Evaluation of Concrete Bridge Decks Comprising Twisted Steel Micro Rebar

Hebdon, Aubrey Lynne

12 March 2021

The objective of this research was to investigate the effects of twisted steel micro rebar (TSMR) fibers on 1) the mechanical properties of concrete used in bridge deck construction and 2) the early cracking behavior of concrete bridge decks. This research involved the evaluation of four newly constructed bridge decks through a series of laboratory and field tests. At each location, one deck was constructed using a conventional concrete mixture without TSMR, and one was constructed using the same conventional concrete mixture with an addition of 40 lb of TSMR per cubic yard of concrete. Regarding laboratory testing, the conventional and TSMR beam specimens exhibited similar average changes in height after 4 months of shrinkage testing. The electrical impedance measurements did not indicate a notable difference between specimens comprising concrete with TSMR and those comprising conventional concrete. Although no notable difference in behavior between conventional and TSMR specimens was apparent before initial cracking, the toughness of the TSMR specimens was substantially greater than that of the conventional concrete specimens. Regarding field testing, sensors installed in the bridge decks indicated that the addition of TSMR does not affect internal concrete temperature, moisture content, or electrical conductivity. The average Schmidt rebound number varied little between the TSMR decks and conventional decks; therefore, the stiffness of the TSMR concrete was very similar to that of conventional concrete. Distress surveys showed that the conventional decks exhibited notably more cracking than the TSMR decks. The TSMR fibers exhibited the ability to limit both crack density and crack width. For all of the decks, chloride concentrations increased every year as a result of the use of deicing salts on the bridge decks during winter. However, the chloride concentrations for samples collected over cracked concrete increased more rapidly than those for samples collected over non-cracked concrete. Although TSMR fibers themselves do not directly affect the rate at which chloride ions penetrated cracked or non-cracked concrete, the fibers do prevent cracking, which, in turn, limits the penetration of chloride ions into the decks. Therefore, the use of TSMR would be expected to decrease the area of a bridge deck affected by cracking and subsequent chloride-induced corrosion damage and thereby increase the service life of the bridge deck.

chloride concentration

concrete bridge deck

cracking

fiber-reinforced concrete

twisted steel micro rebar

Engineering

Influence of steel fibres on response of beams

Belghiti, Moulay El Mehdi.

January 2007

No description available.

Metal fibers.

Concrete beams -- Testing.

Fiber-reinforced concrete -- Testing.

Reinforcing bars.

Role of Force Resultants Interaction on Fiber Reinforced Concrete

Chan, Titchenda

01 January 2014

Ultra-high performance concrete (UHPC) is a recently developed concrete gaining a lot of interest worldwide, and a lot research has been conducted to determine its material properties. UHPC is known for its very high strength and high durability. Association Francaise de Genie Civil (AFGC) has defined UHPC as a concrete exhibiting compressive strength greater than 150 MPa (22 ksi). To utilize the full compressive strength of UHPC, complementary tension reinforcement is required. A recent research study to find light weight yet high strength alternative deck systems for Florida movable bridges demonstrated that a composite UHPC and high strength steel (HSS) reinforcement deck system is a viable alternative. However, failure modes of the deck system observed during experimental testing were shear failures rather than flexural failures. Interestingly, the shear failures were ductile involving large deformations and large sectional rotations. The purpose of this research is to quantify the sensitivity of UHPC structural member mechanical response to different shear and normal stress demands, and investigate the underlying failure modes. An experimental investigation on small-scale prisms without reinforcement, prisms reinforced with ASTM Grade 60 steel, and prisms reinforced with high strength steel was carried out to capture load-deflection behavior as well as modes of failure of the UHPC specimens. Numerical analysis based on modified compression field theory (MCFT) was developed to verify experimental results at the section level, and further verification using continuum methods was performed using MCFT/DSFM (disturbed stress field method) based finite element analysis software (VecTor2). Results from the numerical analysis could reasonably predict the load-displacement as well as the failure modes of the experimental specimens. Obvious flexural failure was observed on unreinforced UHPC specimens where wide crack opening gradually widened at the bottom fiber of the concrete to the loading position. Whereas UHPC-Grade 60 steel specimens experienced ductile flexural failure with similar wide crack opening after the rebar yielded. On the other hand, UHPC-MMFX specimens largely failed in shear from a diagonal tension crack and crush of concrete top fiber.

Civil Engineering

Engineering

Structural Engineering

Shear Failure of Steel Fiber and Bar Reinforced Concrete Beams Without Stirrups : Predictions based on Nonlinear Finite Element Analyses

Andersson, David

January 2022

Shear failure in concrete beams are often brittle in nature and potentially dangerous without adequatereinforcing measures. In design of concrete, it is commonly recommended to install transversalreinforcement along the shear span to induce a more ductile structural response, improving the shearcapacity all together and providing sufficient warning prior to collapse. However, it is more frequentlybeing assessed whether analogous performance can be achieved in fiber reinforced concrete beamswithout stirrups, and multiple attempts in literature confirm that it is possible. This alternative technologyintroduces need for better understanding of the modeling aspects of FRC in numerical simulations, as it isbecoming more common for engineers to resort to the finite element method in quality assurance ofstructures.In this thesis, the possibility of predicting shear failure numerically in simply supported fiber reinforcedconcrete beams with flexural bar reinforcement but without stirrups was investigated by means ofnonlinear finite element analysis, using the software package ATENA 2D Engineering. The ultimate aimwas to, as accurately as possible by means of numerical analyses on representative FE-models, replicatethe results from physical three-point-bending tests on simply supported FRC beams of various sizesperformed by Minelli et al. (2014). These beams were merely equipped with flexural reinforcement andexhibited shear failure.This thesis revolved around development and comparative assessment of material models for FRC basedon the smeared crack approach, adopting two different strategies: (1) The first strategy was to calibratematerial parameters based on results from 3PBT on notched FRC beams that were carried out prior totesting of the reinforced FRC beams, as reported by Minelli et al. (2014). Nonlinear finite element analysiswas used on representative FE-models for the notched 3PBT specimens, from which material parameterswere obtained iteratively by employing inverse analysis methods proposed by Červenka Consulting s.r.o.(2). The second strategy comprised of utilizing recommended constitutive relations from designrecommendations in SS812310 and RILEM TC 162-TDF. All of the constructed material models werefinally coupled with the FE-models that represented the beams with flexural reinforcement for evaluationof their performance based on their consistency with experiment data.It was found that the material models that were generated from inverse analysis in general would haveyielded successful predictions for the occurrence of shear failure in the reinforced FRC beams, providedthat the governing post-cracking residual tensile parameters were processed with respect to relevantassumptions as to describe uniaxial tensile behavior. However, although it was possible to utilize theproposed calibration method to replicate the load-displacement data for the notched 3PBT specimens withsufficient conformity, it was not possible to arrive at only one unique solution. Instead, multiple outcomescould be obtained based on the initial choice for the input value of the uniaxial tensile strength, leading tothe conclusion that experience and the engineering judgment of the user is of high importance whenadopting this method.Regarding the material models that were derived from constitutive relations in design recommendations,satisfactory estimates for the shear capacity could be obtained from the FE-models that were based onrecommendations by RILEM. The models that were based on SS812310, on the other hand, demonstratedover-stiff behavior and they were unable to provide accurate graphical visualizations of characteristicshear cracking, although the obtained load bearing capacity overall matched the experiment data in caseswhen size effects seemingly had a minor influence. An important observation from the comparison ofthese material models was that the initial drop in tensile strength during crack initiation within an elementis crucial in modeling of FRC, as it accounts for a more realistic behavior through a gradual transitionfrom aggregate bridging mechanisms of PC to the added fiber bridging mechanisms of FRC. Forsituations with high residual tensile strengths in relation to tensile strength at crack initiation, theguidelines in SS812310 become less practical for predicting shear failure by means of NLFEA.

Nonlinear finite element analysis

Shear failure

Fiber reinforced concrete beams

ATENA

Engineering and Technology

Teknik och teknologier

Flexural And Tensile Properties Of Thin, Very High-Strength, Fiber-Reinforced Concrete Panels

Roth, Michael Jason

15 December 2007

This research was conducted to characterize the flexural and tensile characteristics of thin, very high-strength, discontinuously reinforced concrete panels developed by the U.S. Army Engineer Research and Development Center. Panels were produced from a unique blend of cementitous material and fiberglass reinforcing fibers, achieving compressive strength and fracture toughness levels that far exceeded that of typical concrete.The research program included third-point flexural experiments, novel direct tension experiments, implementation of micromechanically based analytical models, and development of finite element numerical models. The experimental, analytical, and numerical efforts were used conjunctively to determine parameters such as elastic modulus, first-crack strength, post-crack modulus and fiber/matrix interfacial bond strength. Furthermore, analytical and numerical models implemented in the work showed potential for use as design tools in future engineered material improvements.

micromechanical properties

tensile properties

flexural properties

fiber reinforced concrete

high-strength concrete

STRUCTURAL INVESTIGATION OF A FIBER REINFORCED PRECAST CONCRETE BOX CULVERT

SCHWARTZ, CHRIS J.

26 September 2005

No description available.

Engineering, Civil

Fiber reinforced concrete

Precast concrete box culvert

Conspan

Polypropylene monofilament fibers

Behavior of plain and steel fiber reinforced concrete under multiaxial stress

Tawana, Siyd S.

January 1995

No description available.

Engineering, Civil

Multiaxial Stress

Steel Fiber Reinforced Concrete

Hydrostatic Compression

Conventional Triaxial Compression

Simple Shear

[en] CREEP AND MECHANICAL PROPERTIES OF CEMENTITIOUS COMPOSITES REINFORCED WITH STEEL AND POLYPROPYLENE FIBER / [pt] FLUÊNCIA E PROPRIEDADES MECÂNICAS DE COMPÓSITOS CIMENTÍCIOS REFORÇADOS COM FIBRA DE AÇO E POLIPROPILENO

VICTOR NOGUEIRA LIMA

10 January 2020

[pt] A fluência em compósito cimentício reforçado com fibra (CRF) no estado pré-fissurado tornou-se um importante tópico de estudo recentemente. Isso se deve ao fato de que o comportamento dependente do tempo do CRF e a estabilidade a longo prazo de fissuras sob cargas de flexão sustentadas ainda são pouco compreendidas. Este trabalho busca explorar o uso de fibras de aço e PP para definir sua influência na fluência, analisando a evolução das aberturas de fissuras com o tempo. O material foi inicialmente caracterizado sob testes de flexão de três e quatro pontos em amostras prismáticas com entalhe. Para os testes de fluência, os corpos de prova foram pré-fissurados a 0,5 mm e testados sob carga constante durante 45 dias. Para entender os mecanismos relacionados, testes de fluência também foram realizados em fibras e em uma configuração de arrancamento. Analisando os resultados dos testes de fluência, verificou-se que a taxa de COD (crack opening displacement) é uma ferramenta interessante para avaliar o comportamento a longo prazo do CRF fissurado e para definir um critério de estabilidade. Além disso, verificou-se que o concreto incorporando fibras sintéticas apresenta maiores deformações de fluência do que o reforçado com fibras de aço. Isso pode ser explicado pelas diferentes características das ligações fibra-matriz, analisadas pelos testes de arrancamento monotônico e de carga sustentada, e pela resposta de compressão do compósito. Finalmente, as propriedades residuais das amostras ensaiadas por fluência foram determinadas por testes monotônicos de flexão. / [en] Creep in pre-cracked fiber reinforced cementitious composites has become an important topic of study recently. This is due to the fact that the time dependent behaviour of FRC and long term stability of cracks under sustained bending loads are still poorly understood. This work seeks to explore the use of steel and PP fibers in order to define their influence on creep, by analyzing the crack opening displacement rate in FRC specimens. The material was first characterized under three and four-point bending tests in notched prismatic specimens. For the creep tests, the specimens were pre-cracked to 0.5 mm, and then tested under constant load during 45 days. In order to better understand the related mechanisms, creep tests were also carried on single fibers and in a fiber pullout configuration. Analyzing the creep tests results, it was verified that the COD rate is an interesting tool to evaluate the long-term behaviour of the cracked FRC and to define a stability criterion. In addition, it was found that concrete incorporating macro synthetic fibers presents higher creep deformations and higher creep rate than concrete reinforced with steel fibers. This can be explained by the different fiber-matrix bond characteristics, analyzed by monotonic and sustained load pullout tests, and by the compression response of the composite. Finally, the residual properties of creep tested specimens were determined by monotonic flexural tests performed in the FRC specimens after the creep tests.

[pt] CONCRETO REFORCADO COM FIBRA

[pt] ESTABILIDADE DE FISSURAS

[pt] FLUENCIA

[en] FIBER REINFORCED CONCRETE

[en] CRACK GROWTH

[en] CREEP

Impact resistance of deflection-hardening fiber reinforced concretes with different mixture parameters

Banyhussan, Q.S., Yildirim, Gurkan, Anil, O., Erdem, R.T., Ashour, Ashraf, Sahmaran, M.

31 January 2019

Yes / The impact behavior of deflection-hardening High Performance Fiber Reinforced Cementitious Concretes (HPFRCs) was evaluated herein. During the preparation of HPFRCs, fiber type and amount, fly ash to Portland cement ratio and aggregate to binder ratio were taken into consideration. HPFRC beams were tested for impact resistance using free-fall drop-weight test. Acceleration, displacement and impact load vs. time graphs were constructed and their relationship to the proposed mixture parameters were evaluated. The paper also aims to present and verify a nonlinear finite element analysis, employing the incremental nonlinear dynamic analysis, concrete damage plasticity model and contact surface between the dropped hammer and test specimen available in ABAQUS. The proposed modelling provides extensive and accurate data on structural behavior, including acceleration, displacement profiles and residual displacement results. Experimental results which are further confirmed by numerical studies show that impact resistance of HPFRC mixtures can be significantly improved by a proper mixture proportioning. In the presence of high amounts of coarse aggregates, fly ash and increased volume of hybrid fibers, impact resistance of fiberless reference specimens can be modified in a way to exhibit relatively smaller displacement results after impact loading without risking the basic mechanical properties and deflection-hardening response with multiple cracking.

Deflection-hardening

Impact

Coarse aggregate

Fly ash

Abaqus

Design of systems for time delayed activated internal release of chemicals in concrete from porous fibers, aggregates of prills, to improve durability

Dry, Carolyn Minnetta

22 May 2007

Incorporation of chemicals into the internal matrix of cement or concrete, with later release occurring upon stimulation, alters the matrix parameters from those at the initial set. Permeability is reduced, for example, and therefore durability enhanced. The advantages of these designs would be the ability to reduce maintenance and repair costs in the initial building configuration and to delay the time of eventual repair. The components and the structure could take greater environmental abuse also. Permeability is significantly reduced by release of a polymer from wax-coated porous fibers upon heating to temperature of polymerization. Freeze/thaw damage is somewhat reduced by the timed release of linseed oil or antifreeze from porous aggregates due to the freezing action itself. These example designs using timed release mostly gave improved durability performance when compared to conventional treatments for durability or environmental distress. Concerns that significant strength reduction would occur due to heating or fiber loading were shown to be unfounded by our test results; indeed, heating and fiber inclusion increased strength. An adequate amount of wetting of the samples could be obtained with 2.75% volume of fibers; however, above a 2.75% volume of fibers, fibers do reduce the strength. Results were analyzed by the method of comparing results in the samples with factors varied to results in samples without variable factors, that is, by comparing to the controls. This research shows that timed internal release of chemicals into cement can be accomplished; it appears feasible and is potentially useful. Long-term tests need to be performed on such factors as chloride ion intrusion/ corrosion tests. Filled fiber, aggregate or prill manufacture, storage, and placement need to be researched and assessed for cost. Design of components using only targeted areas for release in the component and the use of time released fibers in reinforced cement laminates should be evaluated. / Ph. D.

LD5655.V856 1991.D79

Concrete -- Additives

Controlled release technology

Fiber-reinforced concrete

Polymer-impregnated concrete