Flexural behavior of GFRP-reinforced concrete continuous beams

Rahman, S. M. Hasanur

12 August 2016

In this study, a total of twelve beams continuous over two spans of 2,800 mm each were constructed and tested to failure. The beams were divided into two series. Series 1 included six T-beams under symmetrical loading, while Series 2 dealt with six rectangular beams under unsymmetrical loading conditions. In Series 1, the test variables included material type, assumed percentage of moment redistribution, spacing of lateral reinforcement in flange, arrangement of shear reinforcement, and serviceability requirements. In Series 2, three different loading cases were considered, I) loading both spans equally, II) loading both spans maintaining a load ratio of 1.5 and III) loading one span only. Under the loading case II, the parameters of reinforcing material type, assumed percentage of moment redistribution and serviceability requirements were investigated. The test results of both series showed that moment redistribution from the hogging to the sagging moment region took place in GFRP-RC beams which were designed for an assumed percentage of moment redistribution. In Series 1, the decrease of the stirrups spacing from 0.24d to 0.18d enhanced the moment redistribution percentage. Also, decreasing the spacing of lateral reinforcement in the flange from 450 to 150 mm improved the moment redistribution through enhancing the stiffness of the sagging moment region. In Series 2, the unsymmetrical loading conditions (loading case II and III) reduced the moment redistribution by reducing flexural stiffness in the heavily loaded span due to extensive cracking. Regarding serviceability in both series, the GFRP-RC beam designed for the same service moment calculated from the reference steel-RC beam, was able to meet the serviceability requirements for most types of the structural applications. / February 2017

Investigation of the performance of fibre reinforced polymer re-bars in structural foundations

Labana, Beltran

06 1900

Thesis. (M.Tech. (Dept. of Civil Engineering and Building, Faculty of Engineering and Technology)) -- Vaal University of Technology, 2011. / This research focused on the structural performance of Fibre Reinforced Polymer (FRP) re-bars in structural foundation compared to steel reinforcement re-bars. The corrosion of steel re-bars is the main reason of deterioration of reinforced concrete. However, use of FRP re-bars as alternative reinforcement will address the deterioration of reinforced concrete. Carbon and Glass Fibre Reinforced Polymer re-bars were used as reinforcing bars and traditional steel reinforced concrete was used as the reference. Thirty six specimens of reinforced concrete bases were tested for flexural capacity at different ages. The simulation of Soil Bearing Pressure of this study was derived from the model of beam finite length on elastic foundation. The foundation base was treated as a beam while the soil was modelled as series of timber elements acting as springs. The mathematical model to reflect the model was as documented by Timoshenko (1976:18) and Den Hartog (1952:160). Results showed that stress in the steel re-bars of reinforced concrete was higher than that of Carbon Fibre Reinforced Polymer (CFRP) and Glass Fibre Reinforced Polymer (GFRP) re-bars by 227 MPa (5.99 percent) and 284 MPa (7.61 percent), respectively. The stress in CFRP re-bars was 57 MPa or 1.53 percent higher compared to GFRP re-bars of FRP reinforced concrete. Furthermore, the experimental ultimate moments of CFRP and GFRP reinforced concrete foundation – bases on the 28th day were 23.917 kNm (79.0 percent) and 23.529 kNm (77.7 percent) higher than the theoretical ultimate moments, respectively. However, steel reinforced concrete foundation – bases had the higher calculated deflection than FRP reinforced concrete. With high resistance to corrosion as a property, FRP re-bars appeared to be a better alternative reinforcement to steel in corrosion in an aggressive environment. / Vaal University of Technology

Fibre reinforced polymer re-bars

Steel re-bars

Reinforced concrete

624.171

Reinforced concrete.

Reinforced concrete -- Fiber

Mix Design and Impact Response of Fibre Reinforced and Plain Reactive Powder Concrete

Gao, Xiang, S3090502@student.rmit.edu.au

January 2008

Concrete is the most broadly used material in construction worldwide and Reactive Powder Concrete (RPC, a type of ultra high performance concrete) is a relatively new member of the concrete family. In this work the critical parameters of RPC mix design are investigated and the mix design is explored through a program of concrete casting and testing. Owing to the enhanced microstructure of RPC, porosity and permeability can be significantly decreased in the concrete matrix. This benefits the durability characteristics of RPC elements resulting in a longer service life with less maintenance costs than conventional concrete. It has been used for high integrity radiation waste material containers because of its low permeability and durability. Fibre reinforced RPC is also ideal for use in long span and thin shell structural elements without traditional reinforcement because of its advantageous flexural strength. Moreover, due to improved impact resistance, RPC can be widely employed in piers of bridges, military construction and blast protection. There is no standard approach to assessing the impact resistance of concrete. This investigation utilises relatively well accepted impact equipment to evaluate the mechanical properties of RPC under dynamic loading. The compressive and flexural tensile strengths of plain and fibre reinforced RPC are investigated using a variety of specimens and apparatus. The dynamic increase factor (DIF) is evaluated to indicate the strain rate sensitivity of the compressive and flexural strength.

Reactive Powder Concrete

RPC

mix design

silica fume

impact

fibre reinforced

drop hammer rig

Degradation Models for the Collapse Analysis of Composite Aerospace Structures

Orifici, Adrian Cirino, adrian.orifici@student.rmit.edu.au

January 2007

For the next generation of aircraft, the use of fibre-reinforced polymer composites and the design of

Fibre-reinforced composites

Aerospace

Stiffened structures

Postbuckling

Collapse

Interlaminar damage

Ply damage

Virtual Crack Closure Technique

Innovative Pre-cast Cantilever Constructed Bridge Concept

Visscher, Brent Tyler

30 July 2008

Minimum impact construction for bridge building is a growing demand in modern urban environments. Pre-cast segmental construction is one solution that offers low-impact, economical, and aesthetically pleasing bridges. The standardization of pre-cast concrete sections and segments has facilitated an improved level of economy in pre-cast construction. Through the development of high performance materials such as high strength fibre-reinforced concrete (FRC), further economy in pre-cast segmental construction may be realized. The design of pre-cast bridges using high-strength FRC and external unbonded tendons for cantilever construction may provide an economical, low-impact alternative to overpass bridge design. This thesis investigates the feasibility and possible savings that can be realized for a single cell box girder bridge with thin concrete sections post-tensioned exclusively with external unbonded tendons in the longitudinal direction. A cantilever-constructed single cell box girder with a curtailed arrangement of external unbonded tendons is examined.

unbonded external post-tensioning

cantilever construction

fibre-reinforced concrete

minimum impact construction

0543

Innovative Pre-cast Cantilever Constructed Bridge Concept

Visscher, Brent Tyler

30 July 2008

Minimum impact construction for bridge building is a growing demand in modern urban environments. Pre-cast segmental construction is one solution that offers low-impact, economical, and aesthetically pleasing bridges. The standardization of pre-cast concrete sections and segments has facilitated an improved level of economy in pre-cast construction. Through the development of high performance materials such as high strength fibre-reinforced concrete (FRC), further economy in pre-cast segmental construction may be realized. The design of pre-cast bridges using high-strength FRC and external unbonded tendons for cantilever construction may provide an economical, low-impact alternative to overpass bridge design. This thesis investigates the feasibility and possible savings that can be realized for a single cell box girder bridge with thin concrete sections post-tensioned exclusively with external unbonded tendons in the longitudinal direction. A cantilever-constructed single cell box girder with a curtailed arrangement of external unbonded tendons is examined.

unbonded external post-tensioning

cantilever construction

fibre-reinforced concrete

minimum impact construction

0543

Strengthening of Wooden Cross arms in 230 kV Transmission Structures Using Glass Fibre Reinforced Polymer (GFRP) Wrap

Shahi, Arash

20 August 2008

There are approximately 6000 Gulfport-type wood structures used to support 1600 km of 230 kV electrical transmission lines in Ontario. An unexpected structural failure caused by wood deterioration has been recognized as a major risk to the safety of these transmission lines. Since the reliability of the electricity transmission and distribution lines is extremely important to the electrical industry and other users of electricity, failure of these structures can result in devastating incidents. Due to the remote location of the transmission network and the requirement to keep the power lines in continuous service, replacement of the Gulfport structures has proved to be very difficult and expensive. This research program investigated the use of Glass Fibre Reinforced Polymer (GFRP) wrap as a light weight and durable strengthening system that can be applied to the existing structures without any interruptions in the functionality of the transmission lines. A total of three control specimens and three strengthened samples were tested in Phase I of the experimental program, which was designed as a feasibility study. It was concluded that the average strength of strengthened samples was 42% higher than the average strength of the control samples, and was greater than the end of life (EOL) threshold of 30 MPa for the cross arms. Therefore, the proposed strengthening system was concluded to be an effective solution for strengthening the deteriorated cross arms of the Gulfport structures. Taguchi methods and Analysis of Variation (ANOVA) were employed in Phase II to optimize the proposed strengthening system. The optimal configuration was determined to be the application of the filler material, non-sanded surface, and the shorter width of wrap (width of 0.6 m). The mean strength of the optimal configuration was estimated to be 52 MPa with a 95% confidence interval of: 38.7 MPa < True Mean < 65.3 MPa. Phase III confirmed the estimated mean and the confidence interval for the optimal configuration in Phase II. The strengthening system changed the failure mode from combined shear-flexure failure to pure flexure and resulted in more consistent strength and stiffness values. The strain values of the GFRP wrap showed that a single layer of wrap was sufficient for the confinement purposes.

Strengthening

GFRP Wrap

Glass Fibre Reinforced Polymer

Wood

Timber

Transmission Structure

230 kV

Civil Engineering

Strengthening of Wooden Cross arms in 230 kV Transmission Structures Using Glass Fibre Reinforced Polymer (GFRP) Wrap

Shahi, Arash

20 August 2008

There are approximately 6000 Gulfport-type wood structures used to support 1600 km of 230 kV electrical transmission lines in Ontario. An unexpected structural failure caused by wood deterioration has been recognized as a major risk to the safety of these transmission lines. Since the reliability of the electricity transmission and distribution lines is extremely important to the electrical industry and other users of electricity, failure of these structures can result in devastating incidents. Due to the remote location of the transmission network and the requirement to keep the power lines in continuous service, replacement of the Gulfport structures has proved to be very difficult and expensive. This research program investigated the use of Glass Fibre Reinforced Polymer (GFRP) wrap as a light weight and durable strengthening system that can be applied to the existing structures without any interruptions in the functionality of the transmission lines. A total of three control specimens and three strengthened samples were tested in Phase I of the experimental program, which was designed as a feasibility study. It was concluded that the average strength of strengthened samples was 42% higher than the average strength of the control samples, and was greater than the end of life (EOL) threshold of 30 MPa for the cross arms. Therefore, the proposed strengthening system was concluded to be an effective solution for strengthening the deteriorated cross arms of the Gulfport structures. Taguchi methods and Analysis of Variation (ANOVA) were employed in Phase II to optimize the proposed strengthening system. The optimal configuration was determined to be the application of the filler material, non-sanded surface, and the shorter width of wrap (width of 0.6 m). The mean strength of the optimal configuration was estimated to be 52 MPa with a 95% confidence interval of: 38.7 MPa < True Mean < 65.3 MPa. Phase III confirmed the estimated mean and the confidence interval for the optimal configuration in Phase II. The strengthening system changed the failure mode from combined shear-flexure failure to pure flexure and resulted in more consistent strength and stiffness values. The strain values of the GFRP wrap showed that a single layer of wrap was sufficient for the confinement purposes.

Strengthening

GFRP Wrap

Glass Fibre Reinforced Polymer

Wood

Timber

Transmission Structure

230 kV

Civil Engineering

Μελέτη περίσφιγξης υποστηλωμάτων ορθογωνικής διατομής μεγάλου λόγου πλευρών με ινοπλισμένα πολυμερή (FRP) και ινοπλέγματα σε ανόργανη μήτρα (TRM)

Φωτάκη, Αιμιλία

02 March 2015

Αντικείμενο της παρούσας Διατριβής Διπλώματος Ειδίκευσης είναι η κατά βάση πειραματική διερεύνηση της αποτελεσματικότητας περίσφιγξης ορθογωνικών υποστυλωμάτων με μεγάλο λόγο πλευρών, ενισχυμένων με μανδύες ινοπλισμένων πολυμερών και σύνθετων υλικών ανόργανης μήτρας. Το πειραματικό πρόγραμμα διεξήχθη στο Εργαστήριο Μηχανικής και Τεχνολογίας Υλικών του Τμήματος Πολιτικών Μηχανικών του Πανεπιστημίου Πατρών. Το πρόγραμμα αυτό, περιελάμβανε δύο σειρές δοκιμίων. Η πρώτη περιελάμβανε έξι δοκίμια και η δεύτερη δέκα. Η κατηγοριοποίηση σε σειρές έγινε με βάση το λόγο πλευρών των δοκιμίων. Έτσι, την πρώτη σειρά αποτέλεσαν δοκίμια με λόγο πλευρών (3:1), ενώ τη δεύτερη δοκίμια με λόγο πλευρών (4:1). Ένα δοκίμιο από κάθε σειρά δοκιμάσθηκε χωρίς ενίσχυση και αποτέλεσε μέτρο σύγκρισης για όλα τα υπόλοιπα. Τρία δοκίμια από κάθε σειρά ενισχύθηκαν με τρείς στρώσεις FRP και με θυσάνους. Ακόμα, ένα δοκίμιο από κάθε σειρά ενισχύθηκε με δύο στρώσεις FRP, χωρίς χρήση θυσάνου. Επίσης, δύο υποστυλώματα από τη δεύτερη σειρά ενισχύθηκαν με δύο στρώσεις FRP, θυσάνους και δύο επιπρόσθετες στρώσεις FRP τύπου U, στις δύο μικρές πλευρές. Τέλος, ένα δοκίμιο από κάθε σειρά ενισχύθηκε με τέσσερις στρώσεις TRΜ, ενώ άλλο ένα με τέσσερις στρώσεις TRΜ και με θυσάνους. / The subject of this thesis is the experimental investigation of the effectiveness of confining rectangular columns with large aspect ratio, reinforced with fiber reinforced polymers and with tensile reinforced mortars. The experimental program was conducted at the Laboratory of Engineering and Technology of Materials in Civil Engineering, University of Patras. This program is consisted of two sets of samples. The first included six small scale columns and the second ten. The categorization in series was based on the aspect ratio of the specimens. So specimens with aspect ratio (3: 1) were included in the first series, while the second included specimens with aspect ratio (4: 1). One specimen from each series was tested without any reinforcement and became the comparison for all the rest. Three specimens from each series were reinforced with three layers of FRP and anchors. Still, a sample from each series was reinforced with two layers of FRP, without use of anchors. Also, two columns of the second series of amplified with two layers FRP, anchors and two additional layers of FRP type U, in the two smaller sides. Finally, a sample from each series was reinforced with four layers TRM, while another one to four layers TRM and anchors.

Ινοπλισμένα πολυμερή

624.177 25

Fibre-reinforced plastic (FRP)

Textile-reinforced mortar (TRM)

Experimental Evaluation of the Bond Dependent Coefficient and Parameters which Influence Crack Width in GFRP Reinforced Concrete

McCallum, Brittany

28 March 2013

Reinforcement of concrete flexural components has been traditionally provided by steel rebar; however, durability concerns and life maintenance costs of this product have powered the emergence of fibre reinforced polymers (FRP) as reinforcement in concrete. FRP products hold tremendous promise but their application can be constrained due to design challenges resulting from a reduced modulus of elasticity. The ability to meet serviceability behavior, such as crack width and deflection, is commonly the limiting factor for design. Therefore, the area of FRP reinforcement provided is often greater than the amount required for strength alone and this has significant impacts on the project economics. The bond dependent coefficient (kb) of FRP is required for serviceability design purposes in order to account for the bonding capability of FRP to concrete. The values of this coefficient reported in experimental studies are highly variable, resulting in unreliable crack response predictions. Therefore, a more consistent interpretation and calculation must be found for the bond dependent coefficient due to its critical importance in design. The bond dependent coefficient, as well as physical parameters which influence crack width in GFRP reinforced concrete, were investigated experimentally in this study using a total of 33 specimens. The test procedure was taken from a procedure being developed by the American Concrete Institute (ACI) Committee 440 and was evaluated and modified as required during testing. Phase I testing was used to investigate and determine the physical parameters which had the most significant influence on cracking behaviour and bonding capability. Using significant findings from Phase I, Phase II testing was structured to focus on the interpretation of the bond dependent coefficient and the statistical variation in a set of 5 identical test specimens. Current design equations, as recommended by ACI 440.1R-06 and CHBDC CAN/CSA-S6-06, were used for the calculation of the bond dependent coefficient for all specimens. Interpretation of the bond dependent coefficient was considered using the stress-level approach and newly developed slope approach. Results of the study indicated that the high variability of kb was likely due to its interpretation. Current design equations force a zero intercept, neglecting the fact that concrete does not crack immediately upon loading. In addition, clear definitions of service stress and maximum crack width are ambiguous, further complicating the calculation of the bond dependent coefficient. This resulted in a range of kb values for a given beam despite the fact that kb is inherently a material property of the bar. The behaviour of specimens following load cycling was also very different than the initial loading cycle and consequently, kb was also significantly different. As structures in the field will be subjected to continual loading and unloading, the effect of cyclic loading becomes a consideration in the calculation of kb.

Bond

Crack width

Fibre reinforced polymers (FRP)

Bond dependent coefficient (kb)

Concrete