged slab. The identified parameters are examined in a three dimensional finite element model to assess their effect when columns of the structure are lost in different locations such as an edge, corner or internal column. Based on the findings of this study methods for improving the connections performance are presented. Also the effect of alternative transverse tying method is evaluated and it is concluded that although this kind of tie increases the load carrying capacity of the connection, its effect on the catenary action is not significant. 624.1
19	Analysis of progressive collapse in single-story buildings affected by local fire Hedlund, Tim January 2020 (has links) When a building is exposed to fire, it is required to remain structurally stable for a period of time. The regulations do however allow some types of localised failures within this time frame. The damage area of these failures must be contained and remain proportional to the initial triggering action and not continue into a widespread collapse, commonly referred to as a progressive collapse. In order to prevent progressive collapses, it is necessary to first identify which types of failures that could result in a progressive collapse. In a recent study (Iqbal N., Ph.D. thesis, Luleå University of Technology, 2016), single-storey steel frame buildings affected by localised fires were analysed. In the study it was identified that an initial failure in the truss’ top chord could potentially result in a progressive collapse. The reason for this is because when the top chord fails, the truss and its roof sheeting deflect and transitions into only handling catenary forces. The catenary forces present in the roof sheeting are then transferred to the adjacent trusses which therefore risks collapsing. The analysis could however not determine the possibility of progressive collapses and how factors such as truss span length affect the possibility of progressive collapses. The purpose of this thesis therefore became to analyse how span length affect the roof sheeting’s catenary forces and try to determine if a failure in the top chord could result in a progressive collapse. To answer this, finite element analyses where conducted on two different truss models with varying span lengths, i.e. 18- and 36-meter. Each model consisted of three trusses along with columns, bracings, and roof sheeting. Additionally, a hand calculation model was adopted to determine the strength of the catenary forces. From the finite element analysis, it could be seen that the adjacent trusses of the 36-meter truss model became grossly deformed. Hence indicating that a longer span length would increase the possibility of a progressive collapse. However, the hand calculation model used to calculate the strength of the catenary forces indicated that catenary forces present in the roof sheeting of the longer truss model, was relatively weak compared to the shorter truss model. The reason for this could not be determined, but some adjustments to the hand calculation model might be necessary to make it compatible with the analysed truss model. Consequently, it was impossible to determine the possibility of a progressive collapse. Additionally, during this work it was identified that other factors, such as truss model, bay length and roof sheeting thickness, could affect the possibility of progressive collapses. Hence, further work is necessary to determine the possibility of a progressive collapse. / När en byggnad utsätts för brandpåverkan ska den förbli strukturellt stabil under en viss tidsperiod. Regelverken tillåter dock att vissa typer av lokala skador inträffar redan under denna tidsperiod. Dessa skador måste begränsas till en viss area och förbli proportionerliga mot den initiala skadan och inte resultera i utbredda kollapser, det vill säga fortskridande ras. För att kunna förhindra fortskridande ras är det nödvändigt att först identifiera vilka typer av skador som skulle kunna resultera i fortskridande ras. I en relativt ny analys (Iqbal N., Doktorsavhandling, Luleå tekniska universitet, 2016) analyserades den bärande konstruktionen i enplans stålhallar då konstruktionen utsattes för lokala bränder. Där det identifierades att ett brott i balkens överram eventuellt skulle kunna resultera i ett fortskridande ras. Brottet i överramen medförde nämligen att balken och dess takplåt sjönk ihop och övergick till att endast hantera linkrafter. Takplåtens linkrafter fördelades ut till de angränsade balkarna som därmed riskerade att kollapsa. Analysen kunde dock inte verifiera att ett fortskridande ras var möjligt eller avgöra hur faktorer såsom balkspännvidd påverkade sannolikheten för ett fortskridande ras. Syftet med detta arbete blev därför att analysera om balkspännvidd påverkade takplåtens linkrafter samt att försöka avgöra om ett brott i överramen kan resultera i ett fortskridande ras eller inte. För att besvara detta genomfördes finita elementanalyser på en 18- och en 36-meter lång balk. Varje modell bestod av tre balkar med tillhörande pelare och takplåt. För att sedan kunna uppskatta styrkan av linkrafterna i takplåten tillämpades en handberäkningsmodell. Resultatet från finita elementanalyserna visade att den längre balkmodellen utsattes för högre påkänningar i jämförelse med den kortare balkmodellen. Detta indikerar att en längre spännvidd ökar sannolikheten för fortskridande ras. Handberäkningsmodellen som användes för att beräkna styrkan av linkrafterna gav dock generellt mindre linkrafter för den längre balkmodellen jämfört med den kortare balkmodellen. Anledningen till detta gick inte att fastställa men det skulle kunna vara så att handberäkningsmodellen behöver justeras för att kunna tillämpas på den undersökta balkmodellen. I och med detta var det omöjligt att avgöra sannolikheten för ett fortskridande ras. Under detta arbete identifierades det även att andra faktorer så som balkmodell, centrumavstånd mellan fackverk och plåttakstjocklek skulle kunna påverka linkrafternas styrka. På grund av detta är fortsatt arbete nödvändigt för att kunna avgöra möjligheten och sannolikheten för ett fortskridande ras. Progressive collapse Catenary force Local fire Steel buildings Finite element analysis Civil Engineering Samhällsbyggnadsteknik
20	Reliability Assessment of Alternate Path Method for Structural Steel Connections Noe, Norman E., III 28 August 2019 (has links) No description available. Civil Engineering Alternate Path Method Progressive Collapse Steel Moment Frame Connections Reliability

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