Flexural steel anchorage performance at diagonal crack locations /

Triska, Mary Ann.

January 1900

Thesis (M.S.)--Oregon State University, 2010. / Printout. Includes bibliographical references (leaves 112-115). Also available on the World Wide Web.

Further experiments on the seismic performance of structural concrete beam-column joints designed in accordance with the principles of damage avoidance : a thesis submitted in partial fulfilment of the requirements for the degree of Master of Engineering in Civil Engineering at the University of Canterbury /

Li, Luoman.

January 2006

Thesis (M.E.)--University of Canterbury, 2006. / Typescript (photocopy). Includes bibliographical references. Also available via the World Wide Web.

Effects of diagonal steel bars on performance of interior beam-column joints constructed with high-strength concrete

Li, Jing, 李靜

January 2003

published_or_final_version / Civil Engineering / Doctoral / Doctor of Philosophy

Joints (Engineering)

Steel bars.

Concrete construction - Joints.

Reinforced concrete.

Cracking of cold drawn resulfurized type 303 hexagon bars

Gault, Paul Alan

January 1982

Thesis (M.S.)--Massachusetts Institute of Technology, Dept. of Materials Science and Engineering, 1982. / MICROFICHE COPY AVAILABLE IN ARCHIVES AND SCIENCE / Includes bibliographical references. / by Paul Alan Gault. / M.S.

Materials Science and Engineering.

Austenitic stainless steel Fracture

Steel bars Fracture

Flexural Strength, Ductility, and Serviceability of Beams that Contain High-Strength Steel Reinforcement and High-Grade Concrete

Yosefani, Anas

06 June 2018

Utilizing the higher capacity steel in design can provide additional advantages to the concrete construction industry including a reduction of congestion, improved concrete placement, reduction in the required reinforcement and cross sections which would lead to savings in materials, shipping, and placement costs. Using high-strength reinforcement is expected to impact the design provisions of ACI 318 code and other related codes. The Applied Technology Council (ATC-115) report "Roadmap for the Use of High-Strength Reinforcement in Reinforced Concrete Design" has identified key design issues that are affected by the use of high-strength reinforcement. Also, ACI ITG-6, "Design Guide for the Use of ASTM A1035 Grade 100 Steel Bars for Structural Concrete" and NCHRP Report 679, "Design of Concrete Structures Using High-Strength Steel Reinforcement" have made progress towards identifying how code provisions in ACI 318 and AASHTO could be changed to incorporate high-strength reinforcement. The current research aims to provide a closer investigation of the behavior of beams reinforced with high-strength steel bars (including ASTM A615 Grade 100 and ASTM A1035 Grades 100 and 120) and high-strength concrete up to 12000 psi. Focus of the research is on key design issues including: ductility, stiffness, deflection, and cracking. The research includes an extensive review of current literature, an analytical study and conforming experimental tests, and is directed to provide a number of recommendations and design guidelines for design of beams reinforced with high-strength concrete and high-strength steel. Topics investigated include: strain limits (tension-controlled and compression-controlled, and minimum strain in steel); possible change for strength reduction factor equation for transition zone (Φ); evaluation of the minimum reinforcement ratio (þmin); recommendations regarding limiting the maximum stress for the high-strength reinforcement; and prediction of deflection and crack width at service load levels. Moreover, this research includes long-term deflection test of a beam made with high grade concrete and high-strength steel under sustained load for twelve months to evaluate the creep deflection and to insure the appropriateness of the current ACI 318 time-dependent factor, λ, which does not consider the yield strength of reinforcement and the concrete grade.

Reinforced concrete -- Testing

Concrete beams -- Testing

Steel bars

Flexure

Reinforced concrete -- Ductility

Civil and Environmental Engineering

Μηχανική συμπεριφορά διαβρωμένων χαλύβων οπλισμού σκυροδέματος / Mechanical behavior of corroded concrete reinforcing steel bars

Παπαδόπουλος, Μιχαήλ

12 February 2008

Το οπλισμένο σκυρόδεμα αποτελεί στις μέρες μας το πιο διαδεδομένο υλικό για την κατασκευή του φέροντος οργανισμού κτιριακών κατασκευών. Παρά την εξαιρετική επίδοση του οπλισμένου σκυροδέματος ως φέροντος υλικού, διαπιστώθηκε ότι στη διάρκεια ζωής των κατασκευών από οπλισμένο σκυρόδεμα, η οποία συχνά ξεπερνά τα 100 χρόνια, παρατηρείται μια βαθμιαία συσσώρευση βλάβης, ένας από τους κύριους παράγοντες της οποίας εντοπίζεται στη διάβρωση του σιδηροπλισμού. Tα τελευταία χρόνια το πρόβλημα της υποβάθμισης της φέρουσας ικανότητας του οπλισμού σκυροδέματος λόγω βλάβης διάβρωσης έχει προσελκύσει το ενδιαφέρον αρκετών ερευνητών παγκοσμίως. Όμως, μέχρι σήμερα ούτε η τεχνολογική σημασία της υποβάθμισης αυτής μπορεί να εκτιμηθεί ικανοποιητικά, κυρίως λόγω της έλλειψης σχετικών συστηματικών μελετών αλλά και επαρκών πειραματικών δεδομένων, ούτε οι φυσικοί μηχανισμοί που συμβάλλουν στην παρατηρούμενη υποβάθμιση των μηχανικών ιδιοτήτων έχουν γίνει πλήρως κατανοητοί. Κατά την εκπόνηση της παρούσας διδακτορικής διατριβής πραγματοποιήθηκε μια συστηματική μελέτη της μηχανικής συμπεριφοράς χαλύβων οπλισμού σκυροδέματος διαβρωμένων τόσο στο φυσικό τους περιβάλλον εντός του σκυροδέματος όσο και σε συνθήκες εργαστηριακής επιταχυμένης διάβρωσης. Με βάση τη σύγκριση της απώλειας μάζας σε συνάρτηση με το χρόνο έκθεσης στο διαβρωτικό μέσο που καταμετρήθηκε στο εργαστήριο, με την απώλεια μάζας δειγμάτων υλικού τα οποία είχαν διαβρωθεί φυσικά σε κατασκευές, κατέστη δυνατή η εξαγωγή ενός εμπειρικού συντελεστή επιτάχυνσης της βλάβης διάβρωσης όταν το υλικό διαβρώνεται με τη μέθοδο της αλατονέφωσης σε σχέση με τη βλάβη φυσικής διάβρωσης. Κατά την παρούσα εργασία εξετάστηκαν οι χάλυβες S400 και S500s, οι οποίοι χρησιμοποιήθηκαν ευρύτατα για κατασκευές του φέροντος οργανισμού κτιρίων στην Ελλάδα κατά το πρόσφατο παρελθόν, καθώς και ο χάλυβας B500c ο οποίος από τα τέλη του 2006 χρησιμοποιείται στην Ελλάδα σχεδόν αποκλειστικά. Για την εξασφάλιση μια επαρκούς πειραματικής βάσης, πραγματοποιήθηκαν περισσότερες από 500 δοκιμές εφελκυσμού σε διαβρωμένα και μη διαβρωμένα δοκίμια. Οι μηχανικές δοκιμές εφελκυσμού έδειξαν ότι οι ιδιότητες αντοχής του διαβρωμένου υλικού παρουσιάζουν μικρή μόνο υποβάθμιση. Παρά ταύτα, η μείωση της διατομής των ράβδων του σιδηροπλισμού λόγω βλάβης διάβρωσης οδηγεί σε αύξηση των εφαρμοζόμενων τάσεων, αφού το βάρος των δομικών στοιχείων των κατασκευών προφανώς δεν μεταβάλλεται. Αυτό έχει ως συνέπεια τη σημαντική μείωση των συντελεστών ασφαλείας. Αντίθετα με τις ιδιότητες αντοχής, παρατηρήθηκε μια σημαντική μείωση στην παραμόρφωση θραύσης του διαβρωμένου υλικού. Η παραμόρφωση θραύσης και η ειδική ενέργεια παραμόρφωσης είναι κρίσιμες τεχνολογικές ιδιότητες σε συνθήκες σεισμού. Για την κατανόηση των φυσικών μηχανισμών που συμβάλλουν στην παρατηρούμενη υποβάθμιση των μηχανικών ιδιοτήτων, διεξήχθη εκτενής μεταλλογραφική μελέτη καθώς και μελέτη των επιφανειών θραύσης του διαβρωμένου υλικού. Παρατηρήθηκε ότι η διάβρωση είναι ομοιόμορφη, ενώ κατά το μήκος των δοκιμίων εντοπίστηκαν περιοχές με εντονότερη και άλλες με λιγότερο έντονη διάβρωση. Επιπλέον, η ανάλυση των επιφανειών θραύσης έδειξε πλήρως όλκιμη συμπεριφορά θραύσης των δοκιμίων ακόμη και στο έντονα διαβρωμένο υλικό. Επομένως, μπορεί να εξαχθεί το συμπέρασμα ότι η υποβάθμιση των μηχανικών ιδιοτήτων εφελκυσμού του χάλυβα οπλισμού οφείλεται κυρίως στην ανομοιομορφία που παρουσιάζει η διατομή του σιδηροπλισμού κατά μήκος των ράβδων του υλικού λόγω της βλάβης διάβρωσης, με συνέπεια αφενός την τοπική συγκέντρωση τάσεων και αφετέρου την καταπίεση της ομοιόμορφης παραμόρφωσης κατά τον εφελκυσμό του υλικού. Τέλος, στην εργασία αυτή παρουσιάζεται μια μέθοδος με την οποία προσομοιώνεται η βλάβη λόγω διάβρωσης με μια τεχνητή εγκοπή. Η μέθοδος αυτή στηρίζεται στις παραδοχές ότι η ολκιμότητα του υλικού παραμένει αμετάβλητη λόγω της διάβρωσης και η παρατηρούμενη μείωση στην παραμόρφωση θραύσης οφείλεται στην καταπίεση της ομοιόμορφης παραμόρφωσης λόγω των εγκοπών που προκαλεί η διάβρωση στο υλικό οι οποίες διευκολύνουν τη δημιουργία του λαιμού. Επίσης γίνεται η παραδοχή ότι η παρατηρούμενη μείωση των ιδιοτήτων αντοχής οφείλεται στη συγκέντρωση τάσεων που προκαλούν οι εγκοπές αυτές. Δοκιμές εφελκυσμού σε δοκίμια με εγκοπές γνωστής γεωμετρίας έδειξαν ότι η μέθοδος αυτή μπορεί να χρησιμοποιηθεί με ικανοποιητική ακρίβεια για τον υπολογισμό των ιδιοτήτων εφελκυσμού του υλικού χωρίς την ανάγκη πραγματοποίησης μηχανικών δοκιμών. / Reinforced concrete is currently the most common material used for the construction of the load bearing elements of structures. Although this composite material performs exceptionally well, it has been noted that during the life span of reinforced concrete structures, which often exceeds 100 years, a gradual damage accumulation takes place. One of the most influential factors of this damage has been attributed to the corrosion of steel reinforcement. Recently, the degradation of the load bearing ability of steel reinforcement has been an issue under research by several researchers worldwide. Yet to date, the technological importance of this degradation caused by corrosion damage cannot be assessed to a satisfactory degree, mainly due to the lack of relevant experimental studies. Similarly, the physical mechanisms which contribute to the degradation have not been totally resolved. In the framework of the current PhD thesis, a systematic study of the mechanical behaviour of concrete reinforcing steel bars, corroded both in their natural environment (embedded in concrete) and by means of laboratory accelerated corrosion, was performed. By comparing the mass loss as a function of time recorded during the laboratory corrosion tests with the respective mass loss recorded from naturally corroded samples, an empirical acceleration factor was derived for laboratory corrosion damage compared to natural corrosion damage. Reinforcing steel grades S400* and S500s*, which have been used in the recent past for the reinforcement of concrete structures in Greece, as well as steel grade B500c**, which from the end of 2006 is used almost exclusively, were tested. To obtain a sufficient experimental database more than 500 tensile tests on corroded and non-corroded samples were performed. The tensile tests performed have shown only a slight degradation of the strength properties of the corroded steel bars. However, the reduction of the cross sectional area of the corroded bars lead to an increase of the applied stress, as the loads applied to which steel bars in structures are constant over time. This leads to a significant reduction of the safety factors applied during design. On the contrary, a significant reduction of the material’s ductility properties was recorded. Elongation to failure and strain energy density are crucial properties in the case of alternating loading during earthquakes. In order to understand the physical mechanisms which contribute to the recorded degradation of the mechanical properties, an extensive metallographic investigation as well as an investigation of the fracture surfaces of corroded material was performed. From this investigation it was concluded that corrosion damage is uniform without pitting, while along the bars’ length areas more severe corrosion damage was noted. Furthermore, the investigation of the fracture surfaces showed ductile fracture characteristics even of the most severely corroded specimens. It can therefore be concluded that the degradation of the tensile properties of corroded material is caused mainly by the non-uniformity of the corrosion damage and therefore of the cross sectional area along the longitudinal axis of the bars. This leads to a local stress concentration as well as to the depression of the uniform elongation during the tensile testing of the material. Finally, in the current PhD thesis a method by which corrosion damage can be simulated by a fictitious notch is suggested. This method is based on the assumptions that the ductility of the material remains unaffected by corrosion and the recorded reduction of the ductility properties is attributed to the depression of the uniform elongation caused by notches which are formed on the bars due to corrosion exposure and facilitate necking. In addition, the recorded reduction of the strength properties is attributed to the stress concentration caused by these notches. Tensile tests performed on specimens with artificial notches of known geometry have shown that the suggested method can be used to assess to a satisfactory degree the tensile properties of steel reinforcing bars without the need to perform tensile tests. * Names according to the Hellenic regulations. These steel grades are similar to the StIIIs and StIVs steel grades of the DIN regulations respectively. ** Name according to the Hellenic regulations. It is similar to StIV steel grade but with higher ductility requirements compared to S500s.

Μηχανική συμπεριφορά

Διάβρωση

624.183 41

Mechanical behavior

Concrete reinforcing steel bars

Corrosion

Contribution à l'évaluation de l'état de dégradation de divers types de barres d'acier utilisées comme armatures dans des bétons carbonatés ou pollués par des chlorures / Assessment of the state of degradation of various types of steel bars used as reinforcement in concrete carbonated or contaminated by chlorides

Rivera-Corral, Jesus Octavio

29 September 2016

Le béton armé est sans conteste le matériau le plus utilisé dans la construction, et permet de réaliser la plupart des infrastructures dans tous les pays du monde. Cependant, sa durabilité peut être compromise de façon prématurée par la corrosion des aciers, qui est la pathologie considérée comme la plus dangereuse vis-à-vis du maintien de l'intégrité des ouvrages de Génie Civil. Afin d'obtenir une meilleure résistance face au risque de corrosion, l'acier conventionnel (AC) peut être soumis à divers traitements, dont les plus connus sont le recouvrement superficiel par d'autres matériaux métalliques à base de zinc (AG), ou par des revêtements doubles métal-polymères (AD). Cependant, il existe aussi des barres d'acier thermiquement traitées (ATT) qui ne sont actuellement quasiment pas utilisées en tant qu'armatures. De ce fait, leur comportement face aux mécanismes de détérioration comme la corrosion en milieu cimentaire causée par les chlorures ou la carbonatation est encore très peu connu. Dans ce travail, le comportement des différentes barres d'acier mentionnées ci-dessus a été étudié. Des éprouvettes prismatiques de béton, incluant ces types d'armatures, ont été fabriquées avec deux rapports E/C : 0,45 et 0,65. Avant leur utilisation, les barres ont été caractérisées mécaniquement et métallographiquement. Ensuite, les éprouvettes ont été placées dans différentes conditions d'exposition : un environnement urbain/industriel ou côtier, et un environnement contrôlé en laboratoire. Des mesures du potentiel de corrosion, de résistance de polarisation linéaire, et de spectroscopie d'impédance électrochimique ont été mises en œuvre durant la période d'exposition. Pour chaque série, la teneur critique en chlorures a été déterminée, et la progression de la profondeur de carbonatation a été suivie. En outre, en induisant un couple galvanique par effet de la carbonatation, des mesures originales du comportement électrochimique de ces barres ont été effectuées puis une analyse, en s'appuyant sur une modélisation en éléments finis, en a été faite. Dans l'environnement contrôlé en laboratoire, l'ordre de dépassivation des différentes barres exposées a été observé de façon similaire pour les deux rapports E/C, à savoir : ATT, AC, AG et enfin AD. Une teneur critique en chlorures plus élevée a été obtenue pour les barres AG et AD. Cependant, lors de l'inspection visuelle, les dommages causés sur les armatures AG étaient plus élevés que sur les autres types de barres. Enfin, durant l'étape de propagation, la densité de courant de corrosion des barres ATT et des barres AG s'est révélée inférieure. / Corrosion of reinforcing bars in concrete is considered as the most important problem that affects the integrity of the civil structures. In order to obtain a better resistance to corrosion, various superficial processes as coatings with zinc (AG) or such as the dual covering metallic-polymeric (AD) are applicate to ordinary steel bars (AC). On the other hand, steel bars with thermal treatments (ATT), principally developed as an alternative to improve the mechanical properties without the use of ferroalloys, are not used in concrete. The behavior of these kinds of bars in front of mechanisms of deterioration as the corrosion induced by chlorides or carbonation has not yet been studied. In this work, all these various steel bars (AG, AD, AC and ATT) were embedded in prismatic specimens of concrete made with two ratio water/cement: 0.45 and 0.65. Previously, steels bars were characterized by mechanical tests and metallographic identifications. Then, specimens were placed in several sites of exposition: urban/industrial environment, or coastal environment, or controlled atmosphere in laboratory. During these expositions, measurements of corrosion potential, linear polarization resistance, and electrochemical impedance spectroscopy were regularly carried out. For each type of steel bar, chloride threshold level and progress of the carbonation depth were determined. Furthermore, by means of the induction of a galvanic couple during design of new samples, the electrochemical behavior of the steels bars AC, ATT and AG was followed up experimentally and then analyzed with finite element model. It was founded that the different steels bars exposed in controlled atmosphere of laboratory followed a same sequence in depassivation for both ratios water/cement: ATT, AC, AG and AD. The chloride thresholds were higher for steels bars AG and AD. However, visual inspection showed that the morphology of damages caused on AG bars was most important compared with the other steel bars. In the propagation phase, the corrosion current density of the ATT bars was lower, even to that obtained by the AG bars.

Corrosion

Béton armé

Traitement de barres d'acier

Chlorures

Carbonatation

Corrosion

Reinforced concrete

Types steel bars

Chlorides

Carbonation

A study of single angle compression members

Callaway, James Robert

01 January 1983

A study was undertaken to investigate the compressive capacity of a specific group of single angle members. A review of existing literature and techniques was presented. Laboratory compression tests were performed on 22 angle members of four different sizes and two different lengths. Additional tests were performed to determine the yield strength of the material. The results, normalized with respect to the yield stress, were tabulated and discussed. Two existing analytic models were used to attempt to predict the ultimate capacity of the test members. The first, an elastic method, was based upon the AISC combined stress equation. The second, an inelastic method, was developed by Mueller and Erzurumlu of Portland State University. Comparisons were made with the results of the test program. The results indicate that both analytic models give conservative predictions when pinned end conditions are assumed and unconservative results for fixed end conditions. For the test members with L/r ratios greater than 125, the elastic method results closely paralleled the test results but for the members with L/r ratios less than 125 the correlation was less consistent. The results of the inelastic technique closely paralleled the results of all the member tests.

Struts (Engineering)

Steel bars

Civil Engineering

Structural Engineering

Experimental Test of Two Span Continuous Concrete Beams Reinforced with Hybrid GFRP-Steel Bars

Araba, A.M., Zinkaah, O.H., Alhawat, Musab M., Ashour, Ashraf

25 October 2022

Yes / The current paper aimed at investigating the flexural performance of five large-scale continuous concrete beams reinforced by both steel bars and glass fibre reinforced polymer (GFRP). All the studied specimens had the same geometrical dimensions, with 200mm width, 300mm depth, and two identical spans of 2600mm. The quantity of longitudinal steel reinforcement, GFRP reinforcement, and hybrid reinforcement ratio at the top and bottom layers of beams were the key parameters explored in this study. The experimental findings indicated that using the hybrid reinforcement of steel and GFRP in multi-span continuous concrete beams exhibited a ductile behaviour. However, the hybrid ratio of steel bars/GFRP is critical for restricting the extent of moment redistribution ratios. Moreover, using the same hybrid reinforcement ratios at sagging and hogging regions led to a limited moment redistribution. On the other hand, the hybrid beams strengthened by various hybrid ratios in the critical sections of the tested beams demonstrated a remarkable moment redistribution up to 43%. The test results were compared with the available theoretical model and equations for predicting the beams’ moment capacity. It was found that the ACI.440.2R-08 reasonably predicted the flexural capacity of tested beams whereas the Yinghao and Yong equation underestimated the flexural capacity in the hogging sections. It was also shown that using the collapse mechanism with plastic hinges at sagging and hogging sections yielded good predictions for the loading capacity of hybrid reinforced concrete continuous beams.

FRP/steel bars

Continuous beams

Moment redistribution

Ductility

Load capacity prediction

Flexural behavior of ECC–concrete hybrid composite beams reinforced with FRP and steel bars

Ge, W-J., Ashour, Ashraf, Yu, J., Gao, P., Cao, D-F., Cai, C., Ji, X.

09 November 2018

Yes / This paper aims to investigate the flexural behavior of engineered cementitious composite (ECC)-concrete hybrid composite beams reinforced with fiber reinforced polymer (FRP) bars and steel bars. Thirty two hybrid reinforced composite beams having various ECC height replacement ratio and combinations of FRP and steel reinforcements were experimentally tested to failure in flexure. Test results showed that cracking, yield and ultimate moments as well as the stiffness of hybrid and ECC beams are improved compared with traditional concrete beams having the same reinforcement, owing to the excellent tensile properties of ECC materials. The average crack spacing and width decrease with the increase of ECC height replacement ratio. The ductility of hybrid reinforced composite beams is higher than that of traditional reinforced concrete beams while their practical reinforcement ratios are similar. Reinforced ECC beams show considerable energy dissipation capacity owing to ECC’s excellent deformation ability. Considering the constitutive models of materials, compatibility and equilibrium conditions, formulas for the prediction of cracking, yield and ultimate moments as well as deflections of hybrid reinforced ECC-concrete composite beams are developed. The proposed formulas are in good agreement with the experimental results. A comprehensive parametric analysis is, then, conducted to illustrate the effect of reinforcement, ECC and concrete properties on the moment capacity, curvature, ductility and energy dissipation of composite beams. / National Natural Science Foundation of China (51678514, 51308490), the Natural Science Foundation of Jiangsu Province, China (BK20130450), Six Talent Peaks Project of Jiangsu Province (JZ-038, 2016), Graduate Practice Innovation Project of Jiangsu Province (SJCX17-0625), the Jiangsu Government Scholarship for Overseas Studies and Top-level Talents Support Project of Yangzhou University

Engineered cementitious composite (ECC)

Concrete

Composite beams

Hybrid reinforcement

Flexural behavior

Steel bars

Fiber-reinforced polymer (FRP) bars