Blast Performance of Reinforced Concrete Columns Protected by FRP Laminates

Kadhom, Bessam

January 2016

Recent terrorist attacks on critical infrastructures using car bombs have heightened awareness on the needs for blast resistance of structures. Blast design of civilian buildings has not been a common practice in structural design. For this reason, there is now an urgent need to mitigate the potentially devastating effects of blast shock waves on existing structures. The current research project, the results of which are reported in this dissertation, aims to expand knowledge on blast resistance of reinforced concrete building columns, while developing a technology and design procedure for protecting critical buildings columns against the damaging effects of impulsive blast loads through the use of externally applied fibre-reinforced polymer (FRP) jackets of different material architecture. The research project has a significant experimental component, with analytical verifications. A total of thirty two reinforced concrete columns were experimentally investigated under the effects of simulated blast loads using the University of Ottawa Shock Tube. Column dimensions were 150 mm x 150 mm in cross section and 2438 mm in length. Each concrete column was reinforced longitudinally with four 10M rebars which were tied laterally with 6.3 mm closed steel hoops, spaced at 37.5 mm and 100 mm c/c, representing seismic and non-seismic column details, respectively. The experimental research had two phases. Phase-I (sub-study) included blast tests of eight as-built, seismically detailed columns. The behaviour of these columns was explored under single and multiple blast shots, with and without the application of pre-blast axial loads. Phase-II (main-study) included column tests of different carbon FRP (CFRP) designs to investigate the significance of the use of different CFRP column jacket designs on dynamic response of twenty four seismic and non-seismic RC columns. Analytical investigation was conducted to assess and verify the significance of experimentally investigated parameters on column response. These included the use of Single-Degree-of-Freedom (SDOF) dynamic inelastic analysis, generation of dynamic resistance functions, the effects of variable axial loads, different plastic hinge lengths and the influence of secondary moments (P- moments) on column behaviour. The results indicate that the loading history has effects on column response, with multiple shots reducing column stiffness, and affecting dynamic response of columns relative to single blast shots of equivalent magnitude. The effect of concrete strength within the normal-strength concrete range is to increase strength and decrease deformations. Columns with CFRP jackets have considerable improvements in column deformability, with additional increases in column strength. The CFRP laminate design influences performance, with jackets having fibres in ±45o orientation especially improving column ductility and increasing plastic hinge lengths, thereby permitting redistribution of stresses and dissipating blast energy. Axial gravity loads vary during blast loads and can affect column strength. It was shown that SDOF dynamic inelastic analysis does capture key structural performance parameters in blast analysis. The consideration of experimentally observed parameters in column analysis; including the influence of CFRP design and associated change in plastic hinge length, variable axial load during response, and secondary moment (P- moments) result in significant improvements in the accuracy of blast analysis. The experimental results and the suggested improvements to the SDOF analysis technique can be used to implement a performance-based design approach recommended as part of the current research project for design of CFRP protection systems for concrete columns.This research project was conducted jointly by the National Research Council Canada (NRC) and the University of Ottawa.

Blast loads

FRP Laminates

RC columns

Shock tube

Retrofit of Seismically Deficient RC Columns with Textile- Reinforced Mortar (TRM) Jackets

Bournas, Dionysios A., Triantafillou, Thanasis C., Papanicolaou, Catherine G.

03 June 2009

The effectiveness of a new structural material, namely textilereinforced mortar (TRM), was investigated experimentally in this study as a means of confining old-type reinforced concrete columns with limited capacity due to bar buckling or due to bond failure at lap splice regions. Comparisons with equal stiffness and strength fiber-reinforced polymer (FRP) jackets allow for the evaluation of the effectiveness of TRM versus FRP. Tests were carried out on full scale non-seismically detailed RC columns subjected to cyclic uniaxial flexure under constant axial load. Thirteen cantilever-type specimens with either continuous longitudinal reinforcement (smooth or deformed) or lap splicing of longitudinal bars at the floor level were constructed and tested. Experimental results indicated that TRM jacketing is quite effective as a means of increasing the cyclic deformation capacity of old-type RC columns with poor detailing, by delaying bar buckling and by preventing splitting bond failures in columns with lap spliced bars. Compared with their FRP counterparts, TRM jackets used in this study were found to be equally effective in terms of increasing both the strength and deformation capacity of the retrofitted columns. From the response of specimens tested in this study, it can be concluded that TRM jacketing is an extremely promising solution for the confinement of reinforced concrete columns, including poorly detailed ones with or without lap splices in seismic regions.

confinement

lap-splices

RC columns

seismic retrofitting

textile-reinforced mortars

ddc:620

rvk:ZI 2000

Evaluation of the Effect of Reinforcement Corrosion on the Axial and Flexural Performance of RC Columns

Dabas, Maha

25 July 2022

The heavy use of de-icing salts in the winter to accommodate heavy traffic has been the most detrimental cause of chloride-induced corrosion in Canadian reinforced concrete (RC) bridge infrastructure. In addition, the rise of greenhouse emissions and subsequent increase in the mean surface temperature have increased the potential risk of carbonation-induced corrosion. It is believed that the synergistic effect of multiple deteriorating mechanisms will accelerate the incidence of reinforcement corrosion in Canadian infrastructure. Over time, premature deterioration of RC bridges due to reinforcement corrosion leads to concrete cover cracking and spalling, loss of bond between reinforcement and concrete, and reduction in the structural capacity and ductility of the structure. There is limited research work that has examined the effect of corrosion on the structural performance of RC columns. This research has evaluated the axial and flexural capacity of corroded RC columns exposed to different levels and patterns of reinforcement corrosion. An experimental testing campaign of ten RC columns was conducted in two stages. During the first stage, eight columns were subjected to an accelerated corrosion regime by impressing a constant current for 137 days. In the second stage, all ten columns were subjected to an axial quasi-static load until failure. Five columns were loaded concentrically, while the remaining five were loaded eccentrically. The structural performance (residual strength, ductility, resilience, stiffness, toughness and failure mode) of the columns were analyzed from load-displacement curves of the entire and mid-span length of the columns. The experimental results show that corrosion of the ties directly affects the column's post-peak response even at low corrosion levels. Columns with corroded ties had a brittle failure, and the residual ductility and toughness were significantly reduced. On the other hand, longitudinal reinforcement corrosion primarily affects the residual strength of the columns, which is prominent at a medium level of corrosion. At high levels of both longitudinal and transverse reinforcement corrosion, the residual strength, ductility, and axial stiffness are significantly reduced. This is accompanied by a significant deterioration of the cover and local buckling of the longitudinal rebars, which is attributed to a significant reduction in the confinement pressure of the core concrete. A three-dimensional non-linear finite element model (3D-NLFEM) of the columns was developed using the finite element package DIANA (v.10.4) and validated with the experimental results. The effect of reinforcement corrosion on the structural response of columns was modelled as a change in the mechanical and geometrical properties of concrete and steel materials. This was achieved by integrating constitutive and deteriorating models into the 3D-NLFEM. The model accounts for the bond-slip behaviour between longitudinal bars and concrete (for eccentrically loaded columns), the confinement of the concrete core and strength reduction of the concrete cover, and the buckling potential of longitudinal reinforcement. The validated model was used to conduct a parametric analysis to investigate the effect of several influencing variables such as damage level and patterns and to explore scenarios beyond those tested in a laboratory setting. Finally, an analytical model based on sectional analysis was developed and compared with both the experimental and FEM results. The proposed analytical approach was developed by integrating deteriorating models and incorporating data collected from field investigation. Based on this evaluation, a practical analytical approach is proposed to estimate the nominal residual capacity of corroded columns considering the reduction in confinement effects, bond loss and potential buckling. The results from the experimental, numerical, and analytical studies correlate well. This work's outcome will contribute to a better understanding of the axial and flexural performance in terms of the ultimate capacity, post peak response and failure mode of RC columns affected by the reinforcement corrosion and static loading. Moreover, it provides a simplified analytical tool for practicing engineers to predict the axial and flexural capacity of deteriorated bridges vulnerable to reinforcement corrosion and increased traffic volume.

Reinforcement corrosion

RC columns

Axial and flexural response

Finite element modelling

Experimental testing

Analytical approach

Μελέτη περίσφιγξης υποστυλωμάτων ορθογωνικής διατομής μεγάλου λόγου πλευρών με ινοπλισμένα πολυμερή και με ινοπλέγματα σε ανόργανη μήτρα

Χουτοπούλου, Ελένη

24 February 2015

Αντικείμενο της παρούσας Διατριβής Διπλώματος Ειδίκευσης αποτελεί η πειραματική διερεύνηση της αποτελεσματικότητας της περίσφιγξης υποστυλωμάτων οπλισμένου σκυροδέματος με μεγάλο λόγο πλευρών με μανδύες ινοπλισμένων πολυμερών και με μανδύες ινοπλεγμάτων σε ανόργανη μήτρα. Για το σκοπό αυτό διενεργήθηκε εκτενές πειραματικό πρόγραμμα στο Εργαστήριο Μηχανικής και Τεχνολογίας Υλικών του Τμήματος Πολιτικών Μηχανικών του Πανεπιστημίου Πατρών. Το πειραματικό πρόγραμμα περιελάμβανε 18 υποστυλώματα υπό κλίμακα 3/5 ύψους 770 mm τα οποία χωρίστηκαν σε δύο ομάδες, ανάλογα με το λόγο των πλευρών τους (1η ομάδα: με λόγο πλευρών 1:3, 150×450mm, 2η ομάδα: με λόγο πλευρών 1:4, 150×600mm). Δύο από τα υποστυλώματα παρέμειναν χωρίς ενίσχυση και αποτέλεσαν τα δοκίμια αναφοράς για τα ενισχυμένα δοκίμια, τα οποία περισφίχθηκαν με μανδύες ΙΟΠ και ΙΑΜ. Τα συστήματα ενίσχυσης που χρησιμοποιήθηκαν περιελάμβαναν μανδύες ΙΟΠ ινών άνθρακα με μια, δύο ή τρεις στρώσεις, χωρίς ή με αγκύρια ινών άνθρακα μορφής θυσάνου καθώς και μανδύα με δύο στρώσεις περιμετρικά του δοκιμίου και μανδύα μορφής U και αγκύρια ινών. Επιπλέον, εξετάστηκαν και μανδύες με τέσσερεις στρώσεις ινοπλέγματος με ίνες άνθρακα σε ανόργανη μήτρα με και χωρίς αγκύρια ινών άνθρακα μορφής θυσάνου εμποτισμένων σε εποξειδική ρητίνη. Η παρούσα διατριβή αποτελείται από οχτώ κεφάλαια, κάθε ένα από τα οποία διαχωρίζεται σε κατάλληλες ενότητες, υποενότητες και παραγράφους. Στο πρώτο και δεύτερο Κεφάλαιο γίνεται μια εισαγωγή στα σύνθετα υλικά με περιγραφή των επιμέρους συστατικών τους, των χαρακτηριστικών ιδιοτήτων τους καθώς και των παραγόντων που επηρεάζουν τη συμπεριφορά τους. Στο τρίτο Κεφάλαιο πραγματοποιείται βιβλιογραφική ανασκόπηση για την περίσφιγξη υποστυλωμάτων, όπου αρχικά περιγράφονται συμβατικές τεχνικές ενίσχυσης που περιλαμβάνουν νέους μανδύες οπλισμένου σκυροδέματος, μεταλλικά ελάσματα, μεταλλικούς μανδύες κλπ και στη συνέχεια περιγράφονται τεχνικές ενίσχυσης με σύνθετα υλικά. Περιγράφεται ο καταστατικός νόμος που διέπει τη συμπεριφορά του περισφιγμένου με μανδύες σύνθετων υλικών σκυροδέματος και παρουσιάζονται συνοπτικά πειραματικές μελέτες από τη διεθνή βιβλιογραφία που αφορούν τη διερεύνηση της αποτελεσματικότητας της μεθόδου ενίσχυσης µε ΙΟΠ σε υποστυλώματα με μικρό και μεγάλο λόγο πλευρών. Τέλος, το κεφάλαιο ολοκληρώνεται με συνοπτική αναφορά πειραματικών μελετών σε δοκίμια περισφιγμένα με μανδύες σε ανόργανη μήτρα. Στο τέταρτο Κεφάλαιο παρουσιάζεται η πειραματική διαδικασία που ακολουθήθηκε για την κατασκευή των δοκιμίων καθώς και οι παράμετροι που διερευνήθηκαν. Συγκεκριμένα, περιγράφονται όλα τα υλικά που χρησιμοποιήθηκαν, τα διάφορα συστήματα ενίσχυσης που εφαρμόστηκαν καθώς και οι διαδικασίες που ακολουθήθηκαν από την προετοιμασία των δοκιμίων μέχρι την ενίσχυσής τους. Στο τέλος του κεφαλαίου γίνεται μια σύντομη περιγραφή της πειραματικής διάταξης και του επιμέρους μηχανικού εξοπλισμού που χρησιμοποιήθηκε για την υλοποίηση των δοκιμών μονοαξονικής θλίψης. Στο πέμπτο Κεφάλαιο παρουσιάζονται διεξοδικά τα αποτελέσματα όλων των δοκιμίων που συμμετείχαν στο πειραματικό πρόγραμμα. Πιο συγκεκριμένα, περιγράφονται οι τρόποι αστοχίας των δοκιμίων συνοδεία φωτογραφικού υλικού και παρατίθενται οι καμπύλες τάσης – παραμόρφωσης τόσο για κάθε ένα ξεχωριστά όσο και συγκεντρωτικά για κάθε ομάδα. Στο έκτο Κεφάλαιο γίνεται σύγκριση των αποτελεσμάτων όλων των πειραμάτων που διεξήχθησαν στο Εργαστήριο Μηχανικής και Τεχνολογίας Υλικών σε υποστυλώματα με λόγους πλευρών 1:3 και 1:4 περισφιγμένα με μανδύες ΙΟΠ και ΙΑΜ προκειμένου να εξαχθούν γενικότερα συμπεράσματα πάνω στην επίδραση του υλικού της μήτρας, του αριθμού των στρώσεων και της ύπαρξης αγκυρίων στην αποτελεσματικότητα της περίσφιγξης. Στο έβδομο Κεφάλαιο παρουσιάζονται τα αποτελέσματα από ένα αναλυτικό προσομοίωμα που χρησιμοποιήθηκε για την πρόβλεψη του μέγιστου θλιπτικού φορτίου και της οριακής παραμόρφωσης αστοχίας των περισφιγμένων με μανδύες ΙΟΠ και ΙΑΜ. Επιπλέον, γίνεται σύγκριση των αποτελεσμάτων του αναλυτικού προσομοιώματος με τα πειραματικά δεδομένα και εξετάζεται κατά πόσο αυτό το προσομοίωμα μπορεί να χρησιμοποιείται για υποστυλώματα με μεγάλο λόγο πλευρών, μετά από αλλαγή κάποιων παραμέτρων του. Στο όγδοο και τελευταίο Κεφάλαιο, παρουσιάζονται συνοπτικά τα τελικά συμπεράσματα που προέκυψαν αρχικά από την πειραματική διαδικασία και στη συνέχεια από τη χρήση του αναλυτικού προσομοιώματος. Τέλος, γίνονται και μερικές προτάσεις για περαιτέρω έρευνα πάνω σε υποστυλώματα με μεγάλο λόγο πλευρών. / The present study investigates experimentally the effectiveness of the confinement of reinforced concrete (RC) columns with high aspect ratio (wall-like RC columns) retrofitted either with fiber-reinforced polymer (FRP) or with textile-reinforced mortars (TRM) jackets. For this purpose an extensive experimental program was conducted at the Structural Materials Laboratory of the Civil Engineering Department at the University of Patras. A total of 18 identical rectangular reinforced concrete columns were constructed in a scale of 3/5 and 770 mm height so that the slenderness effects could be eliminated and tested in uniaxial compression. The columns were separated in two groups according to their aspect ratio; the first group consisted of seven RC column specimens with cross section dimensions 150mm by 450mm and an aspect ratio equal to 3, and the second group consisted of eleven RC column specimens with cross section dimensions 150mm by 600mm and an aspect ratio equal to 4. To facilitate FRP and TRM wrapping, the four corners were chamfered with a radius equal to 20mm. A number of parameters were investigated such as the kind of the matrix material (organic and inorganic), the number of layers of the jackets (1, 2, 3 and 4), the role of different cross section aspect ratios (3 and 4), the effectiveness of spike anchors (resin-impregnated fiber rovings) and local strengthening with U shape jacketing placed at the smaller sides of the columns. The first chapter provides general information on FRP materials describing their individual components, their characteristic properties, the factors affecting their behavior as well as the basic techniques for their application. The second chapter describes the composite materials in inorganic matrix (TRM) and presents a comparison between the two composite material strengthening systems. In the third chapter a brief literature review is provided about the confinement of columns with conventional techniques (e.g. steel plating, steel jacketing, RC jacketing) as well as with composite materials. The constitutional law of confined concrete with jackets of composite materials is described. Furthermore some experimental studies from the international literature are presented concerning the effectiveness of the confinement with FRP jackets of columns with small and high aspect ratio. Finally, the chapter concludes with a brief reference to experimental studies on specimens confined with jackets in inorganic matrix (TRM jackets). The fourth chapter presents the procedure for constructing and retrofitting the specimens including the materials used (carbon fiber fabric and textile, carbon fiber spike anchors, epoxy resin, inorganic matrix) as well as the equipment used for uniaxial compression tests. In the fifth chapter the results for each specimen are given presenting their failure mode and the corresponding load - displacement curve. In the following chapter the results for each group are compared in order to establish general conclusions on the effect of the kind of the matrix material, the number of layers and the existence of FRP anchors in confinement of wall-like RC columns. The seventh chapter presents the results of an analytical model used to predict the maximum compressive load and the ultimate deformation of specimens confined with FRP or TRM jackets. A comparison between the experimental and the analytical results is made and it is examined whether this model can be used for columns with high aspect ratio after modifying some of the parameters. The eighth chapter summarises the most important conclusions of all investigations carried out by the present project for both the experimental procedure and the analytical model. Finally, some suggestions for further research on columns with high aspect ratio are listed.

Περίσφιγξη

Ινοπλισμένα πολυμερή

Αγκύρια ινών άνθρακα

Πειράματα

624.183 425

Confinement

Reinforced concrete (RC) columns

Fiber-reinforced polymer (FRP)

Textile-reinforced mortars (TRM)

Rectangular RC columns

Experimental program

Spike anchors

Retrofit of Seismically Deficient RC Columns with Textile- Reinforced Mortar (TRM) Jackets

Bournas, Dionysios A., Triantafillou, Thanasis C., Papanicolaou, Catherine G.

03 June 2009

The effectiveness of a new structural material, namely textilereinforced mortar (TRM), was investigated experimentally in this study as a means of confining old-type reinforced concrete columns with limited capacity due to bar buckling or due to bond failure at lap splice regions. Comparisons with equal stiffness and strength fiber-reinforced polymer (FRP) jackets allow for the evaluation of the effectiveness of TRM versus FRP. Tests were carried out on full scale non-seismically detailed RC columns subjected to cyclic uniaxial flexure under constant axial load. Thirteen cantilever-type specimens with either continuous longitudinal reinforcement (smooth or deformed) or lap splicing of longitudinal bars at the floor level were constructed and tested. Experimental results indicated that TRM jacketing is quite effective as a means of increasing the cyclic deformation capacity of old-type RC columns with poor detailing, by delaying bar buckling and by preventing splitting bond failures in columns with lap spliced bars. Compared with their FRP counterparts, TRM jackets used in this study were found to be equally effective in terms of increasing both the strength and deformation capacity of the retrofitted columns. From the response of specimens tested in this study, it can be concluded that TRM jacketing is an extremely promising solution for the confinement of reinforced concrete columns, including poorly detailed ones with or without lap splices in seismic regions.

info:eu-repo/classification/ddc/620

ddc:620