Predictive Modelling of CFRP-Steel Double Strap Joints

Jiwani, Preet Deepak

19 January 2023

Carbon fiber reinforced polymers (CFRP), which can be used to strengthen and repair damaged steel structures, have gained popularity in recent years. On the one hand, CFRP has demonstrated substantial advantages over conventional reinforcing techniques like welding and bolting, such as light weight, high strength, and corrosion resistance. Additionally, the CFRP application process is relatively easy, rapid, and labor-intensive. On the other hand, failure is more likely to happen at the bond interface due to the high strength characteristics of steel and CFRP. Thus, studying the bond behavior and failure mechanism of CFRP strengthened steel structures as well as the variables that are crucial to the bond quality. Prior to implementing these elements in an actual construction, it is necessary to thoroughly study the factors affecting this bond strength. Despite the fact that some theoretical predictive modeling for the strength between steel/CFRP joints under various loading situations has been published, in this work, by using finite element modelling, one may compute the failure loads and effective length of the steel/CFRP specimens quickly, simply and accurately. Additionally, factors affecting these parameters are also investigated in this study. / Master of Science / Structural Steel deteriorates over time. Due to this, engineers are constantly on the look-out for cheap and easy ways to repair and maintain these structures. One of the methods is the use of carbon fibred polymer or CFRP. In the literature, it has been frequently documented that CFRPs can make existing structures stronger. Additionally, CFRP has the advantages of not corroding and prevents the structure from becoming significantly heavier. Due to this high strength of CFRP, the failure occurs at the steel-CFRP interface and thus this bond and the factors affecting this bond needs to be studied. One way to do this is experimental testing and another way is finite element modelling which can give you data that is harder to get using experimental testing. Thus, this study focuses on finite element modelling of these joints and how it can be used for studying these joints.

: CFRP

Steel

FE Modelling

ABAQUS

Double Strap Joint

C-Grid as Shear Reinforcement in Concrete Bridge Girders

Ward, John Charlton III

28 March 2016

Corrosion of reinforcing steel causes shorter life spans in bridges throughout the United States. The use of carbon fiber reinforced polymer (CFRP) materials as the flexural reinforcement in bridge girders has been extensively studied. However, CFRP transverse reinforcement has not been as rigorously investigated, and many studies have focused on CFCC stirrups. The use of C-Grid as an option for transverse reinforcing has not been previously investigated. This thesis concludes that C-Grid is a viable shear design option and presents the initial recommendations for design methods. These methods provide a basis for the design of C-Grid shear reinforcing that could be used as a starting point for future testing of full scale specimens. This testing program first determined the mechanical properties of C-Grid and its development length. Four 18 ft long 19 in. deep beams, modeled after prestressed Bulb-T beams, were created to test the C-Grid, as well as steel and CFCC stirrups. The beams were loaded with a single point load closer to one end to create a larger shear load for a given flexural moment. Overall beam displacement was measured to determine when flexural reinforcement yielding was reached, and beams were fitted with rosettes and instrumentation to capture initiation of shear cracking. Shear capacity calculations following four methods were compared to test results. The design method should follow the AASHTO modified compression field theory with equations for β and θ. The manufacturer's guaranteed strength should be used for design as long as that strength is the average reduced by three standard deviations. Shear crack widths are controlled to a similar size as steel stirrups when using at least two layers of grid. / Master of Science

C-Grid

CFRP

Shear

Transverse Reinforcement

Concrete Bridge Girders

Investigation of moment redistribution in FRP-strengthened continuous RC beams and slabs

Tajaddini, Abbas

January 2015

Most reinforced concrete (RC) structures are continuous in some way, and many of these structures are strengthened using fibre-reinforced polymer (FRP) materials as a routine basis. The problem of how to exploit moment redistribution in FRP-strengthened continuous RC structures is still unresolved. Reduction in ductility has been recognised in such structures. However, FRP-strengthening is introduced as an effective method to enhance the strength and load bearing capacity of RC structures. As a result, design guidelines worldwide employ conservative guidance for design, such that they limit the potential exploitation of moment redistribution in FRP-strengthened members. To date, limited research has been conducted into the redistribution of bending moment in such structures. Previous theoretical studies have not yet led to a reliable and rigorous solution for quantifying moment redistribution throughout the loading cycle. In addition, a wide scatter of moment redistribution percentage findings, from zero to 56%, has been reported in previous experimental studies. This demonstrates the need for further research to effectively characterise the circumstances under which moment redistribution can be relied on, both into and out of FRP-strengthened zones in continuous RC flexural members. This research aims to encourage the use of FRP for strengthening existing RC structures in a more efficient manner. The findings help to better understand restrictions on moment redistribution into and out of FRP-strengthened zones, effect of mechanical anchorage of the FRP on the degree of moment redistribution, and the extent to which moment redistribution can be relied on. A new analytical model, only based on structural mechanics, is developed in this research. A comprehensive set of large-scale structural testing is undertaken to validate the analytical model under various strengthening circumstances. The analytical and experimental results show that moment redistribution can occur into FRP-strengthened zones to full capacity without any limitation, even if the FRP is unanchored. Further, bending moment can also be redistributed out of strengthened zones to a considerable extent (up to 20%), depending on the quantity and stiffness of the FRP, and provided that the FRP is fully anchored. A set of parametric studies is conducted to investigate the effectiveness of different parameters on the level of moment redistribution. The major parameters include compressive strength of concrete, steel reinforcement proportion, steel yield strength, FRP quantity and stiffness, ultimate strain of the FRP, strengthening configuration, load position, beam shape, and curvature ductility. The outcomes demonstrate that it is not only the curvature ductility of FRP-strengthened sections that is important to the capacity for moment redistribution (out of such zones), but also the mode of failure, strength of the other critical zones, the ratio of stiffness between the critical zones, and the loading arrangement. It is concluded that moment redistribution in continuous FRP-strengthened concrete structures should be permitted both into and out of strengthened zones, provided that the criteria for such redistribution are met.

624.1

Apports de l'analyse comparée des processus de fragmentation et de création de débris dans la compréhension du comportement à l'écrasement de structures composites aéronautiques / Contributions of the comparative analysis of fragmentation and debris generation processes to the understanding of the behaviour of aeronautical composite structures under crushing

Tostain, Floran

02 December 2016

La certification des aéronefs au crash ou à l’atterrissage dur nécessite de concevoir et dimensionner des structureslégères vérifiant les exigences d’absorption d’énergie. Le critère de performance est l’énergie d’absorptionspécifique (Specific Energy Absorption, SEA). Nos travaux expérimentaux et numériques visent une meilleurecompréhension de la contribution favorable ou défavorable des modes de ruine à la stabilité et à l’amplitude del’énergie consommée. Le travail expérimental, réalisé sur des échantillons plaques stratifiées en T700/M21 faible grammage et interlock 55% ou 100%, compare les niveaux et les évolutions des forces d’écrasement avec l’apparition et le maintien desmodes de ruine majeurs que sont l’évasement, les fragmentations en coeur de plis et localisée en bout de pli.L’observation et la mesure des processus dynamiques de fragmentation représentent un verrou contourné ici parune analyse point à point de la synchronisation entre les films des essais et les courbes force-déplacement, et parl’observation post-mortem des échantillons, des débris et des fragments. Les plaques ont une performance àl’écrasement sensible à l’épaisseur des plis et aux vitesses de déformation. Pour les interlocks, c’est le sens detissage qui a le plus d’effet sur l’amplitude et la stabilité de la SEA, et génère un évasement global plus instable.La simulation numérique dynamique transitoire non-linéaire est utilisée comme outil complémentaire de mesureet d’analyse des essais sur plaques T700/M21 [0°/90°]. La morphologie d’écrasement est bien reproduite.L’analyse des processus de ruine à l’échelle du pli fait apparaître l’interaction entre la résistance mécanique encompression transverse du matériau (Yc) et la résistance à la déchirure en cisaillement de la structure (GIIc), etl’articulation et/ou la compétition entre évasement et fragmentation en cœur de pli qui en découlent. La mesurede la contribution des trois modes de ruine dans l’énergie consommée effectuée au travers de l’évolution desseuils de ruine permet de suivre l’évolution correspondante de l’effort d’écrasement. Une étude a été menée surla robustesse du modèle, et permet d’évaluer plus généralement la sensibilité en amplitude et en stabilité de laSEA aux propriétés de résistance mécanique identifiées comme influentes. / The certification of aircrafts to hard landing or crash situations needs to design lightweight structures meetingrequirements in term of energy absorption. The Specific Energy Absorption (SEA) is used to compare theperformance of different structures. Experimental and numerical studies led in our work aim to improve theunderstanding of the influence of ruin modes on the crushing stability and the energy absorption capacity.Crushing experimental tests are carried on low-weight T700/M21 CFRP laminated plates and on 55% or 100%Interlock configurations. The crushing force value and its variations are compared to the proportion of inside plyfragmentation, localized fragmentation and splaying mode observed during the crushing process. The observationand the measure of the dynamic process of fragmentation are lock problems circumvented by two means. First, astep by step observation of synchronized tests’ pictures and force-displacement points is conducted. Second, apost-mortem observation of the specimen and a collect of debris and fragments is carried out. It is shown thatcomposite laminates behaviour is influenced by the ply thickness and the strain-rate parameters. For the Interlock,the woven directions have the most important effect on the SEA value and stability and can produce a globalfragmented splaying with some instability. Nonlinear transient dynamic numerical simulations are used as an additional tool to measure and analyse the experimental tests on T700/M21 [0°/90°] plates. The crushing morphology is correctly reproduced. The analysis of damage at the mesoscale shows the interaction between the mechanical transverse compressive strength of thematerial (Yc) and the shear strength of interfaces between plies (GIIc), and the link and/or the competition betweensplaying and inside ply fragmentation. The measure of the contribution of the three ruin modes in the dissipatedenergy is performed and linked to the variations of the crushing force. A study is carried out on the robustness ofthe model and allows linking the SEA value and stability to the mechanical strength properties identified asinfluential parameters.

Crash

Fragmentation

Modélisation numérique

Composite

Carbone/époxy

Cfrp

Sea

Crash

Crush

Fragmentation

Computational mechanics

Composite

Carbon/epoxy

Cfrp

Sea

620.1

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.

Prestressing RC Beams with Near Surface Mounting (NSM) Fiber Reinforced Polymers (FRP) and/or Iron-Based Shape Memory Alloy (Fe-SMA) Rods

Raad, Janet

January 2018

No description available.

Civil Engineering

Engineering

Etude d’un contrôle ultrasonore pour la détection et l’identification de l’ondulation de plis dans les CFRP aéronautiques

Zardan, Jean-Philippe

23 November 2012

L'ondulation pli est un défaut majeur qui peut apparaître dans certains matériaux composites tels que le CFRP. Des mesures de vitesse et atténuation ultrasonore permettent la détection, mais pas l'identification, de l'ondulation pli. Dans la présente étude, il est démontré que pour identifier cette ondulation pli, il est important de prendre en compte la déviation du faisceau ultrasonore. Deux méthodes différentes, A²Scan et C²Scan, permettent de détecter et mesurer cette déviation. D'une part, de l'écart produit un comportement asymétrique dans les réponses obtenues à des angles d'incidence oblique. Ce phénomène se manifeste à travers l'étude des domaines d'angles d'incidence, qui peuvent normalement être superposés. D'autre part, la technique de C²Scan permet la mesure de la déviation du champ acoustique transmis. Dans les deux cas, l'étude de la déviation induite révèle sa sensibilité à la présence d'ondulation plis. Ces méthodes ont été validées expérimentalement et leur utilisation potentielle, en fonction de l'épaisseur de la pièce, ainsi que sont industrialisation par ultrasons laser sont discutées. / Ply waviness is a major defect, which can appear in certain composite materials such as CFRP. Attenuation and ultrasound velocity measurements allow the detection, but not the identification, of ply waviness. In the present study it is shown that in order to identify this ply waviness, it is important to take the deviation of the ultrasonic beam into account. Two different methods,A²Scan et C²Scan , allowing such deviations to be detected are proposed. On the one hand, the deviation produces an asymmetrical behaviour in the responses obtained at oblique incidence angles. This phenomenon is revealed through the study of incidence angle ranges, which can normally be superimposed. On the other hand, the double scanning technique allows the deviation of the energy maxima of the transmitted acoustic field to be determined. In both cases, the study of induced deviation reveals that it is sensitive to the presence of ply waviness. These methods have been experimentally validated and their potential use, depending on the thickness of the workpiece and industrialization by laser ultrasonic means are discussed.

Cfrp

Contrôle Non Destructif

Déviation ultrasonore

C²Scan

A²Scan

Ondulation de plis

Composites

Ultrasons

Cfrp

Nde

Ndt

Ultrasonic deviation

C²Scan

A²Scan

Ply Waviness

Externally unbonded post-tensioned CFRP tendons : a system solution

Bennitz, Anders

January 2011

The introduction of Fibre Reinforced Polymers (FRP) to the civil engineering market in the late 1980s resulted in the emergence of a range of new tools for rehabilitating and strengthening concrete structures. Strengthening using FRPs is typically accomplished using non-prestressed externally bonded FRPs. The technical and economic benefits of such strengthening could be further increased by prestressing the FRPs, especially when dealing with concrete structures. Prestressing concrete structures suppresses the appearance and growth of cracks in the serviceability limit state. This in turn increases the structure’s stiffness and resistance to degradation. Prestressing also increases the structure’s yield load but does not change its failure load relative to that of an analogous non-prestressed structure, provided that all other parameters are kept constant. In 2004, a pilot study was carried out at the Luleå University of Technology (LTU) to investigate the scope for using unbonded Carbon Fibre Reinforced Polymer (CFRP) strengthening systems, particularly those involving prestressing. In the early stages of this project, a number of difficulties were encountered in anchoring the CFRP rods to concrete structures: the conical wedge anchorages that were used tended to either cause premature failure of the rods or allowed the rod to slip out of the anchorage. It was therefore decided to study the mechanisms at work within these anchorages in more detail. The goal of the project was to develop a small, practical, reliable, and userfriendly anchorage for use in unbonded external CFRP strengthening systems. On the basis of a thorough literature review, which is described in Paper 1, it was concluded that despite the difficulties encountered, the conical wedge anchorages used with steel reinforcing rods were the most promising starting point for the design of a new anchorage for use with CFRPs. Importantly, the conical wedge anchorage can be made small in size and easy to mount while retaining a high degree of versatility; this is not true of bonded, sleeve, and clamping anchorages. Analytical and numerical models were used to investigate the distribution of radial stress within these highly pressurized anchorages. Paper 2 describes an evaluation of the capability of three types of models - an analytical axisymmetric model based on the thick-walled-cylinder-theory and two Finite Element (FE) models, one axisymmetric and one three-dimensional - to predict the behaviour of a conical wedge anchorage. It was concluded that the axisymmetric models were incapable of modelling the stress distribution within the anchorage with sufficient accuracy, and so 3D FE models were used exclusively in subsequent studies. Paper 3 describes the development of a new anchorage for CFRP rods. The design process involved conducting pull-out studies on a series of prototypes, in conjunction with computational studies using a basic FE model, to identify and understand the prototypes’ failure modes. Between the computational data and experimental results, a good understanding of the factors affecting the interaction between the CFRP rod and the anchorage was obtained. The new anchorage design employs a one-piece wedge which effectively incorporates the three wedges and the inner sleeve from more conventional wedge anchorages into a single unit. This increases the reliability and user-friendliness of the anchorage because it eliminates the need to check the alignment of individual wedges. The new design has been patented; the published Swedish patent is included in the thesis as Paper 6. The newly-developed anchorage was then incorporated into a prestressing system and its performance was evaluated using a series of test beams. In parallel with the planning of these tests, a series of pull-out tests was conducted using the new anchorage. The strain measurements obtained in these experiments were compared to predictions made using a new, more advanced FE model, and used to refine the design of the new anchorage. Paper 4 describes this new FE model, the most important parameters affecting anchorage behaviour, and the final anchorage design. Paper 5 focuses on the possibilities provided by the new anchorage. Tests were performed using seven three meter long concrete beams prestressed with external unbonded CFRP tendons. One beam was unstrengthened; the other six were strengthened in different ways, with different prestressing forces, initial tendon depths, and with or without the use of a midspan deviator for the tendons. The results of these tests were compared to those obtained using otherwise identical beams prestressed with steel tendons and to the predictions of an analytical beam model developed for use with steel tendons. These tests showed that the prestressing works as intended and that the behaviour of beams prestressed with external unbonded CFRP tendons is fully comparable to that of beams prestressed with steel tendons. It was also found that the predictions of the analytical model were in good agreement with experimental observations, although there were some differences between the measured and predicted tendon stresses. The development of a functional anchorage represents a fulfilment of the objectives laid out at the start of this project, and represents an important step towards the practical use of prestressed unbonded external CFRP tendons in strengthening concrete structures. However, a number of outstanding questions remain to be addressed. Little is known about the safety of this kind of system, and the benefits of using CFRP tendons should be quantified. Furthermore, there are a number of potential technical issues that must be addressed. These include the risk of creep-rupture in the CFRP, the effects of thermal contraction and expansion on the anchorage, and the scalability of the anchorage as the tendon diameter is increased. Finally, the long-term behaviour of the anchorage and prestressing system should be investigated. / I och med introduktionen av fiberkompositer i byggbranschen under slutet av 80-talet har en rad nya verktyg för förstärkning och underhåll av betongkonstruktioner utvecklats. Förstärkning har oftast utförts med pålimmade kompositer utan förspänning. För att ytterligare öka verkningsgraden, både den tekniska och ekonomiska, kan förspänning vara en möjlighet. Särskilt för betongkonstruktioner. Förspänning av en betongkonstruktion medför att man i bruksgränstillståndet begränsar uppkomsten av sprickor och deras storlek. Det ger i sin tur en ökad styvhet hos konstruktionen. Därutöver höjs lasten för när det slakarmerade stålet flyter. I jämförelse med ospända konstruktioner är dock brottlasten densamma, så länge övriga parametrar behålls. Under 2004 genomfördes en pilotstudie vid Luleå tekniska universitet (LTU) för att undersöka framtida möjligheter och utmaningar med förspända, icke vidhäftande kolfiberkompositkablar. I det läget upptäcktes svårigheter att förankra kompositkabeln mot betongen. De koniska killås som användes orsakade antingen brott på kabeln redan vid låga belastningar eller glidning hos kabeln, som omöjliggjorde fullgod kraftöverföring. Ett beslut togs då att tills vidare fokusera på förankringen och genomföra en mer ingående studie kring denna. Som mål sattes upp att arbetet skulle resultera i en liten, tillförlitlig och användarvänlig förankring. Den skulle sen i en förlängning kunna användas för att slutföra pilotstudien och därefter i större tillämpningar. Trots de förhållandevis nedslående resultaten från pilotförsöken visade den grundliga litteraturstudien som presenteras i Artikel 1 att koniska killås trots allt verkar vara den mest lovande typen av förankring för kolfiberkablar. Den bör därför användas som utgångspunkt för fortsatt utveckling. I motsats till vidhäftande, hyls och klämmande förankringar kan killåset göras litet, lätt att montera och också användas i många praktiska tillämpningar. För att undersöka hur de höga radiella tryckspänningarna i ett sådant killås fördelas är olika former av beräkningsmodeller nödvändiga verktyg. I Artikel 2 jämförs tre olika modeller med avseende på hur väl de kan beskriva komplexiteten hos ett koniskt killås. Det är dels en analytisk axisymmetrisk modell, som också härleds i artikeln, dels en axisymmetrisk Finita Element (FE) modell och dels en 3D FE modell. Undersökningen visade att ingen av de axisymmetriska modellerna har kapacitet nog att tillförlitligt modellera killåset. I fortsatta undersökningar har därför endast 3D FE använts. Resultaten från en enkel FE modell ligger också, tillsammans med tidiga laboratorieförsök, som grund för Artikel 3. Däri beskrivs hur ett nytt killås via prototyper och nya lösningar utvecklats, och hur arbetet för att få fram det nya låset också gett en bättre förståelse för interaktionen mellan kolfiberkompositkabel och lås. Som avslutning presenteras en innovativ design där de tre kilarna och den inre hylsan sammanfogats till en enhet. Med den nyutvecklade designen blir förankringen såväl mer tillförlitlig som användarvänlig. Alla kilar har då redan från början rätt position i förhållande till varandra. Den utvecklade förankringslösningen har också lett fram till ett beviljat svenskt patent, bifogat i avhandlingen som Artikel 6. Efter utvecklingen av den nya förankringen var nästa steg i de uppsatta målen implementering av densamma i ett förspänningssystem och nya balkförsök i konstruktionslabbet. Parallellt med planeringen för balkförsöken pågick ett arbete med att ytterligare förbättra låsdesignen. Bland annat användes en mer detaljerad FE modell som sedan jämfördes med mätningar från en ny serie med dragprov. Den nya FE modellen tillsammans med en utvärdering av viktiga parametrar och den slutliga förankringsdesignen presenteras i Artikel 4. Artikel 5 sammanfattar och avslutar forskningsstudien med en testserie om sju stycken, tre meter långa, betongbalkar förspända med utanpåliggande kolfiberkompositstavar. En av balkarna provades utan förstärkning. Förstärkningen hos de övriga varierades med avseende på förspänningsgrad, förspänningens effektiva höjd och användandet av deviator vid balkmitt. Resultaten har jämförts mellan de provade balkarna, med identiska balkar förspända med stålkablar samt med en analytisk modell utvecklad för förspänning med stålkablar. Från resultaten kan utläsas att förspänningen fungerar bra och att beteendet hos balkarna förspända med utanpåliggande kolfiberkablar är fullt jämförbart med det hos balkarna förspända med stålkablar. Likaså visar jämförelsen med de modellerade beteendena på god överensstämmelse, även om vissa skillnader finns mellan uppmätta och modellerade spänningar i kolfiberkabeln. Med målen för forskningen uppfyllda och en ny fungerande förankring framtagen så har vägen till praktiska tillämpningar kortats betydligt, ändå finns några frågetecken kvar att räta ut. Ett är säkerheten hos den här typen av system och nyttan av att använda kolfiberkomposit istället för stål. Innan systemet används i praktiken bör därför följande frågeställningar belysas: Risk för krypbrott i kolfiberarmeringen, inverkan av temperaturförändringar (och temperaturrörelser) i förankringen samt eventuella storlekseffekter vid förankring av kablar med större diametrar. De här frågorna tillsammans med långtidsförsök på förankringen och förspänningssystemet bör ses som viktiga framtida forskningsfrågor. / Godkänd; 2011; 20110128 (ysko); DISPUTATION Ämnesområde: Konstruktionsteknik/Structural Engineering Opponent: PhD Chris Burgoyne, Dep of Engineering, University of Cambridge, UK Ordförande: Professor Björn Täljsten, Institutionen för samhällsbyggnad och naturresurser, Luleå tekniska universitet Tid: Fredag den 18 februari 2011, kl 10.00 Plats: F1031, Luleå tekniska universitet

CFRP

prestress

tendon

external

unbonded

anchorage

beams

CFRP

förspänning

vajer

utanpåliggande

icke vidhäftande

förankring

Infrastructure Engineering

Infrastrukturteknik

Numerical Investigation into The Cutting Forces, Chip Formation Mechanism, and Burr Formation During Slot Milling of Laminated and 3d Printed CFRP Composites

Hassan, Md Mahmudul

January 2022

No description available.

Mechanical Engineering

Numerical modeling

simulation

CFRP composite

post-processing

milling

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