Cyclic Uniaxial Constitutive Model For Steel Reinforcement

Kim, Se-Hyung

31 January 2015

Reinforced Concrete (RC) structures are common in earthquake-prone areas. During an earthquake, the steel reinforcement is subjected to cyclic strain histories which lead to inelastic response. In the case of rare, strong earthquakes, inelastic buckling and even rupture due to low-cycle fatigue can also occur. The understanding and characterization of the performance of RC structures under earthquake hazards requires the accurate simulation of the inelastic hysteretic behavior of steel reinforcement by means of appropriate constitutive models. Several uniaxial material models have been developed for reinforcing steel. Existing material models sacrifice efficiency for accuracy or vice versa. Conceptually simple and numerically efficient models do not accurately capture the hysteretic response and ignore rupture or buckling. On the other hand, more refined material models are characterized by iterative stress update procedures which can significantly increase the computational cost of an analysis. Additionally, experience suggests that refined models attempting for the effect of inelastic buckling tend to lead to numerical convergence problems in the stress update procedure. The goal of the present study is the formulation and implementation of an accurate and computationally efficient constitutive model for steel reinforcement under cyclic loading. A previously developed model, capable of capturing the inelastic hysteretic response of reinforcing steel in the absence of buckling and rupture, is used as a starting point in this study. The model is enhanced by replacing its original, iterative stress update procedure with an equally accurate, non-iterative one. Additionally, the model is enhanced to capture the effects of inelastic buckling and of rupture. The accuracy of the model and the efficiency of the non-iterative stress update algorithm are demonstrated by means of validation analyses. / Master of Science

Reinforcing Steel

Constitutive Model

Cyclic Loading

Buckling

Rupture

Etude de la structure et des propriétés de l'acier à béton après déformations à froid

Tabalaiev, Kostiantyn

10 September 2010

Les propriétés généralement demandées aux armatures pour béton armé doivent répondre à des exigences particulières précisées dans des normes nationales, européennes et internationales. Actuellement, dans la pratique de la production de l'acier à béton, on tend à substituer différentes nuances d'armature par une armature unifiée ayant une valeur de limite d'élasticité minimale de 500 MPa. Le remplacement des ronds à béton de nuance 400MPa par cette armature conduit à une économie de métal de l'ordre de 10-20 % d'après les estimations de différents spécialistes.Il existe, généralement, plusieurs techniques de fabrication des armatures, dont la déformation à chaud suivie d'un refroidissement accéléré sous flux d'eau (traitement thermomécanique ou Thermomechanical Control Process - TMCP), ainsi que la déformation à froid (tréfilage â travers une filière conique et une filière à rouleaux, microlaminage...), qui se heurte cependant â l'impossibilité de satisfaire aux exigences des Normes vis-à-vis des propriétés de résistance (Re > 500MPa) et de plasticité.Le présent travail a pour but le développement d'un procédé combiné de production d'acier à béton profitant des aspects positifs de deux types de déformation à chaud ainsi qu'à froid, sous forme du traitement combiné mécano-thermomécanique (post déformations à froid après le TMCP). et d'étudier la possibilité de production d'aciers à béton de qualité 500 MPa (B(A)500), de petits diamètres, en couronne, répondant aux exigences des Normes modernes. L'objectif scientifique de ce travail est d'étudier les mécanismes microstructuraux qui se produisent lors de la déformation à froid de l'acier préalablement traité thermomécaniquement et leurs conséquences sur l'évolution des propriétés mécaniques.Plusieurs nuances d'acier bas carbone de différents diamètres ont été étudiées. De nombreuses techniques de caractérisation macroscopique et microscopique de la structure de l'acier ont été utilisées: traction monotone, essais de microdureté, microscopie optique, microscopie électronique â balayage (MEB) et en transmission (MET), diffraction des rayons X. spectrométrie mécanique..Les résultats des essais montrent qu'il est possible d'obtenir avec assurance l’armature de qualité B(A)500, possédant des propriétés mécaniques qui dépassent les exigences des nonnes, à l'aide d’une déformation par torsion avec un cisaillement maximal de 22%, pour des aciers à 0.15 -0.2 % C(en poids), faiblement alliés en Mn et Si et traités themomécaniquement. La déformation par torsion provoque une augmentation de dureté en surface mais aussi au cœur de l'armature. Cette augmentation de dureté à cœur peut être amplifiée par le traitement thermique de vieillissement à 100°C correspondant à l'utilisation en Génie Civil. Cet effet, lié aux interactions dislocation-impuretés interstitielles, a été expliqué grâce â la MET et à l'étude du frottement intérieur. / Properties which are required from an armature for the reinforced concrete should satisfy the requirements of National, European and International standards. At the present time, in practice of armature production, there is a tendency of replacement of various classes of reinforcing steels by the unified armature with the minimum value of yield strength of 500 MPa. Replacement of the armature of the 400 MPa class by such reinforcing steel brings the economy of metal of an order of 10-20 % according to the estimations of various experts.In general, a set of production technologies of the armature exists, including hot deformation with the subsequent accelerated cooling in water - Thermomechanical Control Process (TMCP), and also cold deformation (drawing in conic die block, drawing in roller die block, microrolling) which nevertheless face the impossibility to provide the required strength (yield strength > 500MPa) and plastic properties.The technological purpose of the given work is:- development of the combined mechano-thermomechanical processing of armature's production which would combine positive aspects of hot and cold deformations (post deformation processing after TMCP);- examination of possibilty to manufacture the reinforcing steel of the class of 500MPa (B(A)500) of the small diameter, in coils, meeting the requirements of modem standards.The scientific objective of the work is the analysis of change of the microstructure of reinforcing steels after the cold deformation which is preliminary subjected to thermomechanical processing, and, also, the examination of the influence of microstructural effect on change of mechanical properties of steels.In the present study, a significant quantity of grades of low-carbon steels of various diameters has been investigated. Also, different techniques for macroscopical and microscopical characterization of the steel structures have been applied: tensile tests, micro-hardness test, optical microscopy, scanning electron microscopy (SEM), transmission electron microscopy (TEM), X-ray analysis and mechanical spectroscopy.Results of tests show that it is possible to obtain, with assurance, the reinforcing steel of the strength class B(A)500, with a complex of the mechanical properties surpassing the requirements of standards. For this purpose it is proposed to use the deformation by cold torsion with the maximum relative shear of 22 %, after thermomechanical processing, for steels with carbon content of 0,15...0,25% and alloyed with Mn and Si. Deformation by torsion provides an increase of hardness not only on the surface, but also in the core of armature. The effect of hardness increase can be strengthened by means of thermal ageing at 100°C corresponding to the use in Civil Engineering. This effect, related to the dislocations- interstitial impurities interactions, was explained thanks to MET and internal friction effect.

Traitement mécano-thermomécanique

Torsion

Vieillissement

Reinforced concrete

Reinforcing steel

Thermomechanical control process

Cold deformation

Analysis of Selected Factors Affecting Concrete Cover Measurements on Bridge Decks

Hoki, Jeffrey Ryan

17 March 2011

The objective of this research was to quantify the effects of selected parameters on the accuracy of concrete cover measurements on bridge decks. This research involved three full-factorial laboratory experiments each designed to investigate one of three primary variables. These primary variables included distance to a parallel adjacent bar, distance to a reinforcement intersection, and incorrect bar size input for the cover meter. Each experiment also involved four secondary variables known to affect cover readings. These secondary variables included actual cover depth, meter brand, antenna type, and bar size. Statistical analyses were performed to determine the significance of each factor. A margin of error of 0.125 in., corresponding to the increase in diameter between successive U.S. standard rebar sizes, was established as the threshold for practical importance in the data analysis. Three primary findings resulted from the three experiments performed in this research. For the meters and antennas tested, the results of the field-of-view experiment indicated that, if the spacing is greater than approximately 4.0 in., the returned readings are within the threshold for practical importance established for this research. The results of the proximity-to-an-intersection experiment indicated that, regardless of where the measurement is taking place in relation to an intersection, the operator can be confident that the errors will be less than 0.125 in. as long as the bar in question is above the intersecting bar. The results of the wrong-bar-size experiment indicated that, if the operator of the cover meter does not know the actual rebar size in question, the measured cover will be within 0.125 in. of the actual cover depth as long as the meter input is within one bar size of the correct value. Obtaining accurate cover measurements on bridge decks is important for quality assurance, service life prediction, and rehabilitation programming.

bridge deck

concrete

concrete cover

cover meter

non-destructive testing

rebar

reinforcing steel

Civil and Environmental Engineering

An Investigation of the Suitability of Using AISI 1117 Carbon Steel in a Quench and Self-tempering Process to Satisfy ASTM A 706 Standard of Rebar

Allen, Matthew

11 August 2011

Experiments were conducted to investigate the potential of using a quench and self-tempering heat treatment process with AISI 1117 steel to satisfy the mechanical properties of ASTM A 706 rebar. A series of quenching tests were performed and the resulting microstructure and mechanical properties studied using optical microscopy, microhardness measurement, and tensile tests. The presence of martensite throughout the samples contributed to the enhanced strength and strain-hardening ratio (tensile to yield strength) of the material. The experimental results showed that AISI 1117 is capable of meeting the ASTM standard. In addition to the experiments, a computer model using the finite difference method and incorporating heat transfer and microstructure evolution was developed to assist in future optimization of the heat treatment process.

AISI 1117

reinforcing steel

rebar

QST

microstructure

quench and self-tempering

tempered martensite

0794

0743

An Investigation of the Suitability of Using AISI 1117 Carbon Steel in a Quench and Self-tempering Process to Satisfy ASTM A 706 Standard of Rebar

Allen, Matthew

11 August 2011

Experiments were conducted to investigate the potential of using a quench and self-tempering heat treatment process with AISI 1117 steel to satisfy the mechanical properties of ASTM A 706 rebar. A series of quenching tests were performed and the resulting microstructure and mechanical properties studied using optical microscopy, microhardness measurement, and tensile tests. The presence of martensite throughout the samples contributed to the enhanced strength and strain-hardening ratio (tensile to yield strength) of the material. The experimental results showed that AISI 1117 is capable of meeting the ASTM standard. In addition to the experiments, a computer model using the finite difference method and incorporating heat transfer and microstructure evolution was developed to assist in future optimization of the heat treatment process.

AISI 1117

reinforcing steel

rebar

QST

microstructure

quench and self-tempering

tempered martensite

0794

0743

Polarization of Galvanic Point Anodes for Corrosion Prevention in Reinforced Concrete

Dugarte, Margareth

02 April 2010

The polarization performance of two types of commercial galvanic point anodes for protection of reinforced steel around patch repairs was investigated. Experiments included measurement of the polarization history of the anode under constant current impressed by galvanostatic circuits and in reinforced concrete slabs. The tests revealed, for both types of anodes, a potential-current function (PF) indicating relatively little anodic polarization from an open circuit potential at low current levels, followed by an abrupt increase in potential as the current approached an apparent terminal value. Aging of the anodes was manifested by a continually decreasing current output in the concrete tests, and by increasingly more positive potentials in the galvanostatic tests. Those changes reflected an evolution of the PF generally toward more positive open circuit potentials and, more importantly, to the onset of elevated polarized potentials at increasingly lower current levels. There was considerable variability among the performance of replicate units of a given anode type. Modest to poor steel polarization levels were achieved in the test yard slabs. Modeling of a generic patch configuration was implemented with a one-dimensional approximation. The model calculated the throwing distance that could be achieved by a given number of anodes per unit perimeter of the patch, concrete thickness, concrete resistivity, amount of steel and amount of polarization needed for cathodic prevention. The model projections and aging information suggest that anode performance in likely application scenarios may seriously degrade after only a few years of operation, even if a relatively optimistic 100 mV corrosion prevention criterion were assumed. Less conservative criteria have been proposed in the literature but are yet to be substantiated. Other investigations suggest a significantly more conservative corrosion prevention may apply instead. The latter case would question the ability of the point anodes to provide adequate corrosion prevention.

zinc

cathodic protection

patch repair

reinforcing steel

potential

American Studies

Arts and Humanities

Civil Engineering

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

Performance Evaluation of Epoxy-Coated Reinforcing Steel and Corrosion Inhibitors in a Simulated Concrete Pore Water Solution

Pyc, Wioleta A.

14 February 1998

Three epoxy-coated reinforcing steel (ECR) types removed from job sites, one shipped directly from the coater's plant, three commercial corrosion inhibitors, and one ECR plus a corrosion inhibitor were evaluated as reinforcing steel corrosion protection systems against chloride induced corrosion. The three corrosion inhibitors were calcium nitrite, an aqueous mixture of esters and amines, and a mixture of alcohol and amine. The ECR was tested in two groups, 0% and 1% coating damage. Corrosion protection performance was evaluated by the amount of visually observed blister surface area, for the ECR, and corroded surface area, for the tested corrosion inhibitors. Results of the ECR testing demonstrated that coating debondment and corrosion of ECR is directly related to the amount of damage present in the coating, as well as coating thickness. For the bare steel tested with and without corrosion inhibitors, the results showed that corrosion increases with increasing chloride concentrations. Corrosion inhibition characteristics were demonstrated only by the calcium nitrite corrosion inhibitor. A corrosion protection evaluation test was developed for concrete corrosion inhibitor admixtures. The test solution is a simulated concrete pore water. Corrosion is accelerated by evaluating the temperature to field conditions of 40 C. The test consists of a 7 day pretreatment period followed by a 90 day test period. The corrosive sodium chloride is added to the solution containing the bare or epoxy-coated reinforcing steel specimens after the 7 day pretreatment period. In addition, the solution is periodically saturated with oxygen. / Master of Science

blister formation

corrosion

epoxy-coated reinforcing steel

corrosion inhibitor admixtures

concrete pore solution

solution testing

Parameters Influencing the Corrosion Protection Service Life of Epoxy Coated Reinforcing Steel in Virginia Bridge Decks

Wheeler, Megan Caroline

22 January 2004

This study is an evaluation of epoxy coated reinforcing steel (ECR) and its ability to effectively provide corrosion protection in reinforced concrete highway bridge decks. An analysis was conducted on 10 bridge decks built in the state of Virginia between the years 1981 and 1995. A total of 141 cores containing either ECR or bare steel were evaluated. A chloride solution was applied to the surface on a weekly cycle (for a total duration of 3.06 years) and a nondestructive electrochemical testing was performed on each core on a monthly cycle. Cores were also inspected for surface cracks, the thermal properties of the epoxy coating, and the concrete conditions at bar depth. The concrete was tested for saturation percentages, diffusion coefficients, and chloride contents, while the epoxy was tested for its glass transition temperature, moisture content, and amount of surface cracking. The results indicate that the best predictor for estimating the times to corrosion initiation and cracking is the amount of chlorides present in the concrete encasing the ECR. The presence of chloride ions will have a determining effect on corrosion regardless of the epoxy coating condition. As a result, it is likely that ECR is not the solution to corrosion prevention and it is recommended that closer attention be given to improving concrete conditions that reduce the diffusion of chloride ions. The conclusion that ECR is an unreliable corrosion prevention method is in agreement with the results of previous studies. / Master of Science

concrete

glass transition temperature

corrosion

bridge decks

epoxy coated reinforcing steel (ECR)

Assessment of Commercial Corrosion Inhibiting Admixtures for Reinforced Concrete

Brown, Michael Carey

09 January 2000

Corrosion of reinforcing steel in concrete exposed to chloride-laden environments is a well-known and documented phenomenon. The need for cost effective systems for protection against corrosion has become increasingly clear since the first observations of severe corrosion damage to interstate bridges in the 1960's. As one potential solution to the mounting problem of corrosion deterioration of structures, corrosion-inhibiting admixtures have been researched and introduced into service. This report conveys the results of a three-part laboratory study of corrosion inhibiting admixtures in concrete. The commercial corrosion inhibiting admixtures for concrete have been analyzed by three evaluation methods, including: • Conventional concrete corrosion cell prisms under ponding, • Black steel reinforcing bars immersed in simulated concrete pore solutions, • Electrochemical screening tests of special carbon steel specimens in electrochemical corrosion cells containing filtered cement slurry solution. The purposes of the study include: • Determining the influence of a series of commercially available corrosion inhibiting admixtures on general concrete handling, performance and durability properties not related to corrosion. • Determining the effectiveness of corrosion inhibiting admixtures for reduction or prevention of corrosion of reinforcing steel in concrete, relative to untreated systems, under laboratory conditions. • Conducting a short-term pore solution immersion test for inhibitor performance and relating the results to those of the more conventional long-term corrosion monitoring techniques that employ admixtures in reinforced concrete prisms. • Determining whether instantaneous electrochemical techniques can be applied in screening potential inhibitor admixtures. Concrete properties under test included air content, slump, heat of hydration, compressive strength, and electrical indication of chloride permeability. Monitoring of concrete prism specimens included macro-cell corrosion current, mixed-cell corrosion activity as indicated by linear polarization, and ancillary temperature, relative humidity, and chloride concentration documentation. Simulated pore solution specimens were analyzed on the basis of weight loss and surface area corroded as a function of chloride exposure. Electrochemical screening involved polarization resistance of steel in solution. Results include corrosion potential, polarization resistance and corrosion current density. / Master of Science

polarization resistance

corrosion inhibiting admixtures

reinforcing steel corrosion

concrete pore solution