The feasibility of electrochemical chloride extraction on prestressed concrete structures

Siegwart, Michael

January 2003

No description available.

624

Chloride induced corrosion

An Investigation into Reliability Based Methods to Include Risk of Failure in Life Cycle Cost Analysis of Reinforced Concrete Bridge Rehabilitation

Zhu, Weiqi, ycqq929@gmail.com

January 2008

Reliability based life cycle cost analysis is becoming an important consideration for decision-making in relation to bridge design, maintenance and rehabilitation. An optimal solution should ensure reliability during service life while minimizing the life cycle cost. Risk of failure is an important component in whole of life cycle cost for both new and existing structures. Research work presented here aimed to develop a methodology for evaluation of the risk of failure of reinforced concrete bridges to assist in decision making on rehabilitation. Methodology proposed here combines fault tree analysis and probabilistic time-dependent reliability analysis to achieve qualitative and quantitative assessment of the risk of failure. Various uncertainties are considered including the degradation of resistance due to initiation of a particular distress mechanism, increasing load effects, changes in resistance as a result of rehabilitation, environmental variables, material properties and model errors. It was shown that the proposed methodology has the ability to provide users two alternative approaches for qualitative or quantitative assessment of the risk of failure depending on availability of detailed data. This work will assist the managers of bridge infrastructures in making decisions in relation to optimization of rehabilitation options for aging bridges.

Risk of failure

time-dependent reliability

fault tree analysis

chloride induced corrosion

life cycle cost analysis

Assessment of Chloride Induced Corrosion and Impressed Current Cathodic Protection Conditions in Repaired Reinforced Concrete / 外部電源方式電気防食を施した鉄筋コンクリート断面補修部の浸透塩分による鉄筋腐食評価

Rohaya, Abdul Malek

26 March 2018

京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第21062号 / 工博第4426号 / 新制||工||1688(附属図書館) / 京都大学大学院工学研究科都市社会工学専攻 / (主査)教授 河野 広隆, 准教授 服部 篤史, 准教授 山本 貴士 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM

corrosion

chloride-induced

patching method

polymer modifier mortar

cathodic protection

500

Investigation of Chloride-induced Stress Corrosion Cracking for Long-Term Storage of Spent Nuclear Fuel in Dry Storage Systems

Shakhatreh, Abdulsalam Ismail

14 September 2022

Chloride-induced stress corrosion cracking (CISCC) has been identified as the main degradation mechanism for spent nuclear fuel dry storage canisters. This type of induced cracking is complex and depends on several factors, such as material composition, exposure temperature, relative humidity, applied tensile stress, and atmospheric salt concentration. An accelerated experiment was designed to simulate marine environments in a controlled fogging chamber to examine 304 and 304L stainless steel U-bend and welded U-bend samples. The samples were exposed to chloride rich and humid fogging in a corrosion chamber at 35℃ continuously for 4 weeks, 8 weeks, and 12 weeks. The same experiment was repeated at 50℃ for 4 weeks, 8 weeks, and 14 weeks to study the sensitivity of CISCC to temperature changes. A qualitative evaluation of optical micrographs from a 3D Surface Profiler was performed for 16 corroded samples and compared with 2 reference samples. Cracking was observed on 12 out of 16 samples exposed to 35℃ and 50℃ for durations ranging from 8 to 14 weeks. Likely cracking observations were noted on 4 out of 16 samples. A quantitative statistical analysis was also performed using surface profile depth (valley) data from corroded and reference samples. The quantitative analysis examined the effect of temperature, welding, exposure duration, and material composition. The quantitative results were compared with the qualitative results and literature published in CISCC. / Master of Science / Most nuclear power plants are currently using dry storage canisters (DSCs) which are made of a concrete vault and a stainless steel canister that houses the spent nuclear fuel (SNF) assemblies. Multiple conditions must be present simultaneously for chloride-induced stress corrosion cracking (CISCC) to develop, such as the presence of a susceptible alloy, high relative humidity, high temperature, high atmospheric salt concentrations, and applied tensile stresses. DSCs are typically made from 300-series austenitic stainless steels which are susceptible to this type of corrosion during long-term storage near marine environments. Therefore, understanding of the factors leading to CISCC is critically important for proper management and mitigation and to estimate the service life of DSCs for the safe long-term storage of SNF. An accelerated experiment was designed to examine the effects of temperature, exposure duration, and welding on pitting and cracking for 304 and 304L U-bend samples. The experimental results concluded that stainless-steel grades 304 and 304L are susceptible to CISCC when exposed for 8 weeks or longer to fogging at temperatures between 35℃ and 50℃, 95% relative humidity, and 5% salt concentration. This study also concluded that increasing exposure duration from 8 to 12 weeks or the temperature from 35℃ to 50℃ had no significant effect on the acceleration of CISCC. Also, unwelded samples were deemed more susceptible to CISCC than welded samples and the susceptibility of 304 and 304L grades were relatively similar.

stress corrosion cracking

spent nuclear fuel dry storage

CISCC

SCC

ISFSI

Chloride-Induced Stress Corrosion Cracking in Used Nuclear Fuel Welded Stainless Steel Canisters

Xie, Yi

28 December 2016

No description available.

Nuclear Engineering

SPATIAL RELIABILITY ANALYSIS FOR CORRODED REINFORCED CONCRETE STRUCTURES

Zhao, Li

January 2016

No description available.

Civil Engineering

Durability of precast prestressed concrete piles in marine environments

Holland, Robert Brett

05 July 2012

In this research, two phases of work were conducted. First, an investigation into the durability concerns for precast prestressed concrete piles exposed to marine environments was conducted. The investigation characterized the durability concerns of chemical, biological, and physical deterioration mechanisms. The results of this study were used to develop potential high performance marine concretes (HPMC) that would be capable of 100+ year service lives in marine environments. Extensive durability testing and service life modeling of the HPMC was performed. Chloride ingress resistance was investigated using accelerated and long-term test procedures and the results used to perform service life modeling to predict the time before corrosion initiation. Sulfate resistance characterization was performed using multiple techniques to characterize the physical and chemical behavior of binder compositions containing binary or ternary mixes containing cement and supplementary cementitious materials (SCM's) subjected to a sulfate-laden environment. Accelerated carbonation testing and material characterization led to the finding of relationships in the chemical composition of mix designs and the observed durability and the results used to perform corrosion initiation service life modeling. An investigation into the influence of self-healing of cracked concrete led to fundamental findings on the behavior of chloride ingress for cracked concrete structures in marine environments. The results of this research led to the development of concrete mix designs capable of providing service lives over 100 years in Georgia's marine environments, as well as the advancement of the current state of knowledge on the durability characteristics of ternary mix designs.

Self-healing concrete

High performance concrete

Carbonation

Sulfate attack

Chloride induced corrosion

Self-healing materials

Smart materials

Precast concrete

Zerstörungsfreie Prüfung von Stahlbeton

Jackobasch, Andreas, Schneck, Ulrich, Grieger, Christoph

19 March 2015

Das Ziel der Arbeit bestand darin, die aus der Literatur bekannten Zusammenhänge zwischen Korrosionsaktivität von Stahl im Beton und einer galvanostatischen Pulsmessung, welche unter Laborbedingungen gute Ergebnisse liefern, auf Messungen an realen Bauwerken anzuwenden. Dazu wurden zunächst Untersuchungen an 13 Jahre alten Prüfkörpern durchgeführt und ausgewertet. Die abgeleiteten Zusammenhänge konnten anschließend an realen Bauteilen verifiziert werden. Somit stellt die galvanostatische Pulsmessung eine hilfreiche zerstörungsfreie Prüfmethode zur Interpretation des Korrosionszustandes dar. Die neuen Erkenntnisse lassen eine bessere Einschätzung des Korrosionsverhaltens in Stahlbetonbauwerken zu, als es die Potentialmessung erlaubt.

Bewehrungskorrosion

Chloridinduziert

Lochfraß

galvanostatischer Puls

zerstörungsfreie Prüfung

rebar corrosion

chloride induced

pitting corrosion

galvanostatic pulse

nondestructive testing

ddc:624.18341

ddc:620.1127

rvk:ZI 4502

rvk:ZM 3700

Finite Element Modeling of Steel Corrosion in Concrete Structures

Farhadi, Mehrnoush

14 September 2018

Concrete is a popular construction material for bridges, due to its high durability and energy efficiency. An important concern for concrete bridges is the possible occurrence of chloride- induced corrosion in prestressing strands and reinforcing bars, which may substantially impact the service life of such structures. Chloride- induced corrosion is a complicated electrochemical process which is affected by heat transfer, moisture flow and transport of chemical species through the concrete pore network. Reliable and robust analytical tools are required to allow multi-physics simulations of steel corrosion. This study has developed a nonlinear finite element analysis program, called VT-MultiPhys, to enable multi-physics simulations, including analyses of chloride-induced corrosion. The program includes constitutive laws, element formulations and global solution schemes to allow the analysis of steady-state (static) and time-dependent (dynamic) problems, involving multiple, coupled processes such as mechanical deformation, heat transfer, mass flow and chemical reactions combined with advective/diffusive transport of the various species. Special analysis schemes, based on the streamline-upwind Petrov-Galerkin (SUPG) method, have also been implemented to address the spatial instabilities which characterize analyses of advection-dominated transport. The finite element modeling scheme, constitutive laws and boundary conditions for analysis of chloride-induced corrosion are described in detail. The constitutive laws can be combined with inelastic material models to capture the damage (e.g., cracking) due to chloride-induced corrosion. A set of verification analyses is presented, to demonstrate the capabilities of VT-MultiPhys to conduct different types of simulations and reproduce the closed-form analytical solutions of simple cases. Validation analyses for heat conduction, moisture flow and chloride transport, using data from experimental tests in the literature, are also presented. / Master of Science / The deterioration of concrete structures and infrastructures due to the chloride-induced corrosion in prestressing strands and reinforcing bars may substantially impact the service life of such structures. Chloride-induced corrosion is a complicated electrochemical process which is initiated and proceeds due to the chloride attacks at the surfaces of concrete structures and ends in the volume expansion, cracking and spalling of concrete. Due to the lack of comprehensive modeling tool, which can simultaneously comprise the influential factors in chloride-induced corrosion, the realistic estimation of the service life of reinforced concrete structures is still challenging. Reliable and robust analytical tools are required to allow multi-physics simulations of steel corrosion. This study has developed a comprehensive finite element analysis program, called VT-MultiPhys, for calculating and monitoring the contribution of chloride ions to chloride-induced corrosion during service life of concrete structures. The present analysis program enables modeling of the coupled physical process including heat transfer, moisture flow and transport of chemical species through the concrete pore network. Also, by modeling the influence of flexural cracks on chloride transport in concrete, the analysis program is able to predict the rate of steel corrosion in cracked concrete structures. A set of verification analyses is presented, to demonstrate the capabilities of VT-MultiPhys to conduct different types of simulations of heat conduction, moisture flow and chloride transport and the comparison is found to be satisfactory. The element formulations and solution algorithms in VT-MultiPhys also allow the investigation of other long-term deterioration mechanisms, such as carbonation-induced corrosion, alkali-silika reaction (ASR) and sulfate attack. The present contribution will hopefully enable and facilitate future research in these topics, through the formulation and implementation of proper constitutive laws and chemical reaction equations.

Advection-diffusion

Chloride-induced Corrosion

Chloride transport

Electro-chemical cell

Finite element analysis

Moisture isotherm

Reinforced concrete structures

Polarization

SUPG method

Tafel diagram

Zerstörungsfreie Prüfung von Stahlbeton: Ermittlung des nicht sichtbaren Korrosionsverhaltens von Bewehrungsstählen im Beton durch die galvanostatische Pulsmessung

Jackobasch, Andreas, Schneck, Ulrich, Grieger, Christoph

19 March 2015

Das Ziel der Arbeit bestand darin, die aus der Literatur bekannten Zusammenhänge zwischen Korrosionsaktivität von Stahl im Beton und einer galvanostatischen Pulsmessung, welche unter Laborbedingungen gute Ergebnisse liefern, auf Messungen an realen Bauwerken anzuwenden. Dazu wurden zunächst Untersuchungen an 13 Jahre alten Prüfkörpern durchgeführt und ausgewertet. Die abgeleiteten Zusammenhänge konnten anschließend an realen Bauteilen verifiziert werden. Somit stellt die galvanostatische Pulsmessung eine hilfreiche zerstörungsfreie Prüfmethode zur Interpretation des Korrosionszustandes dar. Die neuen Erkenntnisse lassen eine bessere Einschätzung des Korrosionsverhaltens in Stahlbetonbauwerken zu, als es die Potentialmessung erlaubt.

ddc:624.18341

info:eu-repo/classification/ddc/620.1127

ddc:620.1127