Repair of prestressed concrete bridge girders for shear

Lemay, Lionel.

January 1986

No description available.

Prestressed concrete construction

Shear (Mechanics)

Girders

Prestressed concrete beams

Behavior Of Partially Prestressed Concrete T-Beams Having Steel Fibers Over Partial Or Full Depth - An Experimental And Analytical Study

Thomas, Job

09 1900

No description available.

Concrete Beams

Steel - Concrete Beams

Steel Fiber Reinforced Concrete (SFRC)

Prestressed Concrete Beams

Test Beams

Fiber Reinforced Concrete

Reinforced Concrete Beams

Prestressed Concrete Beams T-beams

Steel Fibers

Prestressed Beams

Fiber Reinforced Concrete

Structural Concrete

Structural Engineering

Improving efficiency and effectiveness in the design, manufacturing and construction of the beam and block slab systems

Khuzwayo, Bonga PraiseGod

January 2015

Submitted in fulfillment for the Master of Engineering, Department of Civil Engineering and Surveying, Durban University of Technology. Durban. South Africa, 2015. / Beam and block slab systems have become a preferred suspended flooring technology in South Africa. Their structural efficiency and relatively low cost makes them suitable for low to medium cost developments. Like all other structural components, they are required to demonstrate sound structural integrity. Concerns were raised by some manufacturers and users in Durban (South Africa) about (a) the lack of basic technical information which makes it difficult to identify methods of improving efficiency and effectiveness of these flooring systems in general, (b) the efficiency and effectiveness of concrete masonry rebated filler blocks - with respect to the load carrying capacity and protecting the structural topping from fire, (c) what constitutes acceptable quality of a deliberately roughened precast concrete surface, (d) interfacial tensile bond strength of special connections and (e) an alternative rib that can span 5 metres without temporary props. These issues were investigated by the student. Thus, this project aimed at improving the structural efficiency and effectiveness in designing, manufacturing and constructing beam and block slab systems was undertaken in Durban, South Africa, between 2012 and 2013. Pilot studies (involving questionnaires), interviews with manufacturers, site visits, and testing of non-structural and structural components were also undertaken. The first aim (in order to address concern (a)) was to provide users of beam and block slab systems with basic technical information about the possible ways to improve efficiency and effectiveness in the design, manufacturing and construction of beam and block slab systems by undertaking an exploratory (pilot) study to better understand users of these systems concerns. The second aim (to address concern (b)) was to investigate, by conducting a series of strength to weight ratio tests, how efficient or inefficient these filler blocks are, examine the structural integrity with respect to the integrity of the manufacturing methodologies and the product thereof, and formulate a method to quantify the fire-resistivity of concrete masonry rebated filler blocks to the structural topping with respect to confining fire. The third aim (to address concern (c)) was to determine what constituted acceptable quality of a deliberately roughened precast concrete surface through a literature review and by conducting a survey to learn about the construction methodologies used by manufacturers. Site visits were undertaken to validate information given by the contractors. The fourth aim (to address concern (d)) was to determine interfacial tensile bond strength through physical testing of deliberately roughened concrete ribs which are sometimes used in special connections. The fifth aim (to address the last concern (e)) was to make an assessment by undertaking a basic comparison study between one local beam and block slab system that uses a shallow rectangular precast pretensioned rib to beam and block slab systems used in the United Kingdom and propose an ideal section (precast pretensioned rib) that spans up to 5 metres without temporary props. With respect to the first aim, it was found that the lack of technical knowledge, including access to critical information about the design philosophy, manufacturing and construction standards of these flooring systems leads to reluctance in selecting them. The outcome of the second aim is that all concrete masonry rebated filler blocks tested were found to be effective because they supported more than the required construction load but some were shown to be inefficient as more materials, such as binders, are wasted in producing over-strength filler blocks and also, undertaking trial mix designs and the testing of samples prior to batch production will reduce costs. A method is formulated in the thesis that could also show that concrete masonry rebated filler blocks provide significant protection to the structural topping thereby preventing fire progression. With respect to the third aim, although a broom or brush is effective in providing a surface roughness (Rz) of 3 mm, it is not always efficient when considering factors like the variation in uniformity, appearance of laitance and roughening frequency, which are not addressed by the South African codes. The outcome of the fourth aim is that connections should be designed such that they do not rely purely on the tensile bond strength but through reinforcing bars (or ties) taking the full tension load causing delamination. With respect to the fifth aim, a basic comparison study indicates that T-section beams are more efficient than common rectangular ribs (±150 mm wide x ±60 mm deep) since they can eliminate completely the use of temporary props for spans of up to 4.51 m. Consequently, further research is underway to design an inverted T-section rib by using high strength precast pretensioned concrete that can span up to 5 m without using temporary props.

Prestressed concrete beams--Testing

Concrete slabs--Design and construction

Concrete slabs--Testing

Concrete masonry

Construction industry

Deformation Capacity and Moment Redistribution of Partially Prestressed Concrete Beams

Rebentrost, Mark

January 2004

Ductility is a measure of the ability of a material, section, structural element or structural system to sustain deformations prior to collapse without substantial loss of resistance. The Australian design standard, AS 3600, imposes minimum ductility requirements on structural concrete members to try to prevent premature non-ductile failure and hence to ensure adequate strength and ductile-type collapse with large deflections. The requirements also enable members to resist imposed deformation due to differential settlement, time effects on the concrete and temperature effects, whilst ensuring sufficient carrying capacity and a safe design. Current AS 3600 requirements allow a limited increase or reduction in elastically determined bending moments in critical regions of indeterminate beams, accommodating their ability to redistribute moment from highly stressed regions to other parts of the beam. Design moment redistribution limits and ductility requirements in AS 3600 for bonded partially prestressed beams are a simple extension of the requirements for reinforced members. The possibility of premature non-ductile failure occurring by fracture of the reinforcement or prestressing steel in partially prestressed members has not adequately addressed. The aim of this research is to investigate the overload behaviour and deformation capacity of bonded post-tensioned beams. The current ductility requirements and design moment redistribution limits according to AS 3600 are tested to ensure designs are both safe and economical. A local flexural deformation model based on the discrete cracked block approach is developed to predict the deformation capacity of high moment regions. The model predicts behaviour from an initial uncracked state through progressive crack development into yielding and collapse. Local deformations are considered in the model using non-linear material laws and local slip behaviour between steel and concrete interfaces, with rigorous definition of compatibility in the compression and tension zones. The model overcomes limitations of past discrete cracked block models by ensuring compatibility of deformation, rather than strain compatibility. This improvement allows the modeling of members with multiple layers of tensile reinforcement and variable depth prestressing tendons having separate material and bond properties. An analysis method for simple and indeterminate reinforced and partially prestressed members was developed, based on the proposed deformation model. To account for the effect of shear in regions of high moment and shear present over the interior supports of a continuous beam, a modification to the treatment of local steel deformation in the flexural model, based on the truss analogy, was undertaken. Secondary reactions and moments due to prestress and continuity are also accounted for in the analysis. A comparison of past beam test data and predictions by the analysis shows the cracking pattern and deformation capacity at ultimate of flexural regions in reinforced and partially prestressed members to be predicted with high accuracy. The analysis method accurately predicts local steel behaviour over a cracked region and deformation capacity for a wide range of beams which fail either by fracture of steel or crushing of the concrete. A parametric study is used to investigate the influence of different parameters on the deformation capacity of a typical negative moment region in a continuous beam. The structural system consists of a bonded post-tensioned, partially prestressed band beam. The primary parameters investigated are the member height and span-to-depth ratio; relative quantity of reinforcing and prestressing steel; material properties and bond capacity of the steels; and lastly the compression zone properties. Results show that the effects of the various parameters on the overload behaviour of partially prestressed beams follow the same trends as reinforced beams. A new insight into the local steel behaviour between cracks is attained. The deformation behaviour displays different trends for parametric variations of the local bond capacity, bar diameter and crack spacing, when compared to past analytical predictions from comparable studies. The discrepancy in findings is traced back to the definition of the plastic rotation capacity and the sequencing of the yielding of the steels. Compared to the other local deformation models, the current model does not assume a linear distribution of strain at a crack. The current findings highlight an important difference between predicted behaviours from different deformation compatibility requirements in local deformation models which has not yet been discussed in the literature. The local deformation model evaluates the relationship between maximum steel strain at a crack and average steel deformation over a crack spacing for the entire loading history. The total steel percentage, hardening properties of the steel and concrete strength are shown by the model to have the greatest effect on these steel strain localisation factors. Section analysis, as currently used in design, can be improved with the proposed simplification of the relationships to identify and quantify the effects of steel fracture on deformation capacity and strength. The numerical effort required to simulate the overload behaviour of practical beam designs with multiple reinforcement elements and a prestressing tendon are currently too great to be used in an extensive numerical study. The numerically more efficient smeared block approach is shown to accurately predict the ultimate carrying capacity of prestressed beams failing by crushing of the concrete. Consequently, this method is adopted to study the allowable limits of moment redistribution in the present investigation, Simplified relationships of the steel strain localisation factors evaluated in the parametric study of deformation capacity is used to predict maximum steel strains and premature failure. The limits of moment redistribution in bonded, post-tensioned partially prestressed band beams are explored by comparing the design load and predicted carrying capacity, for different section ductilities and design moment redistribution. In addition, the effects of different concrete strengths, up to 85 MPa, along with as three reinforcing and prestressing steel ductilities are quantified and compared to current Australian and international design requirements. Limitations in the carrying capacity are investigated for different reinforcement and prestress uniform elongation capacities. More than one thousand beam simulations produce results showing that current design moment redistribution and ductility requirements in the Australian design code for concrete structures (AS 3600) are sufficient for normal strength concretes (less than 50 MPa). A suggestion for design moment redistribution limits, section ductility requirements and steel ductility limits is made for members constructed from higher strength concretes. A special high steel ductility class is proposed for both the reinforcement and prestressing steel to allow moment redistribution in higher strength concrete. No moment redistribution is proposed for members reinforced with low ductility (Class L) steel. An increase of the current elongation limit of Class L steel from 1.5 % to 2.5% is suggested to ensure strength and safety. An increase in the current ductility requirements from fsu/ fsy=1.03 and elongation equal to 1.5% to fsu/fsy=1.05 and 2.5% elongation for low ductility Class L steel is suggested to ensure strength and safety. / Thesis (Ph.D.)--Civil and Environmental Engineering, 2004.

Stability of precast prestressed concrete bridge girders considering imperfections and thermal effects

Hurff, Jonathan B.

30 June 2010

The spans of precast prestressed concrete bridge girders have become longer to provide more economical and safer transportation structures. As the spans have increased, so has the depth of the girders which in turn have increased the slenderness of the girders. Slenderness in a beam or girder would increase the likelihood that a stability failure would occur. Stability failures could pose a danger to construction personnel due to the sudden nature in which a stability failure would occur. Furthermore, stability failures of prestressed concrete girders during construction would cause a detrimental economic impact due to the costs associated with the failure of the girder, the ensuing construction delays, damage to construction equipment and potential closures to highways over which the bridge was being constructed. An experimental and analytical study was performed to determine the stability behavior of prestressed concrete beams. Two stability phenomenons were investigated: (1) lateral-torsional buckling and (2) global stability. An emphasis was placed on the effects of initial imperfections on the stability behavior; the effect elastomeric bearing pads and support rotational stiffness was investigated. The experimental study involved testing six rectangular prestressed concrete beams for lateral-torsional buckling, a PCI BT-54 for thermal deformations and the same PCI BT-54 for global stability. The 32-ft. long rectangular beams were 4-in. wide and 40-in. deep. The PCI BT-54 had a 100-ft. long span. A material and geometric nonlinear, incremental load analysis was performed on the six rectangular beams. The nonlinear analyses matched the experimental load versus lateral displacement and load versus rotation behavior, and the analysis predicted the experimental maximum load within an error of 2%. The nonlinear analysis was extrapolated to several different initial imperfection conditions to parametrically study the effect of initial lateral displacement and initial rotation on the inelastic lateral-torsional buckling load. A simplified expression for lateral-torsional stability of beams with initial imperfections was developed. The data from the parametric study were used to develop reduction parameters for both initial sweep and initial rotation. The rollover stability behavior of the PCI BT-54 was investigated experimentally, and it was found that support end rotations and the elastomeric bearing pads had an adverse effect on the global stability. The nonlinear analysis was employed with the addition of a bearing pad model. It was found that the behavior was sensitive to the bearing pad stiffness properties and the assumption of uniform bearing. From the research, it was apparent that rollover stability was the controlling stability phenomenon for precast prestressed concrete bridge girders, not lateral-torsional buckling.

Experimental techniques

Nonlinear geometric analysis

Structural stability

Inelastic behavior

Precast concrete

Bridges

Concrete bridges

Prestressed concrete beams

Modelo de gestão para obras de arte especiais : pontes e viadutos / Model of management for special structures : bridges and viaducts

Pregeli Neto, Antonio

02 August 2006

Orientador: Vladimir Antonio Paulon / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Civil, Arquitetura e Urbanismo / Made available in DSpace on 2018-08-13T11:14:39Z (GMT). No. of bitstreams: 1 PregeliNeto_Antonio_M.pdf: 3909884 bytes, checksum: 410b6d25a48bfd9306620ba57294b3d0 (MD5) Previous issue date: 2006 / Resumo: A aplicação de modelos de gestão na construção civil se mostra uma tendência, buscando minimizar riscos em empreendimentos e criar um diferencial competitivo. Neste contexto, o presente trabalho teve por objetivo desenvolver e implantar um modelo de gestão para confecção de vigas pré-moldadas, verificando possíveis ganhos em termos de custo, prazo e qualidade. A metodologia adotada foi o estudo de caso, nas obras de uma ponte. O modelo de gestão desenvolvido dividiu a gestão do empreendimento em três áreas de atuação, sendo Gestão de Engenharia, Gestão de Suprimentos e a Gestão de Recursos. Na Gestão de Engenharia observou-se o parcial atendimento às expectativas no macro planejamento e na metodologia de gestão de informações, no controle de projetos; já as metodologias construtivas mostraram-se adequadas, a exceção da cura e do transporte das vigas; na gestão da segurança do trabalho e meio ambiente mostrou-se eficiente a localização de riscos, porém ineficiente o controle de acidentes de trabalho. A Gestão de Suprimentos foi eficiente no controle de custos, embora partes das análises tenham sido prejudicadas dada a escolha equivocada de alguns dos coletores de custo; no processo de contratação e compras os indicadores adotados se mostraram superficiais para a avaliação de desempenho. A Gestão de Recursos teve um bom desempenho, refletido nos índices de custos. Em geral, o empreendimento mostrou que os indicadores adotados para a avaliação do desempenho do modelo de gestão apontam um rendimento satisfatório para tempo e custo, e não conclusivo na qualidade. Concluiu-se que, embora não se possa afirmar que a aplicação do modelo de gestão fora o único responsável pelo sucesso parcial do empreendimento, certamente este contribuiu significativamente para tal. / Abstract: The application of management models in the civil construction is a new trend which searches to minimize risks in workmanships and to create a competitive differential. In this context, the objective of the present work was to develop and to implant a model of management for confection of precast prestressed beams, verifying possible improvements in costs, schedule and quality. The adopted methodology was the case study, in a bridge workmanship. The developed model of management divided the enterprise in three areas of performance, being Management of Engineering, Supply Management and Management of Resources. The Management of Engineering had a partial attendance to the expectations in the macro planning, the methodology of management of information was observed, in the control of projects; the constructive methodologies was adequate, in exception of the curing and the transport of the beams; the management of the work security and environment was efficient in the control of industrial accidents but inefficient to localize risks. The Supply Management was efficient in cost control, but parts of the analyses were harmed because of a mistake in the choice of some cost collectors; in the purchase process the pointers were superficial for the performance evaluation. The Management of Resources had a good performance, reflected in costs. In general, this job showed that the adopted pointers for the performance evaluation of the management model were satisfactory considering time and cost, but not conclusive in the quality. The conclusion is it cannot affirm that the application of the management model is the responsible one for the partial success of the workmanship, certainly this contributed significantly for such. / Mestrado / Edificações / Mestre em Engenharia Civil

Gestão de negocios

Obras públicas

Pontes de concreto

Pontes estaiadas

Vigas de concreto protendido

Model of management

Precast prestressed concrete beams

Bridges

Viaducts

Shear Testing of Prestressed High Performance Concrete Bridge Girders

Haines, Robert Anthony

19 May 2005

This report details the design and construction of an AASHTO Type IV prestressed girder and a PCI BT-56 prestressed girder. It also details the shear testing and shear performance of the BT-56 girder. The results are compared with results from previous research dating back to 1986. Finally, all research was compared with the AASHTO Standard (2002), AASHTO LRFD (1998) and AASHTO LRFD (2004) Specifications to examine thier overall accuracy in predicting shear strengths.

Shear

Concrete

Prestressed

Girders

High performance

Shear (Mechanics) Testing

Bridges, Concrete Testing

Girders Testing

Prestressed concrete beams Testing

Prestressed concrete Testing

Experimental and analytical investigations of the thermal behavior of prestressed concrete bridge girders including imperfections

Lee, Jonghang

07 July 2010

An experimental and analytical study was conducted on a BT-63 prestressed concrete girder to investigate the thermal effects on the girder. A 2D finite element heat transfer analysis model was then developed which accounted for heat conduction, convection, radiation, and irradiation. The solar radiation was predicted using the location and geometry of the girder, variations in the solar position, and the shadow from the top flange on other girder surfaces. The girder temperatures obtained from the 2D heat transfer analysis matched well with the measurements. Using the temperatures from the 2D heat transfer analysis, a 3D solid finite element analysis was performed assuming the temperatures constant along the length of the girder. The maximum vertical displacement due to measured environmental conditions was found to be 0.29 inches and the maximum lateral displacement was found to be 0.57 inches. Using the proposed numerical approach, extremes in thermal effects including seasonal variations and bridge orientations were investigated around the United States to propose vertical and transverse thermal gradients which could then be used in the design of I-shaped prestressed concrete bridge girders. A simple beam model was developed to calculate the vertical and lateral thermal deformations which were shown to be within 6% of the 3D finite element analyses results. Finally, equations were developed to predict the maximum thermal vertical and lateral displacements for four AASHTO-PCI standard girders. To analyze the combined effects of thermal response, initial sweep, and bearing support slope on a 100-foot long BT-63 prestressed concrete girder, a 3D finite element sequential analysis procedure was developed which accounted for the changes in the geometry and stress state of the girder in each construction stage. The final construction stage then exposed the girder to thermal effects and performed a geometric nonlinear analysis which also considered the nonlinear behavior of the elastomeric bearing pads. This solution detected an instability under the following conditions: support slope of 5¡Æ and initial sweep of 4.5 inches.

Solar radiation

Prestressed concrete girder

Girder stability

Thermal effect

Heat transfer

Finite element

Concrete bridges

Concrete beams

Prestressed concrete beams

Strains and stresses

[en] INTERACTIVE GRAPHICS TOOL FOR SERVICEABILITY LIMIT STATE STRESS CHECK OF PRESTRESSED CONCRETE BEAMS WITH POST-TENSIONED BONDED TENDONS / [pt] FERRAMENTA GRÁFICO-INTERATIVA DE VERIFICAÇÃO DE TENSÕES NO ESTADO LIMITE DE SERVIÇO DE VIGAS PROTENDIDAS COM PÓS-TRAÇÃO ADERENTE

PEDRO KAJ KJELLERUP NACHT

16 September 2016

[pt] Este trabalho apresenta o desenvolvimento de uma ferramenta computacional gráfico-interativa para a verificação de vigas de concreto protendido com pós-tração aderente ao estado limite de serviço, de acordo com a norma brasileira NBR 6118:2014. A ferramenta é uma extensão (addin) para o Autodesk Robot Structural Analysis Professional , que serve como plataforma de modelagem estrutural. A partir de dados fornecidos pelo usuário através de uma interface gráfica, o programa desenvolvido calcula todas as perdas de protensão que ocorrem ao longo da vida-útil da estrutura, assim como os carregamentos equivalentes à protensão durante este período. O trabalho apresenta os métodos de cálculo tradicionais das perdas imediatas e diferidas, obtidos da NBR 6118, e as modificações que tiveram que ser feitas para permitir um cálculo incremental. Exemplos de utilização do programa e dos cálculos necessários também são apresentados e comprovam, pelos bons resultados obtidos, o acerto na escolha da metodologia escolhida. Como resultado, a ferramenta apresenta duas saídas: uma planilha contendo os esforços e as tensões atuantes na viga ao longo de sua vida-útil e verificações destes valores em relação aos limites estabelecidos para o estado limite de serviço; e o modelo estrutural no Robot apresenta os carregamentos equivalentes da protensão. O usuário pode então adotar estes carregamentos em demais cálculos da estrutura, enquanto a planilha pode ser utilizada para verificar com facilidade se a protensão atende às condições de serviço. / [en] This work presents the development of an interactive graphics computational tool for the verification of prestressed concrete beams with posttensioned bonded tendons to the serviceability limit state stress check according to the Brazilian code NBR 6118:2014. The tool is an add-in for Autodesk Robot Structural Analysis Professionalr, which serves as a structural modeling platform. With data supplied by the user through a graphics user interface, the program here developed calculates all relevant prestress losses that occur throughout the structure s life-cycle, along with the prestressing s equivalent loads during this period. The traditional calculation methods, obtained in the NBR 6118, are presented along with the modifications which had to be implemented in order to allow for incremental loss calculations. Usage examples and the necessary calculations are presented and, through the results obtained, validate the adopted methodology. As results, the program presents two outputs: a spreadsheet containing the resultant forces and stresses and a check of these values with respect to the permissible stresses in the serviceability limit state; and the Robot model presents the prestress equivalent loads. The user may then use these loads in additional calculations. The spreadsheet may be used to easily check if the prestress is sufficient with respect to serviceability conditions.

[pt] VIGAS DE CONCRETO PROTENDIDO

[en] PRESTRESSED CONCRETE BEAMS

[pt] ESTADO LIMITE DE SERVICO

[pt] ABNT NBR 6118

POST-FIRE ASSESSMENT OF PRESTRESSED CONCRETE BRIDGES

Tzu-chun Tseng (11632921)

02 November 2021

<div>Several truck fires have occurred in recent years involving bridges with reinforced and prestressed concrete components. If the fire burns for a significant period of time (15 minutes or more), bridge inspectors and engineers must determine if the exposure to elevated temperature has reduced the strength and serviceability of the concrete components. Little guidance is available, however, correlating the results of field inspections with the actual condition of the reinforced/prestressed concrete elements. This dissertation presents the results of a research program conducted to develop rational guidance for inspectors and engineers to evaluate concrete bridge elements after a fire event and help them make informed decisions regarding the future status of the bridge. <br></div><div><br></div><div>The research program includes tests on portions of a reinforced concrete deck and three full-scaled AASHTO Type I prestressed girders acquired from a decommissioned highway bridge. In addition, six pretensioned concrete prismatic beam specimens with varying levels of prestress were fabricated and tested. The specimens had cross-sectional dimensions of 8 in. by 8 in. and were designed to simulate the bottom flanges of common I-shaped prestressed concrete bridge girders. The deck specimens and four (of the six) concrete beam specimens were subjected to elevated temperatures using radiation-based heaters. Two (of the six) prismatic specimens built in the laboratory were subjected to a hydrocarbon pool fire test conducted in the field for using approximately 135 gallons of kerosene. The concrete temperature profiles and the deformations of the specimens were measured using thermocouple trees and displacement transducers, respectively. Concrete samples were also cored and examined using various methods (DSC and SEM) to correlate microstructure degradation (microcracking, dehydration of C-S-H, decomposition of calcium hydroxide, etc.) with the measured temperatures through the depth of the specimens. <br></div><div><br></div><div>To evaluate the residual loading-carrying capacities of prestressed concrete girders after being subjected to fire, a hydrocarbon pool fire test was performed on two decommissioned AASHTO Type I girders in the field. Load tests were then conducted on the prestressed girders under both ambient and post-fire conditions. After structural testing, material tests were also conducted on concrete cores taken from the girders to evaluate the post-fire concrete microstructure alteration. Furthermore, three-dimensional finite element models were developed to predict the residual load-carrying capacities and overall structural responses of prestressed concrete bridge girders after being exposed to fire. Results from the numerical models generally agree favorably with experimental observations and provide insights into the behavior of the specimens. A parametric study was performed using the benchmarked finite element models to expand the database and establish design recommendations further. Capacity influence lines for load-carrying capacities and structural stiffness were developed and discussed.</div><div><br></div><div>Based on the results from this research, guidelines for the post-fire assessment of prestressed concrete bridges are included in this dissertation along with a step-by-step checklist. Bridge inspectors can infer the extent of damage to prestressed concrete bridge girders in the event of a fire and develop a post-fire assessment plan cognizant of the findings. In most cases, no more than 1.0 in. of the concrete from the exposed surface undergoes material damage / deterioration due to loss of CH, cracking, and spalling. The impact on the strength of prestressed concrete girders is relatively minor based on experimental results. Their initial stiffness, however, will likely be reduced. <br> </div><br>

Structural Engineering

Bridge Deck

Calcium hydroxide

Differential Scanning Calorimetry

fire exposure

microstructural analysis

Numerical analysis

Prestressed concrete beams

scanning electron microscopy