AREVA Fatigue Concept - A Three Stage Approach to the Fatigue Assessment of Power Plant Components

Modern state-of-the-art fatigue monitoring approaches gain in importance not only as part of the ageing management of nuclear power plant components but also in the context of conventional power plants and renewables such as wind power plants. Consequently, lots of operators have to deal with demanding security requirements to ensure the safe operation of power plants and to cope with plant lifetime extension (PLEX) related issues. AREVA disposes of a long tradition in the development of fatigue and structural health monitoring solutions. Nuclear and conventional power plant applications require the qualified assessment of measured thermo-mechanical loads. The methodology is transferable to mechanical loading conditions such as those of wind energy plants. The core challenge is the identification and qualified processing of realistic load-time histories. The related methodological requirements will be explained in detail. In terms of the nuclear industry, the ageing management of power plant components is nowadays a main issue for all actors: states, regulatory agencies, operators, designers or suppliants. As regards fatigue assessment of nuclear components stringent safety standards imply the consideration of new parameters in the framework of the fatigue analysis process: • new design fatigue curves, consideration of environmental fatigue (EAF) parameters and • stratification effects. In this general context AREVA developed the integral approach AREVA Fatigue Calculation (AFC) with new tools and methods in order to live up to operators’ expectations: Simplified Fatigue Estimation (SFE), Fast Fatigue Evaluation (FFE) and Detailed Fatigue Check (DFC). Based on real measured thermal loads and superposed mechanical loads the Fast Fatigue Evaluation (FFE) process allows a highly automated and reliable data processing to evaluate cumulative usage factors of mechanical components. Calculation and management of results are performed within the fatigue assessment software FAMOSi (FAatigue MOnitoring System integrated), thus impact of operating cycles on components in terms of stress and fatigue usage can be taken into account in order to plan optimized decisions relating to the plant operation or maintenance activities. This paper mainly describes the fatigue and structural health methodologies developed within the AREVA Fatigue Concept (AFC).

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Human reliability in non-destructive inspections of nuclear power plant components: modeling and analysis

Brazilian Journal of Radiation Sciences ◽

10.15392/bjrs.v7i2b.368 ◽

2019 ◽

Vol 7 (2B) ◽

Author(s):

Vanderley Vasconcelos ◽

Wellington Antonio Soares ◽

Raissa Oliveira Marques ◽

Silvério Ferreira Silva Jr ◽

Amanda Laureano Raso

Keyword(s):

Power Plant ◽

Nuclear Power Plant ◽

Human Factors ◽

Nuclear Power ◽

Power Plants ◽

Failure Modes ◽

Cooling System ◽

Human Reliability ◽

Non Destructive ◽

Plant Components

Non-destructive inspection (NDI) is one of the key elements in ensuring quality of engineering systems and their safe use. This inspection is a very complex task, during which the inspectors have to rely on their sensory, perceptual, cognitive, and motor skills. It requires high vigilance once it is often carried out on large components, over a long period of time, and in hostile environments and restriction of workplace. A successful NDI requires careful planning, choice of appropriate NDI methods and inspection procedures, as well as qualified and trained inspection personnel. A failure of NDI to detect critical defects in safety-related components of nuclear power plants, for instance, may lead to catastrophic consequences for workers, public and environment. Therefore, ensuring that NDI is reliable and capable of detecting all critical defects is of utmost importance. Despite increased use of automation in NDI, human inspectors, and thus human factors, still play an important role in NDI reliability. Human reliability is the probability of humans conducting specific tasks with satisfactory performance. Many techniques are suitable for modeling and analyzing human reliability in NDI of nuclear power plant components, such as FMEA (Failure Modes and Effects Analysis) and THERP (Technique for Human Error Rate Prediction). An example by using qualitative and quantitative assessesments with these two techniques to improve typical NDI of pipe segments of a core cooling system of a nuclear power plant, through acting on human factors issues, is presented.

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Corrosion of metals and alloys. Evaluation of selective corrosion of Cu alloys and grey cast iron for power plant components by visual inspection and hardness measurement

10.3403/30264735u ◽

2015 ◽

Keyword(s):

Cast Iron ◽

Power Plant ◽

Visual Inspection ◽

Hardness Measurement ◽

Metals And Alloys ◽

Grey Cast Iron ◽

Cu Alloys ◽

Selective Corrosion ◽

Grey Cast ◽

Plant Components

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Fundamental considerations of the effects of flexible operation on the fatigue of power plant components

Materials at High Temperatures ◽

10.1080/09603409.2021.1909886 ◽

2021 ◽

pp. 1-10

Author(s):

K. Bauerbach ◽

P. Grammenoudis

Keyword(s):

Power Plant ◽

Flexible Operation ◽

Plant Components

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Prediction of Stress Relaxation in Power Plant Components Based on a Constitutive Model

Volume 8: Microturbines, Turbochargers and Small Turbomachines; Steam Turbines ◽

10.1115/gt2017-63608 ◽

2017 ◽

Cited By ~ 1

Author(s):

Y. Kostenko ◽

K. Naumenko

Keyword(s):

Power Plant ◽

Stress Relaxation ◽

Constitutive Model ◽

Evolution Equations ◽

Material Behavior ◽

Assessment Procedure ◽

Reliable Prediction ◽

Inelastic Material ◽

Plant Components

Many power plant components and joint connections are subjected to complex thermo-mechanical loading paths under severe temperature environments over a long period. An important part in the lifetime assessment is the reliable prediction of stress relaxation using improved creep modeling to avoid possible integrity or functionality issues and malfunction in such components. The aim of this work is to analyze the proposed constitutive model for advanced high chromium steels with the goal of predicting stress relaxation over the long term. The evolution equations of the constitutive model for inelastic material behavior are introduced to account for hardening and softening phenomena. The material properties were identified for 9–12%CrMoV steels in the creep range. The model is applied to the stress relaxation analysis of power plant components. The results for long-term assessment, which are encouragingly close to reality, will be presented and discussed. An outlook on further developments of the model and assessment procedure is also provided.

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