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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
1

Effect of FRP Anchors on the FRP Rehabilitation of Shear Critical RC Beams and Flexure Critical RC Slabs

Baggio, Daniel Frank 20 February 2013 (has links)
The use of fiber-reinforced polymer (FRP) composites as a repair and strengthening material for reinforced concrete (RC) members has increased over the past twenty years. The tendency for FRP sheets to debond at loads below their ultimate capacity has prompted researchers to investigate various approaches and designs to increase the efficiency of FRP strengthening systems. Various anchors, wrapping techniques and clamps have been explored to postpone and/or delay the debonding process which results in premature failure. FRP anchors are of particular interest because they can be selected to have the same material properties as the FRP sheets that are installed for strengthening or repair of the RC member and can be done so using the same adhesives and installation techniques. This research study aimed to investigate the effectiveness of using commercially manufactured FRP anchors to secure FRP sheets installed to strengthen and repair RC beams in shear and RC slabs in flexure. Twenty one shear critical RC beams were strengthened in shear with u-wrapped FRP sheets and FRP anchors. Eight RC one-way slabs were strengthened in flexure with FRP sheets and FRP anchors. The test variables include the type of FRP sheets (GFRP,CFRP), type of FRP anchors (CFRP, GFRP) and the strengthening configuration. The test results of the shear critical RC beams revealed that the installation of commercially manufactured FRP anchors to secure externally applied u-wrap FRP sheets improved the shear behaviour of the strengthened beam. The installation of FRP anchors to secure u-wrapped FRP sheets provided an average 15% increase in the shear strength over companion unanchored beams and improved the ductility of failure experienced with the typical shear failure in beams. The use of FRP anchors allowed the FRP sheets to develop their tensile capacity. Premature failure by FRP debonding was eradicated with the presence of FRP anchors and the failure modes of the strengthened beams with FRP anchors was altered when compared to the companion unanchored beam. Additionally, as the width of a u-wrapped FRP sheet was increased; larger increases in strength were obtained when FRP anchors were used. The test results of the flexure critical RC slabs revealed that the installation of commercially manufactured FRP anchors to secure externally applied u-wrapped FRP sheets improved the behaviour of strengthened slabs. Installation of FRP anchors to secure flexural FRP sheets provided an average 17% increase in strength over companion unanchored beams. The use of FRP anchors allowed the FRP sheets to develop their full tensile strength. Premature failure by CFRP debonding was not eliminated with the presence of FRP anchors; rather the critical failure zone was shifted from the bottom soffit of the slab to the concrete/steel rebar interface. The failure modes of slabs with FRP anchors were altered for all specimens when compared to the companion unanchored slab. The effective strain in the FRP sheet was predicted and compared with the experimental results. The efficiency of FRP anchors defined as the ratio of effective strain in the FRP sheet with and without anchors was related to the increase in strength in beams and slabs. A good correlation was established between the FRP anchor efficiency and the increase in strength. A step-by-step FRP anchor installation procedure was developed and a model to predict the number of FRP anchors required to secure a FRP sheet was proposed. This is the most comprehensive examination of beams and slabs strengthened with FRP sheets and FRP anchors conducted to date. This study provides an engineer with basic understanding of the mechanics, behaviour and failure modes of beams and slabs strengthened with FRP sheets and anchors.
2

Effect of FRP Anchors on the FRP Rehabilitation of Shear Critical RC Beams and Flexure Critical RC Slabs

Baggio, Daniel Frank 20 February 2013 (has links)
The use of fiber-reinforced polymer (FRP) composites as a repair and strengthening material for reinforced concrete (RC) members has increased over the past twenty years. The tendency for FRP sheets to debond at loads below their ultimate capacity has prompted researchers to investigate various approaches and designs to increase the efficiency of FRP strengthening systems. Various anchors, wrapping techniques and clamps have been explored to postpone and/or delay the debonding process which results in premature failure. FRP anchors are of particular interest because they can be selected to have the same material properties as the FRP sheets that are installed for strengthening or repair of the RC member and can be done so using the same adhesives and installation techniques. This research study aimed to investigate the effectiveness of using commercially manufactured FRP anchors to secure FRP sheets installed to strengthen and repair RC beams in shear and RC slabs in flexure. Twenty one shear critical RC beams were strengthened in shear with u-wrapped FRP sheets and FRP anchors. Eight RC one-way slabs were strengthened in flexure with FRP sheets and FRP anchors. The test variables include the type of FRP sheets (GFRP,CFRP), type of FRP anchors (CFRP, GFRP) and the strengthening configuration. The test results of the shear critical RC beams revealed that the installation of commercially manufactured FRP anchors to secure externally applied u-wrap FRP sheets improved the shear behaviour of the strengthened beam. The installation of FRP anchors to secure u-wrapped FRP sheets provided an average 15% increase in the shear strength over companion unanchored beams and improved the ductility of failure experienced with the typical shear failure in beams. The use of FRP anchors allowed the FRP sheets to develop their tensile capacity. Premature failure by FRP debonding was eradicated with the presence of FRP anchors and the failure modes of the strengthened beams with FRP anchors was altered when compared to the companion unanchored beam. Additionally, as the width of a u-wrapped FRP sheet was increased; larger increases in strength were obtained when FRP anchors were used. The test results of the flexure critical RC slabs revealed that the installation of commercially manufactured FRP anchors to secure externally applied u-wrapped FRP sheets improved the behaviour of strengthened slabs. Installation of FRP anchors to secure flexural FRP sheets provided an average 17% increase in strength over companion unanchored beams. The use of FRP anchors allowed the FRP sheets to develop their full tensile strength. Premature failure by CFRP debonding was not eliminated with the presence of FRP anchors; rather the critical failure zone was shifted from the bottom soffit of the slab to the concrete/steel rebar interface. The failure modes of slabs with FRP anchors were altered for all specimens when compared to the companion unanchored slab. The effective strain in the FRP sheet was predicted and compared with the experimental results. The efficiency of FRP anchors defined as the ratio of effective strain in the FRP sheet with and without anchors was related to the increase in strength in beams and slabs. A good correlation was established between the FRP anchor efficiency and the increase in strength. A step-by-step FRP anchor installation procedure was developed and a model to predict the number of FRP anchors required to secure a FRP sheet was proposed. This is the most comprehensive examination of beams and slabs strengthened with FRP sheets and FRP anchors conducted to date. This study provides an engineer with basic understanding of the mechanics, behaviour and failure modes of beams and slabs strengthened with FRP sheets and anchors.
3

Experimental Evaluation of Flexural Strengthening Methods for Existing Reinforced Concrete Members Using Fiber Reinforced Polymer (FRP) Systems

Robert Richard Jacobs (9873083) 18 December 2020 (has links)
<div>Research has shown that many adjacent box beam bridges in Indiana experience premature deterioration. Primarily caused by leaking joints between beams, this deterioration leads to corrosion and/or fracturing of prestressing strands, ultimately resulting in flexural deficiency of the bridge. A testing program was designed to simulate this observed deterioration by constructing test specimens and implementing various strengthening techniques using fiber reinforced polymer (FRP) systems. The objective of this testing program is to investigate the effectiveness of FRP strengthening systems to increase or even regain the full capacity of beams that have effectively lost tension reinforcing steel due to corrosion. The FRP-strengthened beam specimens incorporate the use of near-surface-mounted and externally bonded systems. Reinforcing bars in the beams are excluded or cut to simulate deterioration. Furthermore, two different methods of end anchorage for the externally bonded sheets, FRP fan anchorage and U-wrap anchorage, are investigated. Results and conclusions from the testing program are described in order to help advise best practices in implementing the aforementioned strengthening systems. </div>
4

Ενίσχυση πλακοδοκών οπλισμένου σκυροδέματος σε τέμνουσα με μανδύες ινοπλισμένων πολυμερών και αγκύρια ινών / Shear strengthening of T-shaped RC beams with FRP U-jackets and FRP anchors

Κούτας, Λάμπρος 28 September 2010 (has links)
Στην παρούσα διατριβή διερευνήθηκε πειραματικά, η συμπεριφορά διατάξεων ενίσχυσης πλακοδοκών Οπλισμένου Σκυροδέματος, σε τέμνουσα, που αποτελούνται από το συνδυασμό τρίπλευρων μανδυών από Ινοπλισμένα Πολυμερή και αγκυρίων ινών. Πρόκειται για διατάξεις ενίσχυσης που λόγω της παρουσίας των αγκυρίων, καλούνται να υπερκεράσουν τις αδυναμίες της τεχνικής των «ανοικτών» μανδυών, δηλαδή της συνήθους τεχνικής ενίσχυσης πλακοδοκών σε τέμνουσα. Οι αδυναμίες της εν λόγω τεχνικής, οφείλονται στην ανεπαρκή αγκύρωση των άκρων του μανδύα. Η πειραματική διερεύνηση της συμπεριφοράς τέτοιων διατάξεων ενίσχυσης, έγινε με εφαρμογή τους σε τέσσερα δοκίμια πλακοδοκών Οπλισμένου Σκυροδέματος, και συγκρίθηκε με τη συμπεριφορά ενός δοκιμίου αναφοράς που δεν έφερε καμία διάταξη ενίσχυσης, καθώς και με τη συμπεριφορά ενός δοκιμίου ενισχυμένου μόνο με τρίπλευρο «ανοικτό» μανδύα ΙΟΠ, απουσία αγκυρίων. Όλα τα δοκίμια, υποβλήθηκαν σε μονοτονική φόρτιση μέσω συγκεντρωμένου φορτίου με φορά ώστε να προκαλείται θλίψη στο άνω πέλμα της δοκού, δηλαδή στην πλάκα, και οι συνθήκες στήριξης ήταν τέτοιες που να προσομοιώνουν αμφιέρειστη δοκό. Τα πρώτα Κεφάλαια της διατριβής αποτελούνται από την εισαγωγή, τη βιβλιογραφική ανασκόπηση και την περιγραφή της πειραματικής διαδικασίας. Στα επόμενα Κεφάλαια, πέραν της παρουσίασης των πειραματικών αποτελεσμάτων, επιχειρείται ο προσδιορισμός της αποδοτικότητας με παράλληλη προσέγγιση της συμπεριφοράς των διατάξεων ενίσχυσης με έμφαση στον τρόπο με τον οποίον τα αγκύρια την επηρεάζουν. Στο τελευταίο Κεφάλαιο παρουσιάζεται ο κεντρικός άξονας της διατριβής περιλαμβάνοντας και τη σύνοψη των συμπερασμάτων. / In the present thesis, the effectiveness of shear strengthening schemes for T-Shaped RC beams, consisting of FRP U-Jackets and FRP anchors, was experimentally investigated. For this purpose, six full-scale of T-Shaped RC beams were produced. One specimen served as reference (unstrengthened) beam, whereas the remaining five received FRP U-jackets; out of the latter FRP anchors were used in four beams in order to enhance the effectiveness of the strengthening schemes, whereas no anchoring system was applied to the fifth beam. All specimens were tested under monotonic loading causing compression to the wide part of the section. The first chapter of this dissertation discusses the necessity of strengthening beams in shear and introduce the objective of the study. A relatively extended literature overview about shear strengthening with externally bonded reinforcement is included in the second chapter. The purpose of the third chapter is to describe the way the specimens were designed and constructed. The strengthening procedure, the experimental setup and the materials’ properties are also included in this chapter. The test results are presented and discussed in the fourth chapter. In the fifth chapter calculations regarding the effectiveness of the strengthening schemes are presented, along with an attempt to understand their general behavior while emphasizing on the way the FRP anchors affect it. The final chapter includes the general conclusions of the present study.

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