Behaviour of Post-Tensioned Slab Bridges with FRP Reinforcement under Monotonic and Fatigue Loading

Noel, Martin

January 2013

The introduction of fibre-reinforced polymers (FRPs) to the field of civil engineering has led to numerous research efforts focusing on a wide range of applications where properties such as high strength, light weight or corrosion resistance are desirable. In particular, FRP materials have been especially attractive for use as internal reinforcement in reinforced concrete (RC) structures exposed to aggressive environments due to the rapidly deteriorating infrastructure resulting from corrosion of conventional steel reinforcement. While FRPs have been successfully implemented in a variety of structural applications, little research has been conducted on the use of FRP reinforcement for short span slab bridges. Furthermore, the behaviour of FRP-RC flexural members cast with self-consolidating concrete (SCC) is largely absent from the literature. The present study investigates the behaviour of an all-FRP reinforcement system for slab bridges which combines lower cost glass FRP (GFRP) reinforcing bars with high performance carbon FRP (CFRP) prestressed tendons in SCC to produce a structure which is both cost-efficient and characterized by excellent structural performance at the serviceability, ultimate and fatigue limit states. An extensive experimental program comprised of 57 large or full-scale slab strips was conducted to investigate the effects of reinforcement type, reinforcement ratio, prestressing level and shear reinforcement type on the flexural performance of slab bridges under both monotonic and fatigue loading. The proposed reinforcement system was found to display excellent serviceability characteristics and high load capacities as well as significant deformability to allow for sufficient warning prior to failure. Lastly, the use of post-tensioned CFRP tendons limited the stresses in the GFRP reinforcing bars leading to significantly longer fatigue lives and higher fatigue strengths compared to non-prestressed slabs. Analytical models were used to predict the behaviour of the slab bridge strips at service and at ultimate. Where these models failed to accurately represent the experimental findings, simple modifications were proposed. The results from ancillary tests were also used to modify existing analytical models to predict the effects of fatigue loading on the deflection, crack width, shear resistance and flexural capacity of each of the tested slabs.

slab bridges

concrete

frp

fibre reinforced polymer

cfrp

gfrp

scc

self-consolidating concrete

carbon

glass

slab

bridge

prestress

prestressing

post-tension

fatigue

Civil Engineering

Design And Characterization Of Electromagnetic Wave Absorbing Structural Compsites

Gurer, Goksu

01 September 2010

Electromagnetic interference (EMI) is one of the most common problems encountered in microwave applications. Interaction of electromagnetic (EM) waves from different sources may result in device malfunction due to misinterpretation of the transferred data or information loss. On the other hand, development of materials with reduced radar detectability is desired in defense applications. Considering the limitations in weight and thickness, development of lightweight structural materials with enhanced electromagnetic absorption potential is needed. In this study, development and characterization of glass fiber-reinforced polymer (GFRP) composite materials to be used in EM wave absorbing or EMI shielding applications was aimed. Incorporation of electromagnetic wave absorption characteristic has been achieved by the application of conductive thin film on fiber glass woven fabric reinforcement layers. Characterization of EM wave absorption potential was conducted using &ldquo / free-space method&rdquo / in 18 &ndash / 27 GHz frequency range. Single and multilayered combinations of surface-modified fiber glass woven fabrics were characterized in terms of their EM wave interaction properties and design principles for efficient broadband EM wave absorbing multilayered GFRP composite material have been presented. A computer aided computation method has also developed in order to predict EM wave transmission, reflection, and hence absorption characteristics of multilayered structures from single layer properties. Estimated results were verified compared to free-space measurement results. In the current study, up to 85% electromagnetic wave absorption has been obtained within 18-27 GHz frequency range (K band). Enhancement of EM wave absorption potential of multilayer structure has also been demonstrated by computer aided computation.

TA Engineering Design 174

Behaviour of Post-Tensioned Slab Bridges with FRP Reinforcement under Monotonic and Fatigue Loading

Noel, Martin

January 2013

The introduction of fibre-reinforced polymers (FRPs) to the field of civil engineering has led to numerous research efforts focusing on a wide range of applications where properties such as high strength, light weight or corrosion resistance are desirable. In particular, FRP materials have been especially attractive for use as internal reinforcement in reinforced concrete (RC) structures exposed to aggressive environments due to the rapidly deteriorating infrastructure resulting from corrosion of conventional steel reinforcement. While FRPs have been successfully implemented in a variety of structural applications, little research has been conducted on the use of FRP reinforcement for short span slab bridges. Furthermore, the behaviour of FRP-RC flexural members cast with self-consolidating concrete (SCC) is largely absent from the literature. The present study investigates the behaviour of an all-FRP reinforcement system for slab bridges which combines lower cost glass FRP (GFRP) reinforcing bars with high performance carbon FRP (CFRP) prestressed tendons in SCC to produce a structure which is both cost-efficient and characterized by excellent structural performance at the serviceability, ultimate and fatigue limit states. An extensive experimental program comprised of 57 large or full-scale slab strips was conducted to investigate the effects of reinforcement type, reinforcement ratio, prestressing level and shear reinforcement type on the flexural performance of slab bridges under both monotonic and fatigue loading. The proposed reinforcement system was found to display excellent serviceability characteristics and high load capacities as well as significant deformability to allow for sufficient warning prior to failure. Lastly, the use of post-tensioned CFRP tendons limited the stresses in the GFRP reinforcing bars leading to significantly longer fatigue lives and higher fatigue strengths compared to non-prestressed slabs. Analytical models were used to predict the behaviour of the slab bridge strips at service and at ultimate. Where these models failed to accurately represent the experimental findings, simple modifications were proposed. The results from ancillary tests were also used to modify existing analytical models to predict the effects of fatigue loading on the deflection, crack width, shear resistance and flexural capacity of each of the tested slabs.

slab bridges

concrete

frp

fibre reinforced polymer

cfrp

gfrp

scc

self-consolidating concrete

carbon

glass

slab

bridge

prestress

prestressing

post-tension

fatigue

Civil Engineering

Long term and short term deflection of GFRP prestressed concrete slabs

Singh, Mahendra

25 June 2014

This thesis investigates the performance of GFRP pretensioned concrete slabs and compares their flexural behaviour with GFRP reinforced and steel prestressed concrete slabs. A total of 12 slabs were cast in this program. The slab mid-span deflections are theoretically predicted and the results indicate that the short-term response of GFRP prestressed concrete slabs can be predicted well by the existing methods. Long-term deflection behaviour has been estimated using the Age Adjusted Effective Modulus Method by incorporating three creep and shrinkage models. A large influence of creep and shrinkage models on the theoretical determination is observed and the use of long term multipliers is not suitable for GFRP prestressed concrete members. The slabs were instrumented for long-term monitoring using strain gauges and fibre-optic sensors. It was concluded that the electrical strain gauges can be successfully used for long-term strain monitoring.

GFRP

prestressed concrete

glass fiber-reinforced polymer

long-term

short-term

deflection

time-dependent behaviour

serviceability

flexural

Age Adjusted Effective Modulus Method

creep

shrinkage

The Effect of Steel Strapping Tensioning Technique and Fibre-Reinforced Polymer on the Performance of Cross-Laminated Timber Slabs Subjected to Blast Loads

Lopez-Molina, America Maria

09 October 2018

Engineered wood products (EWP) are becoming extremely popular and a viable material option for the construction of residential, commercial, and hybrid buildings. Cross-laminated timber (CLT) is among one of the many EWP available in North America, which can be utilized for many different applications such as: walls, floors, and roofs. Despite the available requirements in the Canadian blast design standard (CSA, 2012) with regard to the design of wood structures, there are currently no provisions on how to retrofit timber structures to improve their performance when subjected to blast loads. The current study is aimed at investigating the effect of different retrofitting alternatives in order to improve the overall behaviour of CLT when exposed to out-of-plane bending. The experimental program examined the behaviour of seventeen reinforced CLT slabs. Testing was conducted at the University of Ottawa by means of a shock tube capable of simulating high strain rates similar to those experienced during a blast event. The current study was divided into two phases. The first consisted of CLT slabs retrofitted with steel straps where strap spacing, location, and order of installation was investigated. The second phase focused on the development of dynamic properties of CLT panels when reinforced with GFRP. Lay-up configuration and fabric orientation were among the parameters explored. The results from the experimental program show that reinforcing the panels with steel straps had minimal effect on the ultimate strength, but significant levels of post peak resistance and ductility was achieved. The horizontal straps were able to restrict the failure to small regions and to promote flexural failure by preventing rolling shear failure. It also eliminated flying debris and enhanced the ultimate strength, stiffness as well as ductility. Applying GFRP layers enhanced the overall behaviour of the slab resulting in a significant increase in peak resistance, ductility, and stiffness when compared to the dynamic results of an unretrofitted panel. The post peak resistance was also greatly improved. In particular, applying stacked quadraxial lay-up configuration significantly improved the ductility and resulted in the greatest post peak resistance. The effect of steel straps on damaged and retrofitted was relatively minimal, and only partial recovery of the resistance and the stiffness was achieved. GFRP with full confinement yielded better performance compared to the unretrofitted and undamaged counterpart. More work is needed to quantify the benefits of using GFRP in these applications.

Blast Loads

Hight Strain Rates

Steel Strapping Tensioning Technique

Fibre-Reinforced Polymer

Steel Straps

GFRP

Retrofit

Cross-Laminated Timber

Slabs

Engineered Wood Products

Estruturas mistas de madeira-concreto: avaliação das vigas de madeira laminada colada reforçadas com fibras de vidro / Timber-concrete composite structures: evaluation of GFRP reinforced glulam beams

José Luiz Miotto

17 April 2009

No cenário da produção de edificações sustentáveis, a madeira laminada colada (MLC) ocupa lugar de destaque, sobretudo pela possibilidade de emprego de madeiras provenientes de florestas plantadas. Com o propósito de amenizar os problemas de durabilidade, quando exposta às intempéries, uma solução pressupõe a associação das vigas de MLC com um tabuleiro de concreto armado, sendo as partes ligadas por meio de conexões flexíveis. Essa técnica tem sido aplicada com sucesso, especialmente por conta do expressivo acréscimo de rigidez proporcionado pela composição. No entanto, em situações de elevados carregamentos ou de grandes vãos, a aplicação de reforços com fibras sintéticas, na face tracionada das vigas de MLC, aprimora ainda mais essa técnica, refletindo-se em significativos acréscimos nas forças de ruptura. Neste trabalho avaliou-se, de forma experimental e numérica, o comportamento estrutural de vigas mistas de MLC-concreto reforçadas com fibras de vidro. Numa primeira etapa foram estudados os elementos de ligação, optando-se pelos ganchos de aço com diâmetro de 8 mm pelo seu excepcional desempenho. Em seguida foram confeccionadas as vigas mistas, com e sem reforços com fibras de vidro, registrando-se acréscimo médio de 37% no módulo de ruptura (MOR) das vigas mistas em relação às vigas de MLC, ambas reforçadas com fibras. O emprego do reforço com fibras sintéticas se justifica pela diminuição na dispersão dos resultados. Por fim, um algoritmo foi proposto para o dimensionamento das vigas mistas de MLC-concreto reforçadas com fibras de vidro, o qual, associado às avaliações numéricas e experimentais, permite ampliar os horizontes de aplicação das estruturas de madeira. / Production of sustainable constructions forms a scenario where glulam beams occupy a prominence place, because of the possibility of utilization of wood that comes from planted forests. With the intention of diminution in the durability problems, when exposed to the weather effects, a solution presupposes the association of glulam beams with a reinforced concrete slab, in which the components are linked by means of flexible connections. This technique has been applied with results, especially due to the expressive increment in stiffness provided by the composition. However, in situations where high loads or great spans are found, the application of synthetic fibers reinforcements in the tension side of glulam beams improve this technique, being reflected in significant increments in the rupture forces. In this study it was evaluated, in experimental and numerical way, the structural behavior of glulam-concrete composite beams reinforced with glass fiber reinforced polymer (GFRP). In a first stage the connection elements were studied, being opted for steel hooks with 8 mm in diameter because of their exceptional behavior. Soon after, the composite beams were made with and without GFRP reinforcements and their tests showed average increment of 37% in modulus of rupture (MOR), when the composite beams were compared to glulam beams, both reinforced with GFRP. The decrease in the variability of results justifies the use of synthetic fibers reinforcements. Finally, an algorithm was proposed for the design of glulam-concrete composite beams reinforced with GFRP. So, when associated with the experimental and numerical evaluations that were carried out, this method allows enlarging the horizons of timber structures applications.

Estruturas mistas de MLC-concreto

Modelo de dimensionamento

Reforço com fibras de vidro

Design model

GFRP reinforcement

Glulam-concrete composite structures

GFRP-reinforced concrete columns under simulated seismic loading / Colonnes en béton armé renforcées de PRFV sous un chargement sismique simulé

Mohammed, Mohammed Gaber Elshamandy

January 2017

Abstract : Steel and fiber-reinforced-polymer (FRP) materials have different mechanical and physical characteristics. High corrosion resistance, high strength to weight ratio, non-conductivity, favorable fatigue enable the FRP to be considered as alternative reinforcement for structures in harsh environment. Meanwhile, FRP bars have low modulus of elasticity and linear-elastic stress-strain curve. These features raise concerns about the applicability of using such materials as reinforcement for structures prone to earthquakes. The main demand for the structural members in structures subjected to seismic loads is dissipating energy without strength loss which is known as ductility. In the rigid frames, columns are expected to be the primary elements of energy dissipation in structures subjected to seismic loads. The present study addresses the feasibility of reinforced-concrete columns totally reinforced with glass-fiber-reinforced-polymer (GFRP) bars achieving reasonable strength and the drift requirements specified in various codes. Eleven full-scale reinforced concrete columns—two reinforced with steel bars (as reference specimens) and nine totally reinforced with GFRP bars—were constructed and tested to failure. The columns were tested under quasi-static reversed cyclic lateral loading and simultaneously subjected to compression axial load. The columns are 400 mm square cross-section with a shear span 1650 mm. The specimen simulates a column with 3.7 m in height in a typical building with the point of contra-flexure located at the column mid-height. The tested parameters were the longitudinal reinforcement ratio (0.63, 0.95 and 2.14), the spacing of the transverse stirrups (80, 100, 150), tie configuration (C1, C2, C3 and C4), and axial load level (20%, 30% and 40%). The test results clearly show that properly designed and detailed GFRP-reinforced concrete columns could reach high deformation levels with no strength degradation. An acceptable level of energy dissipation compared with steel-reinforced concrete columns is provided by GFRP reinforced concrete columns. The dissipated energy of GFRP reinforced concrete columns was 75% and 70% of the counter steel columns at 2.5% and 4% drift ratio respectively. High drift capacity achieved by the columns up to 10% with no significant loss in strength. The high drift capacity and acceptable dissipated energy enable the GFRP columns to be part of the moment resisting frames in regions prone to seismic activities. The experimental ultimate drift ratios were compared with the estimated drift ratios using the confinement Equation in CSA S806-12. It was found from the comparison that the confinement Equation underestimates values of the drift ratios thus the experimental drift ratios were used to modify transverse FRP reinforcement area in CSA S806-12. The hysteretic behavior encouraged to propose a design procedure for the columns to be part of the moderate ductile and ductile moment resisting frames. The development of design guidelines, however, depends on determining the elastic and inelastic deformations and on assessing the force modification factor and equivalent plastic-hinge length for GFRP-reinforced concrete columns. The experimental results of the GFRP-reinforced columns were used to justify the design guideline, proving the accuracy of the proposed design equations. / L’acier et les matériaux à base de polymères renforcés de fibres (PRF) ont des caractéristiques physiques et mécaniques différentes. La résistance à la haute corrosion, le rapport résistance vs poids, la non-conductivité et la bonne résistance à la fatigue font des barres d’armature en PRF, un renforcement alternatif aux barres d’armature en acier, pour des structures dans des environnements agressifs. Cependant, les barres d’armature en PRF ont un bas module d’élasticité et une courbe contrainte-déformation sous forme linéaire. Ces caractéristiques soulèvent des problèmes d'applicabilité quant à l’utilisation de tels matériaux comme renforcement pour des structures situées en forte zone sismique. La principale exigence pour les éléments structuraux des structures soumises à des charges sismiques est la dissipation d'énergie sans perte de résistance connue sous le nom de ductilité. Dans les structures rigides de type cadre, on s'attend à ce que les colonnes soient les premiers éléments à dissiper l'énergie dans les structures soumises à ces charges. La présente étude traite de la faisabilité des colonnes en béton armé entièrement renforcées de barres d’armature en polymères renforcés de fibres de verre (PRFV), obtenant une résistance et un déplacement latéral raisonnable par rapport aux exigences spécifiées dans divers codes. Onze colonnes à grande échelle ont été fabriquées: deux colonnes renforcées de barres d'acier (comme spécimens de référence) et neuf colonnes renforcées entièrement de barres en PRFV. Les colonnes ont été testées jusqu’à la rupture sous une charge quasi-statique latérale cyclique inversée et soumises simultanément à une charge axiale de compression. Les colonnes ont une section carrée de 400 mm avec une portée de cisaillement de 1650 mm pour simuler une colonne de 3,7 m de hauteur dans un bâtiment typique avec le point d’inflexion situé à la mi-hauteur. Les paramètres testés sont : le taux d’armature longitudinal (0,63%, 0,95% et 2,14 %), l'espacement des étriers (80mm, 100mm, 150 mm), les différentes configurations (C1, C2, C3 et C4) et le niveau de charge axiale (20%, 30 % et 40%). Les résultats des essais montrent clairement que les colonnes en béton renforcées de PRFV et bien conçues peuvent atteindre des niveaux de déformation élevés sans réduction de résistance. Un niveau acceptable de dissipation d'énergie, par rapport aux colonnes en béton armé avec de l’armature en acier, est atteint par les colonnes en béton armé de PRFV. L'énergie dissipée des colonnes en béton armé de PRFV était respectivement de 75% et 70% des colonnes en acier à un rapport déplacement latéral de 2,5% et 4%. Un déplacement supérieur a été atteint par les colonnes en PRFV jusqu'à 10% sans perte significative de résistance. La capacité d’un déplacement supérieur et l’énergie dissipée acceptable permettent aux colonnes en PRFV de participer au moment résistant dans des régions sujettes à des activités sismiques. Les rapports des déplacements expérimentaux ultimes ont été comparés avec les rapports estimés en utilisant l’Équation de confinement du code CSA S806-12. À partir de la comparaison, il a été trouvé que l’Équation de confinement sous-estime les valeurs des rapports de déplacement, donc les rapports de déplacement expérimentaux étaient utilisés pour modifier la zone de renforcement transversal du code CSA S806-12. Le comportement hystérétique encourage à proposer une procédure de conception pour que les colonnes fassent partie des cadres rigides à ductilité modérée et résistant au moment. Cependant, l'élaboration de guides de conception dépend de la détermination des déformations élastiques et inélastiques et de l'évaluation du facteur de modification de la force sismique et de la longueur de la rotule plastique pour les colonnes en béton armé renforcées de PRFV. Les résultats expérimentaux des colonnes renforcées de PRFV étudiées ont été utilisés pour justifier la ligne directrice de conception, ce qui prouve l’efficacité des équations de conception proposées.

Concrete columns

GFRP bars

Hysteretic response

Ductility parameters

Energy dissipation

Drift capacity

Displacement-based design

Colonnes en béton

Barres en PRFV

Réponse hystérétique

Paramètres de ductilité

Énergie de dissipation

Capacité de déplacement

Axial compressive and seismic shear performance of post-heated columns repaired with composite materials

Yaqub, Muhammad

January 2010

In the light of extreme events of natural disasters (earthquakes or hurricanes) and accidents (fire or explosion), repairing and strengthening of existing concrete structures has become more common during the last decade due to the increasing knowledge and confidence in the use of composite advanced repairing materials. The past experience from real fires shows that it is exceptional for a concrete building to collapse as a result of fire and most fire-damaged concrete structures can be repaired economically rather than completely replacing or demolishing them. In this connection an experimental study was conducted to investigate the effectiveness of fibre reinforced polymer jackets for axial compressive and seismic shear performance of post-heated columns. This study also investigates the effectiveness of ferrocement laminate for the repairing of post-heated reinforced concrete columns.A total of thirty-five reinforced concrete columns were constructed and then tested after categorising them into three main groups: un-heated, post-heated and post-heated repaired. The post-heated columns were initially damaged by heating (to a uniform temperature of 500°C). The concrete cubes were also heated to various temperatures to develop the relation between compressive strength and ultrasonic pulse velocity. The residual compressive strength of the concrete cubes and reinforced concrete columns were determined by ultrasonic testing. The post-heated columns were subsequently repaired with unidirectional glass or carbon fibre reinforced polymer and ferrocement jackets. The experimental programme was divided into two parts. The columns of experimental part-1 were tested under axial compressive loading. The columns of experimental part-2 with a shear span to depth ratio of 2.5 were tested under constant axial and reversed lateral cyclic loading. The results indicated that the trend of reduction in ultrasonic pulse velocity values and in residual compressive strength of concrete was similar with increasing temperature. The reduction in residual stiffness of both post-heated square and circular columns was greater than the reduction in ultimate load. The circular sections benefited more compared to the square cross-sections with fibre reinforced polymers for improving the performance of post-heated columns in terms of compressive strength and ductility tested under axial compression. GFRP and CFRP jackets performed in an excellent way for increasing the shear capacity, lateral strength, ductility, energy dissipation and slowed the rate of strength and stiffness degradation of fire damaged reinforced concrete square and circular columns tested under combined constant axial and reversed lateral cycle loading. However, the effect of a single layer of glass or carbon fibre reinforced polymer on the axial stiffness of post-heated square and circular columns was negligible. The use of a ferrocement jacket for the repairing of post-heated square and circular columns enhanced the axial stiffness and ultimate load carrying capacity of columns significantly.

624.1834

Entwicklung und Verifizierung eines vorlochfreien mechanischen Fügeverfahrens zum Verbinden von Leichtmetallen und Faser-Kunststoff-Verbunden

Podlesak, Frank

27 April 2017

Die Mischbauweise stellt eine Möglichkeit dar, insbesondere im Automobilbau, aber auch in anderen Industriezweigen Leichtbau zu betreiben. Dazu werden verschiedenartige Werkstoffe miteinander kombiniert. Vorzugsweise handelt es sich um Kombinationen aus faserverstärkten Kunststoffen und Leichtmetallen. Nach dem Motto “Der richtige Werkstoff am richtigen Ort” können so belastbare und gleichzeitig leichte Konstruktionen realisiert werden. Eine große Herausforderung besteht dabei jedoch im Fügen solch unterschiedlicher Werkstoffe. Aufgrund großer Unterschiede in Bindungsart und Schmelztemperatur sind klassische Fügeverfahren nicht anwendbar. Zum Verbinden von Metallen mit Faser- Verbund-Werkstoffen (FKV) wurden deswegen vorhandene Technologien adaptiert oder neue entwickelt. Im Rahmen dieser Dissertation wurde mit dem modifizierten Blindnieten ein neuer Lösungsansatz entwickelt, der sowohl mechanische als auch thermische Fügeverfahren miteinander kombiniert. Dazu wird ein rotierender Blindniet in sich überlappende Bleche getrieben und das darunter liegende Material unter Ausbildung einer Hülse aus dem Oberblech verdrängt. Anschließend wird der Niet ausgeformt und der Prozess ist abgeschlossen. Durch die Reibwärme wird die thermoplastische Matrix des FKV geschmolzen und die Fasern werden beweglich und können verdrängt werden. Dadurch kommt es zu einer geringeren Faserschädigungen und es können Delaminationen komplett vermieden werden. Untersuchungen wurden vorzugsweise an Materialkombinationen in Mischbauweise durchgeführt. Es wurden Aluminium- und Magnesiumbleche mit verschiedenen FKV mit Glas- oder Kohlefaserverstärkung gefügt. Für eine große Anwendungsbreite wurden ebenso Verbindungen von mehreren Metallblechen untersucht. Alle Kombinationen konnten so gefügt werden, dass in relativ kurzer Prozesszeit eine qualitativ hochwertige Verbindung entsteht. Mit einer geeigneten Parameterwahl sind Fügezeiten unter drei Sekunden möglich. Die mechanisch technologischen Gütewerten zeigen, dass mittels modifiziertem Blindnieten hergestellte Verbindungen mindestens die gleiche Lasten aufnehmen können, wie konventionelle Verfahren. Unter Scherbelastung kann die Belastbarkeit um bis zu 68 % gesteigert werden. Es hat sich gezeigt, dass mit dem neuen Verfahren eine wirtschaftliche Lösung für den Mischbau zur Verfügung steht. / Composite constructions provide an opportunity to introduce lightweight design in automotive and other industries. Therefore different kind of materials are combined. Preferably, these are combinations of fibre reinforced plastics and lightweight metal alloys. With the slogan 'the right material at the right place' tough and lightweight constructions can be realized. A big challenge the joining of these different materials. Because of big differences in the chemical bindings and in the melting temperature, conventional joining methods cannot be used. To join fibre reinforced plastics (FRP) existing processes were adapted or newly developed. In the course of this work with the modified blind riveting a new approach was developed, which combines mechanical and thermal joining processes. Therefore a rotating blind rivet is penetrated through two overlapping sheets by deforming the sheet material. After that the rivet is set and the process finished. Because of the friction heat the thermoplastic matrix of the FRP is slightly melted and the fibres can be moved without breaking them. Investigations were done mainly with lightweight material combinations. Sheets made out of aluminum and magnesium were joined with glass or carbon fibre reinforced plastic sheets. For a wider application field also combinations of two metal sheets were investigated. All combinations could be joined in a relatively short cycle time and high quality. So it is possible to reach a joining time of under 3 seconds. Under shear load the strength of joints made by modified blind riveting can be up to 68 % higher than conventional riveted joints. It has been shown that the new process can be exploited economically.

info:eu-repo/classification/ddc/600

ddc:600

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