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181	Análise de peças fletidas com protensão não aderente pelo método dos elementos finitos / Analysis of bending members with unbonded tendons through the finite element method Jost, Daniel Trevisan January 2006 (has links) Estruturas com protensão não aderente estão sendo utilizadas como uma alternativa na tecnologia de projeto e execução de edifícios. Este trabalho apresenta a análise numérica de estruturas com protensão não aderente. Para este fim, foi desenvolvido um programa computacional onde implementou-se um modelo não linear físico e geométrico através do método dos elementos finitos. O comportamento dos materiais é descrito por um modelo elasto-viscoplástico. No concreto, são utilizados elementos finitos isoparamétricos tridimensionais. Para representar o seu comportamento após a fissuração é utilizado o modelo de fissuras distribuídas. As armaduras são incluídas através do modelo incorporado, utilizando-se de elementos unidimensionais isoparamétricos.As armaduras passivas são consideradas como uma linha de material mais rígido no interior do elemento de concreto, existindo uma aderência perfeita entre o concreto e o aço. Nas armaduras não aderentes, é considerada a compatibilidade de deslocamentos entre os materiais apenas nas ancoragens, sendo que a armadura pode movimentar-se livremente no interior do concreto. O modelo não linear geométrico, utilizado para o concreto e para a armadura, foi desenvolvido com base na formulação Lagrangeana Total, considerando grandes deslocamentos e pequenas deformações. Para verificar a precisão do modelo computacional, compararam-se resultados numéricos com valores experimentais disponíveis na literatura. / Unbonded prestressed concrete structures have been increasingly used as an alternative in the technology of design and construction of buildings. This work presents a numerical analysis of unbonded prestressed concrete structures. To accomplish this, a computational program has been developed in which a physical and geometrical nonlinear model was implemented through the finite element method. Materials behavior has been described through an elasto-viscoplastic model. In the concrete, a threedimensional isoparametric finite element has been used. To represent its behavior after cracking, the smeared cracking model has been used to. The prestressing tendons and reinforcement have been included according with the embedded model approach by the use of one-dimensional isoparametric elements. The reinforcement has been considered in the model as a line of a stiffer material inside the concrete element, with a perfect bonding between concrete and steel. As for the unbonded tendons, displacement compatibility between materials has been considered only at the anchorages, but they are allowed to move freely along their length inside the concrete. The geometric nonlinear model that has been used for the concrete, reinforcement and tendons has been developed according to the Total Lagrangean formulation, considering large displacements and small strains. In order to evaluate the accuracy of the computational model, numerical results have been compared with experimental values available in the literature. Elementos finitos Estruturas de concreto protendido Prestressed concrete Unbonded tendons Finite element method
182	Inelastic bending of rectangular plates and prestressed concrete slabs. Youssef, Ali Abdel-Rahman. January 1971 (has links) No description available. Concrete slabs Finite element method Plates (Engineering)
183	Investigation of high strength stainless steel prestressing strands Schuetz, Daniel Philip 10 January 2013 (has links) Bridges and other coastal structures in Georgia and throughout the Southeast are deteriorating prematurely due to corrosion. Numerous corrosion initiated failures have occurred in precast prestressed concrete (PSC) piles and reinforced concrete (RC) pile caps, leading to the costly repair and replacement of either the entire bridge or the affected members. With the Federal Highway Administration's goal of a 100-year bridge service life and recent legislative action such as the Bridge Life Extension Act, new emphasis has been placed on the development and implementation of new corrosion mitigation techniques. This thesis involves the mechanical testing, and proposed future test program of high-strength stainless steel (HSSS) prestressing strand to be used in prestressed marine bridge piles. The metallurgy for two types of HSSS strand was selected from a previous study of the corrosion resistance, mechanical properties, and feasibility of 6 candidate HSSS drawn wire samples. Duplex stainless steel (DSS) grades 2205 and 2304 were selected for production of 7-wire 1/2" diameter prestressing strand. DSS wire rod was drawn, stranded, and heat-treated using the same production methods and equipment as used for standard of practice, high carbon prestressing strand. The production process was documented to analyze the problems facing this production method and suggest improvement and optimization. After production, the strands were subjected to a series of mechanical tests. Tension testing was performed to provide a stress-strain curve for the strands and related mechanical properties. Wire samples were also taken at varying points in the drawing process to give more information about the work hardening of the stainless steels. Stress relaxation testing was performed on both strand and wire samples to assess the overall losses and to provide comparisons between strand and wire test results as well as drawn wires before and after heat-treatment. An experimental program for future study was designed to assess the HSSS prestressing strand behavior in precast piles. This testing involves assessment of pile driving performance, pile flexural and shear behavior, strand transfer and development length, long-term prestressing force losses, and material durability. Construction materials Stainless steels Prestressed concrete Bridge piles Building materials Steel, Structural Girders
184	Characterization of Self-Consolidating Concrete for the Design of Precast, Pretensioned Bridge Superstructure Elements Kim, Young Hoon 14 January 2010 (has links) Self-consolidating concrete (SCC) is a new, innovative construction material that can be placed into forms without the need for mechanical vibration. The mixture proportions are critical for producing quality SCC and require an optimized combination of coarse and fine aggregates, cement, water, and chemical and mineral admixtures. The required mixture constituents and proportions may affect the mechanical properties, bond characteristics, and long-term behavior, and SCC may not provide the same inservice performance as conventional concrete (CC). Different SCC mixture constituents and proportions were evaluated for mechanical properties, shear characteristics, bond characteristics, creep, and durability. Variables evaluated included mixture type (CC or SCC), coarse aggregate type (river gravel or limestone), and coarse aggregate volume. To correlate these results with full-scale samples and investigate structural behavior related to strand bond properties, four girder-deck systems, 40 ft (12 m) long, with CC and SCC pretensioned girders were fabricated and tested. Results from the research indicate that the American Association of State Highway Transportation Officials Load and Resistance Factor Design (AASHTO LRFD) Specifications can be used to estimate the mechanical properties of SCC for a concrete compressive strength range of 5 to 10 ksi (34 to 70 MPa). In addition, the research team developed prediction equations for concrete compressive strength ranges from 5 to 16 ksi (34 to 110 MPa). With respect to shear characteristics, a more appropriate expression is proposed to estimate the concrete shear strength for CC and SCC girders with a compressive strength greater than 10 ksi (70 MPa). The author found that girder-deck systems with Type A SCC girders exhibit similar flexural performance as deck-systems with CC girders. The AASHTO LRFD (2006) equations for computing the cracking moment, nominal moment, transfer length, development length, and prestress losses may be used for SCC girder-deck systems similar to those tested in this study. For environments exhibiting freeze-thaw cycles, a minimum 16-hour release strength of 7 ksi (48 MPa) is recommended for SCC mixtures. Bridge Structure Self-Consolidating Concrete Precast, Prestressed Concrete AASHTO LRFD Specifications Bridge Design
185	Seismic performance of flexible concrete structures / Feghali, Habib Labib, January 1999 (has links) Thesis (Ph. D.)--University of Texas at Austin, 1999. / Vita. Includes bibliographical references (leaves 256-262). Available also in a digital version from Dissertation Abstracts.
186	Development of a new spun concrete pole reinforced with carbon fiber reinforced polymer bars Shalaby, Ashraf Mounir Mahmoud. January 2007 (has links) (PDF) Thesis (Ph. D.)--University of Alabama at Birmingham, 2007. / Title from PDF title page (viewed Feb. 5, 2010). Additional advisors: Ashraf Al Hamdan, Wilbur A. Hitchcock, Jason T. Kirby, Talat Salama. Includes bibliographical references (p. 148-153).
187	Estimation of beam prestress by deflection and strain measurements An, JinWoo 29 October 2012 (has links) Laboratory test of reinforced and prestressed concrete structures have been used widely to explore the behavior of reinforced and prestressed concrete components and structures; Such tests are often time-consuming and costly. However, numerical models have been shown to compare favorably with experiments. Thus, computations are viewed nowadays as efficient alternatives to tests, time-wise and cost-wise. In the research reported in this thesis, finite-element model were used in a study of pretressed structural components in order to correlate levels of pretension with deflection and strain measurements. The two main objectives were to develop a suitable finite element model of prestressed concrete beams and to forecast beam prestension on the basis of deformations resulting from specified simple load, e.g., a uniformly distributed transverse load. A commercial finite-element analysis package (ANSYS 12) was used to set up, use and evaluate the computational model. Furthermore, a finite-difference model was employed in order to ascertain the validity of ANSYS results by comparison with engineering beam theory taking into account the applied pretension. This study demonstrates the potential usefulness of deflection and strain measurements as indicators of the pretension applied or remaining in prestressed concrete beams. / text Prestressed concrete beam Estimation of beam prestress Surface strain Finite difference model Finite element analysis
188	Development of software architecture to investigate bridge security Bui, Joeny Quan 04 March 2013 (has links) After September 11, 2001, government officials and the engineering community have devoted significant time and resources to protect the country from such attacks again. Because highway infrastructure plays such a critical role in the public’s daily life, research has been conducted to determine the resiliency of various bridge components subjected to blast loads. While more tests are needed, it is now time to transfer the research into tools to be used by the design community. The development of Anti-Terrorism Planner for Bridges (ATP-Bridge), a program intended to be used by bridge engineers and planners to investigate blast loads against bridges, is explained in this thesis. The overall project goal was to build a program that can incorporate multiple bridge components while still maintaining a simple, user-friendly interface. This goal was achieved by balancing three core areas: constraining the graphical user interface (GUI) to similar themes across the program, allowing flexibility in the creation of the numerical models, and designing the data structures using object-oriented programming concepts to connect the GUI with the numerical models. An example of a solver (prestressed girder with advanced SDOF analysis model) is also presented to illustrate a fast-running algorithm. The SDOF model incorporates the development of a moment-curvature response curve created by a layer-by-layer analysis, a non-linear static analysis accounting for both geometric non-linearity as well as material non-linearity, and a Newmark-beta-based SDOF analysis. The results of the model return the dynamic response history and the amount of damage. ATP-Bridge is the first software developed that incorporates multiple bridge components into one user-friendly engineering tool for protecting bridge structures against terrorist threats. The software is intended to serve as a synthesis of state-of-the-art knowledge, with future updates made to the program as more research becomes available. In contrast to physical testing and high-fidelity finite element simulations, ATP-Bridge uses less time-consuming, more cost effective numerical models to generate dynamic response data and damage estimates. With this tool, engineers and planners will be able to safeguard the nation’s bridge inventory and, in turn, reinforce the public’s trust. / text Bridge security Protective design SDOF Single-degree-of-freedom Prestressed concrete girder Object-oriented programming Direct3D Blast
189	Behavior of the cast-in-place splice regions of spliced I-girder bridges Williams, Christopher Scott 17 September 2015 (has links) Spliced girder technology continues to attract attention due to its versatility over traditional prestressed concrete highway bridge construction. Relatively limited data is available in the literature, however, for large-scale tests of post-tensioned I-girders, and few studies have examined the behavior of the cast-in-place (CIP) splice regions of post-tensioned spliced girder bridges. In addition to limited knowledge on CIP splice region behavior, a wide variety of splice region details (e.g., splice region length, mild reinforcement details, cross-sectional geometry, etc.) continue to be used in the field. In response to these issues, the research program described in this dissertation was developed to (i) study the strength and serviceability behavior of the CIP splice regions of spliced I-girders, (ii) identify design and detailing practices that have been successfully implemented in CIP splice regions, and (iii) develop design recommendations based on the structural performance of spliced I-girder test specimens. To accomplish these tasks, an industry survey was first conducted to identify the best practices that have been implemented for the splice regions of existing bridges. Splice region details were then selected to be included in large-scale post-tensioned spliced I-girder test specimens. Two tests were conducted to study splice region behavior and evaluate the performance of the chosen details. The failure mechanisms of both test girders were characterized by a shear-compression failure of the web concrete with primary crushing occurring in the vicinity of the top post-tensioning duct. Most significantly, the girders acted essentially as monolithic members in shear at failure. Web crushing extended across much of the test span and was not localized within the splice regions. To supplement the spliced girder tests, a shear-friction experimental program was also conducted to gain a better understanding of the interface shear behavior between precast and CIP concrete surfaces at splice regions. The findings of the shear-friction study are summarized within this dissertation. Based on the results of the splice region research program, design recommendations were developed, including recommended CIP splice region details. Spliced girder Splice region Post-tensioning Prestressed concrete Shear I-girder
190	Short-term and time-dependent stresses in precast network arches Yousefpoursadatmahalleh, Hossein 17 September 2015 (has links) Due to their structural efficiency and architectural elegance, concrete arches have long been used in bridge applications. However, the construction of concrete arches requires significant temporary supporting structures, which prevent their widespread use in modern bridges. A relatively new form of arch bridges is the network arch, in which a dense arrangement of inclined hangers is used. Network arches are subjected to considerably smaller bending moments and deflections than traditional arches and are therefore suitable for modern, accelerated construction methods in which the arches are fabricated off-site and then transported to the bridge location. However, service-level stresses, which play a critical role in the performance of the structure, are relatively unknown for concrete network arches and have not been sufficiently investigated in the previous research on concrete arches. The primary objective of this dissertation is to improve the understanding of short-term and time-dependent stresses in concrete arches, and more specifically, concrete network arches. The research presented herein includes extensive field monitoring of the West 7th Street Bridge in Fort Worth, Texas, which is the first precast network arch bridge and probably the first concrete network arch bridge in the world. The bridge consists of twelve identically designed concrete network arches that were precast and post-tensioned before they were transported to the bridge site and erected. A series of vibrating wire gages were embedded in the arches and were monitored throughout the construction and for a few months after the bridge was opened to traffic. The obtained data were processed, and structural response parameters were evaluated to support the safe construction of the innovative arches, identify their short-term and time-dependent structural behavior, and verify the modeling assumptions. The variability of stresses among the arches was also used to assess the reliability of stress calculations. The results of this study provide valuable insight into the elastic, thermal, and time-dependent behavior of concrete arches in general and concrete network arches in particular. The knowledge gained in this investigation also has broader applications towards understanding the behavior of indeterminate prestressed concrete structures that are subjected to variable boundary conditions and thermal and time-dependent effects. Structural health monitoring Accelerated bridge construction Precast Prestressed concrete Time-dependent behavior of concrete Creep Arch bridge

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