Research on the mechanics of CFRP composite lap joints

Curnutt, Austin

January 1900

Master of Science / Department of Architectural Engineering / Donald J. Phillippi / For this thesis, research was performed on CFRP bonded composite lap-joints with one and two continuous laminas through the lap. Composite wraps used to retrofit existing structures use lap joints to maintain their integrity. The use of composites for retrofitting structures has many advantages over traditional methods, such as steel jacketing, and is becoming more widely accepted in the structural engineering industry. While much literature exists documenting the performance of composite wraps as a whole when applied to concrete columns, less information is available on the behavior of the lap-joint of the wrap. Developing a better understanding of how the lap-joint behaves will help researchers further understand composite column wraps. This research sought to determine what affect continuous middle laminas may have on the stiffness of lap joints and whether or not stress concentrations exist in the lap-joint due to a change in stiffness.

CFRP

Lap-joint

Carbon fiber reinforced polymer

Carbon Fiber Reinforced Polymer (CFRP) Tendons in Bridges

Paneru, Nav Raj

January 2018

No description available.

Civil Engineering

CFRP

CFCC

Prestressed CFRP

Tendons

Strands

Carbon Fiber Reinforced Polymer

FRP

GFRP

AFRP

Bridge Design

Size effect on shear strength of FRP reinforced concrete beams

Ashour, Ashraf, Kara, Ilker F.

07 December 2013

yes / This paper presents test results of six concrete beams reinforced with longitudinal carbon fiber reinforced polymer (CFRP) bars and without vertical shear reinforcement. All beams were tested under a two-point loading system to investigate shear behavior of CFRP reinforced concrete beams. Beam depth and amount of CFRP reinforcement were the main parameters investigated. All beams failed due to a sudden diagonal shear crack at almost 45°. A simplified, empirical expression for the shear capacity of FRP reinforced concrete members accounting for most influential parameters is developed based on the design-by-testing approach using a large database of 134 specimens collected from the literature including the beams tested in this study. The equations of six existing design standards for shear capacity of FRP reinforced concrete beams have also been evaluated using the large database collected. The existing shear design methods for FRP reinforced concrete beams give either conservative or unsafe predictions for many specimens in the database and their accuracy are mostly dependent on the effective depth and type of FRP reinforcement. On the other hand, the proposed equation provides reasonably accurate shear capacity predictions for a wide range of FRP reinforced concrete beams.

Improving Ductility And Shear Capacity Of Reinforced Concrete Columns With Carbon Fiber Reinforced Polymer

Ozcan, Okan

01 December 2009

The performance of reinforced concrete (RC) columns during recent earthquakes has clearly demonstrated the possible failures associated with inadequate confining reinforcement. The confinement reinforcement requirements of older codes were less stringent than present standards. Many studies were conducted by applying different retrofitting techniques for RC columns that have inadequate confinement reinforcement. A new retrofitting technique by means of Carbon Fiber Reinforced Polymer (CFRP) was developed and tested in many countries in the last decade. This technique is performed by CFRP wrapping the critical region of columns. The effectiveness of CFRP retrofitting technique was shown in many studies conducted worldwide. In Turkey, the frame members are considerably deficient from the seismic detailing point of view. Therefore, in order to use the CFRP retrofitting technique effectively in Turkey, experimental evidence is needed. This study investigates the performance of CFRP retrofitted RC columns with deficient confining steel and low concrete strength. It was concluded by experimental and analytical results that the CFRP retrofitting method can be implemented to seismically deficient columns. Moreover, two design approaches were proposed for CFRP retrofit design of columns considering safe design regulations.

Improvement Of Punching Strength Of Flat Plates By Using Carbon Fiber Reinforced Polymer (cfrp) Dowels

Erdogan, Hakan

01 December 2010

Due to their practical application, flat-plates have been commonly used slab type in constructions in recent years. According to the investigations that were performed since the beginning of the 20th century, the vicinity of the slab-column connection is found to be susceptible to punching failure that causes serious unrepairable damage leading to the collapse of the structures. The objective of this study is to enhance the punching shear strength of slab-column connections in existing deficient flat plate structures. For this purpose, an economical and easy to install strengthening method was applied to &frac34 / scale flat-slab test specimens. The proposed strengthening scheme employs the use of in house-fabricated Carbon Fiber Reinforced Polymer (CFRP) dowels placed around the column stubs in different numbers and arrangements as vertical shear reinforcement. In addition, the effect of column aspect ratio on strengthening method was also investigated in the scope of this study. Strength increase of at least 30% was obtained for the CFRP retrofitted specimens compared to the companion reference specimen. Three-dimensional finite element analyses of test specimens were conducted by using the general purpose finite element analyses program. 3-D finite element models are successful in providing reasonable estimates of load-deformation behavior and strains. The experimental punching shear capacities and observed failure modes of the specimens were compared with the estimations of strength and failure modes given by punching shear strength provisions of ACI 318-08, Eurocode-2, BS8110-97 and TS500. Necessary modifications were proposed for the existing provisions of punching shear capacity in order to design CFRP upgrading.

Mechanical Properties Of Cfrp Anchorages

Ozdemir, Gokhan

01 February 2005

Due to inadequate lateral stiffness, many reinforced concrete buildings are highly damaged or collapsed in Turkey after the major earthquake. To improve the behavior of such buildings and to prevent them from collapse, repair and/or strengthening of some reinforced concrete elements is required. One of the strengthening techniques is the use of CFRP sheets on the existing hollow brick masonry infill. While using the CFRP sheets their attachment to both structural and non-structural members are provided by CFRP anchor dowels. In this study, by means of the prepared test setup, the pull-out strength capacities of CFRP anchor dowels are measured. The effects of concrete compressive strength, anchorage depth, anchorage diameter, and number of fibers on the tensile strength capacity of CFRP anchor dowel are studied.

Mecanismos de confinamento em pilares de concreto encamisados com polímeros reforçados com fibras submetidos à flexo-compressão / Confinement mechanisms in concrete columns wrapped by carbon fiber reinforced polymers subjected to flexural compression

Ricardo Carrazedo

19 December 2005

Neste trabalho avaliou-se a influência da forma da seção transversal e da excentricidade do carregamento sobre o efeito de confinamento em pilares de concreto encamisados com polímeros reforçados com fibras (PRF). Para estas avaliações foi utilizada a análise experimental, por meio de ensaios de pilares sob flexo-compressão, e a análise numérica com o método dos elementos finitos. Observou-se que ocorreram reduções significativas dos efeitos de confinamento em pilares de seção quadrada e retangular quando a relação entre o raio de arredondamento dos cantos e o maior lado da seção transversal diminuiu. A influência da relação entre o lado maior e menor, no caso de pilares de seção retangular, não foi tão significativa se comparada ao efeito redutor do raio de arredondamento mencionado anteriormente. Ocorreram ganhos de resistência em todos os pilares ensaiados, indicando que o encamisamento com PRF pode ser utilizado mesmo em situações em que a força de compressão seja aplicada com pequenas excentricidades. O efeito da excentricidade sobre o confinamento dependeu da forma da seção transversal considerada. Em pilares de seção circular a excentricidade reduziu levemente os efeitos de confinamento. Nos pilares de seção quadrada a excentricidade não reduziu significativamente os efeitos de confinamento, sendo que para os menores raios de arredondamento o efeito de confinamento foi até maior na presença da excentricidade. Nos pilares de seção retangular observou-se que aplicando a excentricidade na direção da menor inércia o comportamento foi semelhante ao dos pilares de seção quadrada. Porém, aplicando a excentricidade na direção da maior inércia observou-se um grande efeito de confinamento, maior inclusive que no pilar centrado. / In this work the influence of the cross section shape and eccentricity of the compressive load on the confinement of concrete columns wrapped by fiber reinforced polymer (FRP) was evaluated. Experimental analysis, through flexural compression tests of columns, and numerical analysis developed through the finite element method were used to study these effects. Significant reductions of confinement effects were noticed in square and rectangular cross sections when the ratio of the round off radius to the major side of the column was reduced.The ratio between the major and minor side in rectangular columns was not so important to define the effectiveness of confinement as was the fore mentioned factor. Increases of strength were noticed in all columns tested, showing that FRP wrapping can be successfully used even with small eccentricities of loading. The effect of the eccentricity on the confinement showed to be dependent on the cross section shape. In circular columns the eccentricity of loading reduced the confinement effects. For the square cross section columns tested the confinement was not significantly affected by the eccentricity. In fact, for square columns with low round off radius, the eccentricity increased the confinement effects. Rectangular columns subjected to eccentric loading in the direction of the minor inertia showed a behavior similar to square columns. On the other hand, with the eccentricity applied in the direction of the major inertia, an important confinement effect was observed, more important than in the case of concentric loading.

concreto

confinamento

pilares

plasticidade

reforço

carbon fiber reinforced polymer

columns

concrete

confinement

plasticity

strengthening

Carbon Fiber Reinforced Polymer Repairs of Impact-Damaged Prestressed I-Girders

Brinkman, Ryan J.

January 2012

No description available.

Civil Engineering

Carbon Fiber Reinforced Polymer Repair

CFRP Repair

Ultimate Moment Capacity

Prestressed Concrete Bridge I-girders

Impact-Damage

Sagging and hogging strengthening of continuous reinforced concrete beams using CFRP sheets.

El-Refaie, S.A., Ashour, Ashraf, Garrity, S.W.

07 1900

Yes / This paper reports the testing of 11 reinforced concrete (RC) two-span beams strengthened in flexure with externally bonded carbon fiber-reinforced polymer (CFRP) sheets. The beams were classified into two groups according to the arrangement of the internal steel reinforcement. Each group included one unstrengthened control beam. The main parameters studied were the position, length, and number of CFRP layers. External strengthening using CFRP sheets was found to increase the beam load capacity. All strengthened beams exhibited less ductility compared with the unstrengthened control beams, however, and showed undesirable sudden failure modes. There was an optimum number of CFRP layers beyond which there was no further enhancement in the beam capacity. Extending the CFRP sheet length to cover the entire hogging or sagging zones did not prevent peeling failure of the CFRP sheets, which was the dominant failure mode of beams tested.

Reinforced concrete

Reinforced concrete

Continuous beams

Strengthening

Deflection

Capacity

Reaction

Strains

Moment redistribution

Ductility

Reinforced Concrete Beams Strengthened with Side Near Surface Mounted FRP : A parametric study based on finite element analysis

Eredini, Rewan

January 2016

Most of the today’s concrete structures are older than tenyears, and the need to strengthening existing structures is growing steadily. This is due to various reasons such as degradation due to ageing, environmentally induced degradation, poor initial design or construction and lack of maintenance, to name a few. Among the benefits of strengthening existing structures are; less impacts on the environmental and financial benefits. Therefore, there is a need to find alternative ways to strengthen concrete structures more effectively. For the past decades, several different strengthening methods have been studied. Two examples are externally bonded reinforcement (EBR) and near surface mounted reinforcement (NSM). The outcome of these studies has shown a significant enhancement to the structures. Steel plates and rebar have been used to strengthen concrete structures and have shown good increases in flexural capacity. For this purpose, resins have been used to implement the steel plates and rebar, e.g. shotcrete and epoxy. Due to the weight of steel and its sensitivity to corrosion, new materials have been sought. A promising material for this use is the fiber reinforced polymers (FRP). There are several types of FRP such as, carbon fiber reinforced polymer (CFRP), glass fiber reinforced polymer (GFRP) and aramid fiber reinforced polymer (AFRP). These new material has shown a better performance, due to their light weight, resistance to corrosion,etc. NSM and EBR perform extremely well in practice as long as sufficient anchorage is provided. However, a premature debonding has been observed by several researchers. This report will study an alternative method to reinforce existing concrete structures called “Side Near Surface Mounted Reinforcement (S-NSMR)” in association with a project run by Gabriel Sas at Luleå University of Technology. This is compared to Bottom Near Surface Mounted Reinforcement (B-NSM), which is a well-established method. It is assumed that the fiberutilisation will increase in NSM applied on the side of the beam. If this hypothesis is proven correct, the proposed method will also solve a major constrain in the utilisation of the NSM technique. In certain cases, the bottom of a beam is not fully accessible for strengthening using bottom Applied NSM techniques due to e.g. partition walls or beam-column joints. To test the effect of S-NSMR seven concrete beams, one reference beam with no fiberreinforcement and two sets of three, for S-NSMR and B-NSMR respectively with different CFRP-rebar length, were tested in the laboratory. An analytical calculation has also been carried out. In this thesis, a parametric study is performed with FEM software Atena. The thesis begins with a study of the failure phenomena occurring in the earlier mentioned strengthening method. A benchmark model is then modelled with a good comparison to the experimental results. An idealised model of the steel reinforcement in the concrete beam is used according to Eurocode 2. Material parameters in concrete are calculated according to Atena theory documents. The influence of creep and shrinkage are considered by reducing the elastic modulus of concrete by 25 %, reducing the tensile strength by 50 % and fracture energy accordingly. Thereafter, three additional parameters were chosen to continue the parametric study with Atena, 1) CFRP with E-modulus 160 GPa, 2) two different position in cross-section height of S-NSM and 3) five shorter CFRP-rebar each 100 mm smaller than the previous rebar. The behaviour of the two reinforcing types is then compared. The first parameter is, CFRP with a smaller E-modulus. It could be observed that all beams lost their stiffness, especially after yielding of the steel reinforcement. A small improvement in ductility could also be observed. The utilisation rate of CFRP increased by 13-16% in the case of S-NSM and 18-20% in the case of B-NSM. The second parameter is, different position of CFRP along the height of the beams cross-section in S-NSM beams. The positions of the CFRP was lowered in two steps. In each case an increase in stiffness and a decrease in ductility could be observed. However, the increase of the stiffness was still smaller than the stiffness in the B-NSM, in all cases. The failure mode changed from a ductile (concrete crushing) type to a more brittle kind (peeling-off concrete), due to large flexural cracks at the end of the CFRP-rebar.   The utilisation rate of CFRP-rebar, is decreased in each S-NSM beam except for S-NSM 2 with the height 25 mm. The reduction in the utilisation rate of the CFRP is 7-32 % and in S-NSM 2 with the height H25mm showing an increased in utilisation rate by 7 %. The third is parameter, different length of CFRP-rebar. In the case of S-NSM, the failure mode changed from a ductile failure mode to a brittle failure mode. The utilisation rate decreased with the decrease in CFRP length. In three of five cases, the S-NSM shows a higher ultimate load-displacement relation, and in all five cases the maximum tensile strains in the CFRP were higher in S-NSM than B-NSM. Even though the stiffness in the S-NSM is lower than the B-NSM, it would be more preferable to use the S-NSM than B-NSM, because of its higher ultimate load and lower displacements.

Side near surface mounted reinforcement

Parametric study

FEM-analysis

Atena

Carbon fiber reinforced polymer

Other Civil Engineering

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