Earthquake Resilient Bridge Columns Utilizing Damage Resistant Hybrid Fiber Reinforced Concrete

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Earthquake Resilient Bridge Columns Utilizing Damage Resistant Hybrid Fiber Reinforced Concrete

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Author : William Dean Trono
Publisher :
ISBN 13 :
Total Pages : 199 pages
Book Rating : 4.:/5 (94 download)

Book Synopsis Earthquake Resilient Bridge Columns Utilizing Damage Resistant Hybrid Fiber Reinforced Concrete by : William Dean Trono

Download or read book Earthquake Resilient Bridge Columns Utilizing Damage Resistant Hybrid Fiber Reinforced Concrete written by William Dean Trono and published by . This book was released on 2014 with total page 199 pages. Available in PDF, EPUB and Kindle. Book excerpt: Modern reinforced concrete bridges are designed to avoid collapse and to prevent loss of life during earthquakes. To meet these objectives, bridge columns are typically detailed to form ductile plastic hinges when large displacements occur. California seismic design criteria acknowledges that damage such as concrete cover spalling and reinforcing bar yielding may occur in columns during a design-level earthquake. The seismic resilience of bridge columns can be improved through the use of a damage resistant hybrid fiber reinforced concrete (HyFRC). Fibers delay crack propagation and prevent spalling under extreme loading conditions, and the material resists many typical concrete deterioration mechanisms through multi-scale crack control. Little is known about the response of the material when combined with conventional reinforcing bars. Therefore, experimental testing was conducted to evaluate such behaviors. One area of focus was the compression response of HyFRC when confined by steel spirals. A second focus was the tensile response of rebar embedded in HyFRC. Bridge columns built with HyFRC would be expected to experience both of these loading conditions during earthquakes. The third focus of this dissertation was the design, modeling, and testing of an innovative damage resistant HyFRC bridge column. The column was designed to rock about its foundation during earthquakes and to return to its original position thereafter. In addition to HyFRC, it was designed with unbonded post-tensioning, unbonded rebar, and headed rebar which terminated at the rocking plane. Because of these novel details, the column was not expected to incur damage or residual displacements under earthquake demands exceeding the design level for ordinary California bridges. A sequence of scaled, three dimensional ground motion records was applied to the damage resistant column on a shaking table. An equal scale reinforced concrete reference column with conventional design details was subjected to the same motions for direct comparison. Compression tests showed that the ductility of HyFRC is superior to concrete in the post-peak softening branch of the response. HyFRC achieved a stable softening response and had significant residual load capacity even without spiral confinement. Concrete required the highest tested levels of confinement to achieved comparable post-peak ductility. Tension tests showed that HyFRC provides a substantial strength enhancement to rebar well beyond their yield point. Interesting crack localization behavior was observed in HyFRC specimens and appeared to be dependent on the volumetric ratio of rebar. The damage resistant HyFRC bridge column attained its design objectives during experimental testing. It exhibited pronounced reentering behavior with only light damage under earthquake demands 1.5 to 2.0 times the design level. It accumulated only 0.4% residual drift ratio after seven successive ground motions which caused a peak drift ratio of 8.0%. The conventional reinforced concrete column experienced flexural plastic hinging with extensive spalling during the same seven motions. It accumulated 6.8% residual drift ratio after enduring a peak drift ratio of 10.8%.

Self Compacting Hybrid Fiber Reinforced Concrete Composites for Bridge Columns

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Author : Pardeep Kumar
Publisher :
ISBN 13 :
Total Pages : 110 pages
Book Rating : 4.:/5 (762 download)

Book Synopsis Self Compacting Hybrid Fiber Reinforced Concrete Composites for Bridge Columns by : Pardeep Kumar

Download or read book Self Compacting Hybrid Fiber Reinforced Concrete Composites for Bridge Columns written by Pardeep Kumar and published by . This book was released on 2011 with total page 110 pages. Available in PDF, EPUB and Kindle. Book excerpt:

Seismic Response of a Hybrid Fiber-reinforced Concrete Bridge Column Detailed for Accelerated Bridge Construction

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Author : Wilson Nguyen
Publisher :
ISBN 13 :
Total Pages : 50 pages
Book Rating : 4.:/5 (96 download)

Book Synopsis Seismic Response of a Hybrid Fiber-reinforced Concrete Bridge Column Detailed for Accelerated Bridge Construction by : Wilson Nguyen

Download or read book Seismic Response of a Hybrid Fiber-reinforced Concrete Bridge Column Detailed for Accelerated Bridge Construction written by Wilson Nguyen and published by . This book was released on 2014 with total page 50 pages. Available in PDF, EPUB and Kindle. Book excerpt:

Seismic Strengthening of Concrete Buildings Using FRP Composites

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Author :
Publisher : American Concrete Institute
ISBN 13 : 0870313134
Total Pages : 148 pages
Book Rating : 4.8/5 (73 download)

Book Synopsis Seismic Strengthening of Concrete Buildings Using FRP Composites by :

Download or read book Seismic Strengthening of Concrete Buildings Using FRP Composites written by and published by American Concrete Institute. This book was released on 2008 with total page 148 pages. Available in PDF, EPUB and Kindle. Book excerpt: "This CD-ROM consists of eight papers that were presented by ACI Committee 440 at the Spring Convention in Atlanta, GA, in April 2007"--Site Web de l'éditeur

Shaking Table Evaluation of Reinforced Concrete Bridge Columns Repaired Using Fiber Reinforced Polymer Jackets

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Author : Pardeep Kumar
Publisher :
ISBN 13 :
Total Pages : 187 pages
Book Rating : 4.:/5 (919 download)

Book Synopsis Shaking Table Evaluation of Reinforced Concrete Bridge Columns Repaired Using Fiber Reinforced Polymer Jackets by : Pardeep Kumar

Download or read book Shaking Table Evaluation of Reinforced Concrete Bridge Columns Repaired Using Fiber Reinforced Polymer Jackets written by Pardeep Kumar and published by . This book was released on 2014 with total page 187 pages. Available in PDF, EPUB and Kindle. Book excerpt: After an earthquake event it is the responsibility of the engineers to decide if the bridge structure is safe for the traffic flow, requires repair or needs to be replaced completely depending on the damage level. Effective, economical and timely repair of Reinforced Concrete (RC) bridges after a seismic event is crucial to avoid traffic congestion and lengthy detours. Fiber Reinforced Polymer (FRP) composite laminates are one of few options with several advantages. Use of FRP jackets in structural engineering is gaining interest in applications such as strengthening weak structural elements, improving the existing structure capacity to resist increased loads due to change in use of structure and retrofitting structural elements for seismic upgrades. The study presents shaking table experimental investigation to evaluate the use of FRP for repairing RC bridge columns with circular cross-sections. Two 1/4-scale RC columns were tested in as-built configuration. Both tests had identical geometry and reinforcement details except for the spacing of the transverse reinforcing bars. One column had closely spaced hoops satisfying code requirements and the other had larger spacing, representing a shear-critical column. The test specimens were subjected to a series of horizontal and vertical excitations on a shaking table and experienced moderate to high damage. The damaged columns were subsequently repaired with unidirectional FRP composite laminates and subjected to the same set of earthquake excitations. The obtained experimental data showed that the repaired columns achieved higher strength and ductility with lower residual displacements compared to the as-built ones contributing to the resiliency of the bridge system. A three-dimensional (3D) Finite Element (FE) model was developed and calibrated using the experimental test results. A bilinear confined concrete model was adopted to model the constitutive relationship of the FRP confined concrete without explicitly modeling the FRP composite jacket. Due to variability of the material properties, several calibration parameters were studied to develop a reliable FE model. The results of the dynamic FE analysis showed great potential for 3D modeling of the repaired test specimens. From this study, it is concluded that the used FRP composite laminates represent a viable solution for the effective and rapid repair of damaged RC bridge columns. A parametric study was conducted to evaluate the horizontal force, deformation, and confining strain response of the retrofitted RC bridge columns using the computational model. The response of the FE models with different number of FRP plies in the jacket was investigated. The analytical results suggested that increasing the number of FRP plies in the jacket significantly changed the confining strains response of the confined cross-section but the global force-deformation was not significantly affected.

Unbonded Pre-tensioned Bridge Columns with Hybrid Fiber-reinforced Concrete Shells

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Author : Gunnsteinn Finnsson
Publisher :
ISBN 13 :
Total Pages : 156 pages
Book Rating : 4.:/5 (876 download)

Book Synopsis Unbonded Pre-tensioned Bridge Columns with Hybrid Fiber-reinforced Concrete Shells by : Gunnsteinn Finnsson

Download or read book Unbonded Pre-tensioned Bridge Columns with Hybrid Fiber-reinforced Concrete Shells written by Gunnsteinn Finnsson and published by . This book was released on 2013 with total page 156 pages. Available in PDF, EPUB and Kindle. Book excerpt: Many bridges in the United States are getting old and will need to be replaced in the near future. If these bridges are constructed with conventional cast-in-place methods, this construction will cause traffic congestion, which is a costly problem. Furthermore, these cast-in-place systems are susceptible to earthquake-induced damage, such as bar buckling, bar fracture and residual displacements. A new pre-tensioned precast bent system has been developed to meet these challenges. The system consists of precast technology to accelerate the bridge construction, unbonded pre-tensioning to minimize residual displacements, and high-performance materials that extend the bridge durability. Davis et al. (2012) tested the new system using only conventional concrete. They found out that pre-tensioning improves system's re-centering capabilities, but it results in earlier bar buckling and bar fracture than in previously tested reinforced concrete columns (Pang et al. 2008, Haraldsson et al. 2012). Two columns were designed and tested in the University of Washington Structural Laboratory. In the plastic-hinge region of the columns a very ductile concrete shell was added. The shell was made of a hybrid fiber reinforced concrete (HyFRC, developed by Prof. Ostertag at U.C. Berkeley) containing both polymer and steel fibers. The main goal of adding the shell was to delay spalling and buckling of the longitudinal reinforcement bars. One of the columns was the same as one of the columns tested by Davis with only the addition of HyFRC shell. The other column had a HyFRC shell in the plastic hinge region and stainless steel reinforcement bars as longitudinal reinforcement instead of regular black steel rebars. The addition of the stainless steel rebar was expected to increase the ductility of the system and minimize the corrosion susceptibility. The tests showed that the HyFRC delayed the concrete spalling, and to a limited extent, the buckling of the longitudinal bars. The main benefits of having the HyFRC shell was that the columns kept 80% of its strength at 10% drift ratio, which was much higher than the conventional concrete specimens tested by Davis et al. (2012). The response of the stainless steel column was comparable to the black steel column, the main difference being that the stainless steel column was stronger, because the stainless steel was stronger than the black steel.

Resilient Earthquake-resistant Bridges Designed for Disassembly

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Author : Sebastián Varela Fontecha
Publisher :
ISBN 13 :
Total Pages : 1706 pages
Book Rating : 4.:/5 (959 download)

Book Synopsis Resilient Earthquake-resistant Bridges Designed for Disassembly by : Sebastián Varela Fontecha

Download or read book Resilient Earthquake-resistant Bridges Designed for Disassembly written by Sebastián Varela Fontecha and published by . This book was released on 2016 with total page 1706 pages. Available in PDF, EPUB and Kindle. Book excerpt: Ordinary reinforced concrete (RC) highway bridges complying with current seismic design provisions are expected to be severely damaged during a strong earthquake. Previous earthquakes have shown that closing a bridge for repair or having to replace the bridge because of extensive damage and permanent tilting of the structure can be very costly and detrimental to the transportation in major urban areas. When RC bridges reach their useful life, only a small portion of the concrete and steel debris from demolition is recycled, while the rest goes to landfills. This is not the ideal end-of-life for construction materials because their extraction and manufacturing emits greenhouse gases, consumes energy, and depletes natural resources, all of which are negatively affecting the environment. In an attempt to link seismic resistance and resiliency with sustainability in bridge engineering, a new generation of earthquake-resistant and resilient highway bridges designed for disassembly (DfD) was developed in this study for the first time. The global objective of developing these bridges is to (1) minimize the economic impact of losing bridge functionality after strong earthquakes, and (2) reduce the environmental impact of producing new construction materials. The new bridge concept first involved the development and shake-table testing of three 1/4-scale deconstructible column models under simulated strong near-fault motions from the 1994, Northridge, California earthquake. The models were then disassembled and inspected, and subsequently reassembled and retested. Three replaceable plastic hinge elements and connections were developed incorporating advanced materials such as engineered cementitious composite (ECC), shimmed flexural rubber bearings, Nickel-Titanium (NiTi) and Copper-Aluminum-Manganese (CAM) super elastic shape memory alloy (SMA) bars, and prefabricated fiber-reinforced polymer (FRP) tubes were integrated in the column models. An additional cast-in-place column combining ECC and CAM SMA was designed and tested to develop an insight into the behavior of large-scale CAM-reinforced members under seismic loading before this type of SMA was adopted in the replaceable plastic hinge elements. The tests confirmed the feasibility of DfD columns. The experimental investigation was then complemented by analytical studies in OpenSees, in which analytical models were developed to replicate the measured response of the column models. To determine the feasibility of the columns within a bridge system, a 1/4-scale, three-bent, two-span bridge model was designed, constructed and tested under simulated near-fault earthquakes on three shake-tables. Upon successful performance of the original bridge, the bridge model was disassembled, all the components were inspected, and the bridge was subsequently reassembled and retested. Extensive evaluations of the behavior of the columns, connections, plastic hinges, as well as the entire system were made during the experimental investigation. The performance of the reassembled bridge demonstrated the feasibility of the proposed elements in a bridge system. Analytical studies using OpenSees were also conducted to develop a baseline for future studies.

Dynamic Properties and Application of Steel Fiber Reinforced Self-consolidating Concrete to Segmental Bridge Columns in Moderate-to-high Seismic Regions

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Author : Nasi Zhang
Publisher :
ISBN 13 :
Total Pages : 394 pages
Book Rating : 4.:/5 (964 download)

Book Synopsis Dynamic Properties and Application of Steel Fiber Reinforced Self-consolidating Concrete to Segmental Bridge Columns in Moderate-to-high Seismic Regions by : Nasi Zhang

Download or read book Dynamic Properties and Application of Steel Fiber Reinforced Self-consolidating Concrete to Segmental Bridge Columns in Moderate-to-high Seismic Regions written by Nasi Zhang and published by . This book was released on 2014 with total page 394 pages. Available in PDF, EPUB and Kindle. Book excerpt: In this dissertation, the application of steel fiber reinforced self-consolidating concrete (SFRSCC) to precast unbonded post-tensioned segmental bridge columns in moderate-to-high seismic regions is evaluated numerically and experimentally. Drop weight impact tests are first conducted on plain concrete and steel fiber reinforced concrete (SFRC). The standard drop test recommended by the American Concrete Institute (ACI) is first conducted and a modification to this standard ACI, which involves visual inspection of first cracking and ultimate failure, is then developed. The Kolmogorov-Smirnov (K-S) test along with fitted normal and lognormal distributions are used to examine the distribution of the number of blows required to cause first cracking and ultimate failure of the concrete. The minimum sample size required to calculate the impact strength of SFRC is determined using equations available in the literature. This sample size is used in the subsequent impact study on SFRSCC specimens. The static and dynamic properties of ten groups of SFRSCC, including one group of self-consolidating concrete (SCC) without steel fibers, are studied and compared. Dramix℗ʼ ZP305, RC-65/35-BN, and RC-80/30-BP steel fiber (glued and hooked end) at a volume of 0. 25%, 0. 5% and 1% are considered in the study. The static properties are calculated using compression tests, split-tension tests and flexural beam tests. The dynamic properties are determined using the modified ACI impact test. A dynamic load sensor is installed underneath the base plate of the impact test machine to measure the relative reaction force history. The recorded reaction forces are used to develop an automated impact test method, which can circumvent visual inspections. Two large-scale (1:3. 37), precast, unbonded and post-tensioned segmental columns, one constructed with SCC and one constructed with SFRSCC (with 0. 5% of ZP305 steel fiber by volume), are tested under cyclic loading. These segmental columns incorporate shear keys at the joints. The backbone force-displacement relationships of the segmental columns are calculated from a pushover model available in the literature. The hysteretic behavior of the segmental columns under cyclic loading is also simulated by a numerical model developed on the OpenSEES platform. A single span, large-scale (1:3. 37) bridge model incorporating SFRSCC segmental columns (with 0. 5% of ZP305 steel fiber by volume) is tested on a shake table. Two types of cap beam-to-superstructure connections are considered for the bridge model: a connection using non-seismic rubber bearing and a fixed connection. The bridge model is tested for far field and near field ground motions along various directions and with increasing peak ground accelerations (PGAs). The evolution of the cumulative damage to the bridge model after each seismic test is evaluated through a system identification involving white noise excitation. A flag-shaped hysteretic model is proposed and validated through the cyclic test results obtained in this research and those available in the literature. The proposed flag-shaped model is used to predict the seismic response of the bridge model. Adding steel fibers to concrete significantly improves its impact strength and ductility. The SFRSCC segmental columns suffered less damage than the SCC columns for the same level of drift. The large-scale bridge model incorporating SFRSCC segmental columns sustained high intensity far field and near field ground motions with limited damage. The proposed flag-shaped hysteretic model can be used to simulate the cyclic behavior of segmental columns, and to provide reasonable estimates of their seismic response under strong ground motions.

Post-earthquake Evaluation and Emergency Repair of Damaged RC Bridge Columns Using CFRP Materials

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Author : Ashkan Vosooghi
Publisher :
ISBN 13 : 9781124404332
Total Pages : 742 pages
Book Rating : 4.4/5 (43 download)

Book Synopsis Post-earthquake Evaluation and Emergency Repair of Damaged RC Bridge Columns Using CFRP Materials by : Ashkan Vosooghi

Download or read book Post-earthquake Evaluation and Emergency Repair of Damaged RC Bridge Columns Using CFRP Materials written by Ashkan Vosooghi and published by . This book was released on 2010 with total page 742 pages. Available in PDF, EPUB and Kindle. Book excerpt: The main objective of the study was to develop a rapid and effective repair method using carbon fiber reinforced polymer (CFRP) materials for earthquake-damaged reinforced concrete bridge columns. This study consisted of three main phases. In the first phase, a data base of 33 test columns was developed and analyzed and five distinct apparent seismic damage states were defined. The damage states were correlated to measured seismic response parameters in terms of drift, frequency, strains, and yield and ultimate displacements. Fragility curves were developed and applied for two case studies in performance-based design (PBD) and performance-based assessment (PBA) of bridge columns. Comprehensive experimental and analytical studies were conducted in the second phase of the study. Two standard single columns, one standard two-column bent, and two substandard columns were tested on a shake table, repaired using CFRP fabrics, and retested on the shake table to evaluate the proposed repair procedure. The measured data were extensively analyzed to investigate the performance of the repaired columns compared to the original column responses. It was concluded that the strength and ductility of the standard columns were successfully restored and those of sub-standard columns were upgraded to the current seismic standards after the repair. However, the stiffness was not restored due to material degradation during the original column tests. Even though the repair process was done rapidly and was treated as "emergency" repair with implication that it was a temporary measure, it can be treated as a permanent repair as long as the stiffness of repaired columns is sufficient for non-seismic loading. In the analytical studies, extensive static and dynamic nonlinear analyses were performed on the column models and a simple analytical method was developed for the repaired columns to account for stiffness degradation. Based on the results from the experimental and analytical studies, repair design recommendations were developed in the third phase to aid bridge engineers in quickly designing the number of layers of CFRP layers based on the apparent damage and basic information about the column fixity, size, and reinforcement.

Assessment of an Earthquake Resilient Bridge with Pretensioned, Rocking Columns

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Author : Islam Mohamed Mantawy
Publisher :
ISBN 13 :
Total Pages : 946 pages
Book Rating : 4.:/5 (959 download)

Book Synopsis Assessment of an Earthquake Resilient Bridge with Pretensioned, Rocking Columns by : Islam Mohamed Mantawy

Download or read book Assessment of an Earthquake Resilient Bridge with Pretensioned, Rocking Columns written by Islam Mohamed Mantawy and published by . This book was released on 2016 with total page 946 pages. Available in PDF, EPUB and Kindle. Book excerpt: The seismic performance of a new bridge system is studied, tested and improved. The new bridge system: 1) reduces onsite construction time by using precast components, 2) eliminates major earthquake damage by utilizing rocking column and confinement of the column ends with a steel tube, and 3) maintains the system functionality after a strong earthquake by minimizing residual drift through the use of prestressing strands in the columns. Furthermore, it uses only conventional materials. The shaking table performance of a quarter-scale, two-span bridge constructed using the new system was compared with that of a conventional cast-in-place bridge with similar geometry tested in 2005. The new bridge system was constructed in about 20% of the time needed for the conventional cast-in-place system. In the tests, the conventional bridge suffered major concrete cracking and spalling, whereas in the new system, damage to the concrete was only cosmetic. In the conventional bridge, the longitudinal bars buckled and both the longitudinal and spiral reinforcement fractured, whereas in the new system the damage to the reinforcement was limited to longitudinal bar fracture, and that occurred only under excitations larger than the design level motion. The residual drift of the new system was essentially zero for all motions, whereas one of the exterior bents of the conventional bridge was so badly damaged and out of plumb that some of the supplemental mass on the bridge had to be removed and testing was stopped shortly thereafter. The only substantial damage that the new bridge system experienced was longitudinal reinforcing fracture. Therefore, ways to delay fracture were developed analytically. Reinforcement fractures were audible during the shaking table tests of the pretensioned rocking system. Reinforcement fractures were estimated in three ways using: 1) audio recorded during each test, 2) measured rotations at column ends and 3) analytical models, which included a fatigue material. This analytical model was then used to explore methods to improve the performance of the system by delaying reinforcement fracture. The analytical parametric studies on the scaled model showed that increasing the bar size and the locally debonded length of the reinforcement were both effective strategies to reduce and delay bar fractures. For the shaking table experimental model configuration, the analytical model showed that increasing the longitudinal bars by one size and increasing the debonded length by 44% would delay bar fracture until an excitation 67% larger than the excitation where reinforcing bars first fractured in the physical experiment. The parametric study also was conducted for a prototype bent; this recommended values for longitudinal bar size, debonded lengths for longitudinal bars and effective prestressing for prestressing strands to delay the fracture of the longitudinal bars and the yielding of the prestressing strands until after the 150% design level motion.

Bridge Maintenance, Safety, Management, Life-Cycle Sustainability and Innovations

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Author : Hiroshi Yokota
Publisher : CRC Press
ISBN 13 : 100017381X
Total Pages : 8732 pages
Book Rating : 4.0/5 (1 download)

Book Synopsis Bridge Maintenance, Safety, Management, Life-Cycle Sustainability and Innovations by : Hiroshi Yokota

Download or read book Bridge Maintenance, Safety, Management, Life-Cycle Sustainability and Innovations written by Hiroshi Yokota and published by CRC Press. This book was released on 2021-04-20 with total page 8732 pages. Available in PDF, EPUB and Kindle. Book excerpt: Bridge Maintenance, Safety, Management, Life-Cycle Sustainability and Innovations contains lectures and papers presented at the Tenth International Conference on Bridge Maintenance, Safety and Management (IABMAS 2020), held in Sapporo, Hokkaido, Japan, April 11–15, 2021. This volume consists of a book of extended abstracts and a USB card containing the full papers of 571 contributions presented at IABMAS 2020, including the T.Y. Lin Lecture, 9 Keynote Lectures, and 561 technical papers from 40 countries. The contributions presented at IABMAS 2020 deal with the state of the art as well as emerging concepts and innovative applications related to the main aspects of maintenance, safety, management, life-cycle sustainability and technological innovations of bridges. Major topics include: advanced bridge design, construction and maintenance approaches, safety, reliability and risk evaluation, life-cycle management, life-cycle sustainability, standardization, analytical models, bridge management systems, service life prediction, maintenance and management strategies, structural health monitoring, non-destructive testing and field testing, safety, resilience, robustness and redundancy, durability enhancement, repair and rehabilitation, fatigue and corrosion, extreme loads, and application of information and computer technology and artificial intelligence for bridges, among others. This volume provides both an up-to-date overview of the field of bridge engineering and significant contributions to the process of making more rational decisions on maintenance, safety, management, life-cycle sustainability and technological innovations of bridges for the purpose of enhancing the welfare of society. The Editors hope that these Proceedings will serve as a valuable reference to all concerned with bridge structure and infrastructure systems, including engineers, researchers, academics and students from all areas of bridge engineering.

Design and Evaluation of Reinforced Concrete Bridges for Seismic Resistance

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Author : Mark Aschheim
Publisher :
ISBN 13 :
Total Pages : 216 pages
Book Rating : 4.F/5 ( download)

Book Synopsis Design and Evaluation of Reinforced Concrete Bridges for Seismic Resistance by : Mark Aschheim

Download or read book Design and Evaluation of Reinforced Concrete Bridges for Seismic Resistance written by Mark Aschheim and published by . This book was released on 1997 with total page 216 pages. Available in PDF, EPUB and Kindle. Book excerpt: In this report, seismic design approaches for reinforced concrete bridges are reviewed and uncertainties in seismic design and evaluation are discussed. The modeling of bridge components and systems is discussed, and analytical studies of the response series of simple bridges are made. The relative utility of several design approaches and stiffness assumptions for controlling seismic demands is assessed. Modeling of column and wall pier flexural and shear strengths is examined in detail, and available models for the inelastic shear strength of columns are compared with test data.

Post-earthquake Damage Repair and Probabilistic Damage Control Approach for Reinforced Concrete Bridges

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Author : Amarjeet Saini
Publisher :
ISBN 13 :
Total Pages : 804 pages
Book Rating : 4.:/5 (93 download)

Book Synopsis Post-earthquake Damage Repair and Probabilistic Damage Control Approach for Reinforced Concrete Bridges by : Amarjeet Saini

Download or read book Post-earthquake Damage Repair and Probabilistic Damage Control Approach for Reinforced Concrete Bridges written by Amarjeet Saini and published by . This book was released on 2014 with total page 804 pages. Available in PDF, EPUB and Kindle. Book excerpt: The main objectives of the study were to develop post-earthquake repair methods using carbon fiber reinforced polymers (CFRP) and probabilistic damage control approach (PDCA) for reinforced concrete (RC) bridges. To develop repair methods, first repair objectives were defined. To define repair objectives, internal earthquake damage was quantified and correlated to a series of visible damage states (DSs). Bridge columns are designed to be the primary source of energy dissipation through nonlinear action under seismic loading and experience a wide range of apparent damage. Therefore, in the present study, DSs for bridge columns were used as a guide to define damage states for other bridge components. The degree of damage in columns depends on the earthquake level (seismic demand). Due to uncertainties in seismic demand and response, damage to bridge columns is probabilistic in nature. In the present study, in addition to bridge repair, a probabilistic damage control approach PDCA was developed for new and repaired bridge columns by incorporating the extent of lateral displacement nonlinearity defined by "Damage Index" (DI) and reliability analysis. The performance objective was defined based on predefined apparent DSs and the DSs were correlated to damage indices based on a previous study at the University of Nevada, Reno. The correlation between DI and DS was determined from a statistical analysis (resistance model) of over 140 response data measured from testing of 22 bridge column models subjected to seismic loads. To accomplish the objectives of this study, the present study was divided into seven parts. The first part was to conduct a detailed review of damage and repair methods in past earthquakes to identify gaps in repair methods. The second part was to develop practical methods to access the condition of an earthquake damaged bridge structural components in terms of apparent DS's. In the third part, repair design recommendations and design examples were developed to aid bridge engineers in quickly designing the number of CFRP layers based on the apparent DS. The fourth part was to establish a resistance model for the reliability analysis to develop a probabilistic based seismic design of bridge columns. In the fifth part, a load model was developed by conducting a large number of non-linear dynamic analyses on bridge bents. The uncertainties in ground motions, site class, bent configuration, earthquake return period were included in the analyses. In the sixth part of the study, the results of the reliability analyses were investigated, and a direct probabilistic design procedure was developed to calibrate design DI based on target reliability against failure. Finally, the PDCA methodology that was developed for conventional columns was used to extend the PDCA and reliability analysis approach to earthquake-damaged columns that have been repaired. Through this study, a new simple non-iterative method was developed for design of CFRP fabrics used in repair of concrete members. The step-by-step repair methods for bridge components that were developed as part of this study address a gap in rational and systematic repair tools that are needed subsequent to moderate and strong earthquakes. The PDCA that was developed and investigated provides design tools enabling designers and researchers to detail bridge columns for a target expected damage with an associated probability of occurrence and a reliability index.

Rapid Repair of Earthquake Damaged Reinforced Concrete Columns Using Fiber Reinforced Plastics

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Author : Zhiyuan Cheng
Publisher :
ISBN 13 :
Total Pages : 276 pages
Book Rating : 4.:/5 (458 download)

Book Synopsis Rapid Repair of Earthquake Damaged Reinforced Concrete Columns Using Fiber Reinforced Plastics by : Zhiyuan Cheng

Download or read book Rapid Repair of Earthquake Damaged Reinforced Concrete Columns Using Fiber Reinforced Plastics written by Zhiyuan Cheng and published by . This book was released on 2000 with total page 276 pages. Available in PDF, EPUB and Kindle. Book excerpt:

Qualifications for Seismic Retrofitting of Bridge Columns Using Composites: Nondestructive evaluation (NDE) development

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Author :
Publisher :
ISBN 13 :
Total Pages : 48 pages
Book Rating : 4.:/5 (318 download)

Book Synopsis Qualifications for Seismic Retrofitting of Bridge Columns Using Composites: Nondestructive evaluation (NDE) development by :

Download or read book Qualifications for Seismic Retrofitting of Bridge Columns Using Composites: Nondestructive evaluation (NDE) development written by and published by . This book was released on 1999 with total page 48 pages. Available in PDF, EPUB and Kindle. Book excerpt:

Hybrid Fiber Reinforced Concrete Incorporated with Phase Change Material

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Author : Chia-So Chuang
Publisher :
ISBN 13 :
Total Pages : 272 pages
Book Rating : 4.:/5 (914 download)

Book Synopsis Hybrid Fiber Reinforced Concrete Incorporated with Phase Change Material by : Chia-So Chuang

Download or read book Hybrid Fiber Reinforced Concrete Incorporated with Phase Change Material written by Chia-So Chuang and published by . This book was released on 2015 with total page 272 pages. Available in PDF, EPUB and Kindle. Book excerpt: To further efforts toward improvement, an innovative and durable High Performance Fiber Reinforced Cementitious Composites (HPFRCC) was developed, using hybrid steel macro-fibers with designed hook-ends, and polyvinyl alcohol micro-fibers for optimal fiber synergistic effects, crack width control, durability, and reduced maintenance and life-cycle costs for bridges. For functional performance improvements, an off-the-shelf phase change material (PCM) was utilized, optimized and incorporated into the HPFRCC as a bridge slab warmer, to improve freeze-thaw cycling durability, to reduce the use of de-icing salts, to provide improved skid resistance, and to improve safety in cold climates and to reduce traffic congestions. The goal for developing and deploying HPFRCC with controllable functional performance is to utilize new, durable cementitious composites resistant to stringent climate demands compromised of freeze-thaw cycles, de-icing salts, plastic shrinkage and drying shrinkage cracks, chloride and sulfate attacks, corrosion and scaling, and excessive abrasion/wear due to tire chains. This thesis utilized both numerical modeling and experimental. First, mechanical properties after incorporating PCM were discussed. Subsequently, destructive tests were performed in order to study the effect of adding PCM. In addition, thermal performance after incorporating PCM was also addressed as an important topic. As a result, freeze-thaw testing was performed in order to study PCM performance. Numerical modeling regarding material mechanical properties was proposed and compared with experimental data. Numerical modeling regarding concrete composite thermal performance was also studied. Lastly, concrete interior temperature, mechanical properties and concrete composite residual capacity were discussed. In chapter 3, several experimental tests were performed in order to study the behavior of hybrid fiber reinforced concrete with PCM and to verify the validity of the theoretical model. Experimental tests can be divided into two categories. One is a destructive test; where concrete composite compressive strength, tensile strength and ductile capacity can be determined. The other category is a freeze-thaw test where concrete composite freeze-thaw resistance can be studied. In chapter 4, a new crack bridging model accounting for slip-softening interfacial shear stress was proposed for randomly distributed and randomly oriented fibers after PCM were added, based on a micromechanics analysis of single fiber pull-out. The concrete composite bridging stress versus a crack mouth opening displacement (CMOP) curve and associated fracture energy were theoretically determined. In addition, a constant interfacial shear stress model was also proposed in order to compare this with a slip softening interfacial shear stress model. By applying the proposed model on various concrete composites, including 5% PCM and 7% PCM hybrid fiber reinforced concrete, the present model can well describe the slip-softening behavior during fiber pull-out. In chapter 5, the new proposed slip-softening model was used to predict the ultimate tensile stress of a single fiber. Maximum fiber debonding stress and fiber pull-out stress was determined based on slip softening interfacial shear stress. By applying the rule of mixture, maximum fiber debonding and pull-out stress, the maximum tensile stress of a concrete composite was able to be predicted when subjected to three point bending test. In chapter 6, PCM concrete composite interior temperature was modeled and compared with concrete without PCM after being subjected to freeze-thaw cycle. With PCM inside of concrete, interior temperature can be controlled. In preceding chapters, microcracks would be generated inside of the concrete and eventually become larger cracks by going through the freeze-thaw process. The aim of this chapter was to find a temperature gradient inside of concrete using an enthalpy method and specific heat capacity method to solve moving boundary problems. Numerical efficiency from both the enthalpy method and specific heat capacity method were also compared. Two different layouts of how PCM were incorporated into a concrete mix and were discussed in order to determine the efficiency of each design. In chapter 7, concrete mechanical properties after being subjected to freeze-thaw cycle were modeled. In addition, concrete composite residual capacity after freeze-thaw process was also determined based on a stress-strain relationship. With PCM inside of concrete, interior temperature can be controlled. However, the relationship between concrete structure mechanical properties, number of freeze-thaw cycles and freeze-thaw temperature differences also needs to be determined. After a correlation is found between concrete mechanical properties, number of freeze-thaw cycles and temperature difference, the stress-strain relationship can then be determined by using damaged concrete mechanical properties. A Constitutive relationship can be derived based on thermodynamic theory. Elastic damage and plastic damage were both evaluated. Once the stress-strain relationship is obtained, concrete residual life and residual durability can be stimated after going through a freeze-thaw action. Normal concrete was also compared with PCM concrete. The aim of this chapter was to develop a damage model that account for concrete structure strength, number of freeze-thaw cycles and freeze-thaw temperature differences. Concrete composite residual capacity was also estimated and derived from free energy potential function.

Shear Strength and Deformability of RC Bridge Columns Subjected to Inelastic Cyclic Displacements

Download Shear Strength and Deformability of RC Bridge Columns Subjected to Inelastic Cyclic Displacements PDF Online Free

Author : Mark Aschheim
Publisher :
ISBN 13 :
Total Pages : 124 pages
Book Rating : 4.:/5 (318 download)

Book Synopsis Shear Strength and Deformability of RC Bridge Columns Subjected to Inelastic Cyclic Displacements by : Mark Aschheim

Download or read book Shear Strength and Deformability of RC Bridge Columns Subjected to Inelastic Cyclic Displacements written by Mark Aschheim and published by . This book was released on 1992 with total page 124 pages. Available in PDF, EPUB and Kindle. Book excerpt: