Identification and Assessment of Material Models for Age-Related Degradation of Structures and Passive Components in Nuclear Power Plants

Nie, Jinsuo; Braverman, J.; Hofmayer, C.H.; Kim, M. K.; Choi, Ik Je

doi:10.2172/952521

Cited by 3 publications

(11 citation statements)

References 31 publications

(56 reference statements)

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“…For degradation scenario C, a hybrid degradation model was developed based on available anchorage test results for cracked concrete and regression models based on measured data at Korean NPPs. The resultant models are summarized below to facilitate the development of DAC in terms of time in this section; more details about the background of these models can be found in Section 3 as well as the Year 3 and Year 4 annual reports [Nie et al, 2009[Nie et al, , 2011. In which time t is in years, the crack width W in mm, and the tensile capacity T in kips.…”

Section: Resultant Degradation Formulations For the Five Degradation mentioning

confidence: 99%

“…The material degradation model for the stainless steel tank shell used for the seismic fragility analysis of the CST is the mechanochemical model for stress corrosion cracking (SCC), which is one of the three time-dependent material degradation models for stainless steel that are documented in the Year 2 annual report [Nie et al, 2009]. It can be seen from Figure 3-1 that as there are no signs of significant degradation in the CST shell, the consideration of tank shell degradation in the seismic fragility analysis of the CST was for the purpose of demonstration.…”

Section: Materials Degradation Model For Stainless Steel Tank Shellmentioning

confidence: 99%

“…The protecting stainless steel cover as shown in Figure 3-1 may not be leak-tight. A power model for steel corrosion was chosen from the Year 2 annual report [Nie et al, 2009] to model the degradation of the anchor bolts. This model had been used by Mori [2005] to predict reliability-based service life, indicating its suitability for fragility analysis.…”

Section: Materials Degradation Model For Anchor Boltsmentioning

confidence: 99%

“…The five year collaboration program consists of five tasks: (1) identification and characterization of degradation occurrences in US NPPs and important aging characteristics needed for the seismic capability evaluations [Nie et al 2008], (2) identification and assessment of degradation models for the long-term behavior of dominant materials that are determined to be risk significant to NPPs [Nie et al 2009], (3) seismic fragility analysis methodology and its application to a condensate storage tank with three degradation scenarios , (4) additional seismic fragility analysis of the condensate storage tank to consider non-perfect correlations among degradation scenarios [Nie et al 2011], and (5) development of a procedure for determination of degradation acceptance criteria for structures and passive components (SPCs) in nuclear power plants, which is the topic of this report.…”

Section: Introductionmentioning

confidence: 99%

“…The effect of agerelated degradations of SPCs on their seismic fragility was investigated in this collaboration program through the integration of the fragility calculation and the degradation effect, which may be expressed in terms of observed degradation levels or time using proper time-dependent degradation models [Nie et al 2009[Nie et al , 2011. The seismic fragility is the conditional probability of failure of an SPC for given levels of seismic demand, often conveniently described in terms of peak ground acceleration (PGA).…”

Section: Introductionmentioning

confidence: 99%

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A Procedure for Determination of Degradation Acceptance Criteria for Structures and Passive Components in Nuclear Power Plants

Nie¹,

Braverman²,

Hofmayer³

et al. 2012

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The Korea Atomic Energy Research Institute (KAERI) has been collaborating with Brookhaven National Laboratory since 2007 to develop a realistic seismic risk evaluation system which includes the consideration of aging of structures and components in nuclear power plants (NPPs). This collaboration program aims at providing technical support to a five-year KAERI research project, which includes three specific areas that are essential to seismic probabilistic risk assessment: (1) probabilistic seismic hazard analysis, (2) seismic fragility analysis including the effects of aging, and (3) a plant seismic risk analysis. The understanding and assessment of age-related degradations of structures, systems, and components and their impact on plant safety is the major goal of this KAERI-BNL collaboration. Four annual reports have been published before this report as a result of the collaboration research: This report describes the research effort performed by BNL and KAERI for the Year 5 scope of work. The goal of this effort is to develop a procedure for determination of degradation acceptance criteria (DAC) for structures and passive components in nuclear power plants. This report covers the identification of an acceptable risk criterion, the development of a general procedure for three-tier DAC, determination of three-tier DAC for a condensate storage tank (CST), and insights on how to apply these DAC in inspection/maintenance planning. The development of DAC for the CST considers five degradation cases: (A) degraded stainless tank shell; (B) degraded anchor bolts; (C) anchorage concrete cracking; (D) a perfect correlation of the degradation scenarios A, B, and C; and (E) a non-perfect correlation of the three degradation scenarios. These degradation cases are the same as those considered in the seismic fragility analyses of the CST with degradations in the Year 3 and Year 4 studies. The effect of degradation on the fragility capacity as well as on the uncertainties was considered in the DAC development. A necessary and very important part of the Year 5 research is the probabilistic safety/risk analyses performed by KAERI to calculate the core damage frequencies (CDFs) for a range of fragility capacities of the CST, which correspond to the undegraded and various degraded conditions of the CST.This report also includes an extended summary of the seismic fragility analyses of the CST with age-related degradations and three additional seismic fragility analyses to facilitate the development of various DAC and discussions in this report.

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Section: Resultant Degradation Formulations For the Five Degradation mentioning

confidence: 99%

Section: Materials Degradation Model For Stainless Steel Tank Shellmentioning

confidence: 99%

Section: Materials Degradation Model For Anchor Boltsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A Procedure for Determination of Degradation Acceptance Criteria for Structures and Passive Components in Nuclear Power Plants

Nie¹,

Braverman²,

Hofmayer³

et al. 2012

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Icone19-43630 Seismic Fragility Analysis of a Degraded Condensate Storage Tank

Nie¹,

Braverman²,

Hofmayer³

et al. 2011

ICONE

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and Brookhaven National Laboratory are conducting a collaborative research project to develop seismic capability evaluation technology for degraded structures and components in nuclear power plants (NPPs). One of the goals of this collaboration endeavor is to develop seismic fragility analysis methods that consider the potential effects of age-related degradation of structures, systems, and components (SSCs). The essential part of this collaboration is aimed at achieving a better understanding of the effects of aging on the performance of SSCs and ultimately on the safety of NPPs.A recent search of the degradation occurrences of structures and passive components (SPCs) showed that the rate of aging related degradation in NPPs was not significantly large but increasing, as the plants get older. The slow but increasing rate of degradation of SPCs can potentially affect the safety of the older plants and become an important factor in decision making in the current trend of extending the operating license period of the plants (e.g., in the U.S. from 40 years to 60 years, and even potentially to 80 years). The condition and performance of major aged NPP structures such as the containment contributes to the life span of a plant. A frequent misconception of such low degradation rate of SPCs is that such degradation may not pose significant risk to plant safety. However, under low probability high consequence initiating events, such as large earthquakes, SPCs that have slowly degraded over many years could potentially affect plant safety and these effects need to be better understood.As part of the KAERI-BNL collaboration, a condensate storage tank (CST) was analyzed to estimate its seismic fragility capacities under various postulated degradation scenarios. CSTs were shown to have a significant impact on the seismic core damage frequency of a nuclear power plant. The seismic fragility capacity of the CST was developed for five cases: (1) a baseline analysis where the design condition (undegraded) is assumed, (2) a scenario with degraded stainless steel tank shell, (3) a scenario with degraded anchor bolts, (4) a scenario with anchorage concrete cracking, and (5) a perfect correlation of the above three degradation scenarios. This paper will present the methodology for the time-dependent fragility calculation and discuss the insights drawn from this study. ABSTRACT 1To achieve a better understanding of the effects of aging on the performance of structures and passive components (SPCs) in nuclear power plants (NPPs), the Korea Atomic Energy Research Institute (KAERI) and Brookhaven National Laboratory (BNL) are collaborating to develop seismic fragility analysis methods that consider age-related degradation of SPCs. The rate of age-related degradation of SPCs was not found to be significantly large, but increasing as the plants get older. The slow but increasing rate of degradation of SPCs can potentially affect the safety of the older plants and become an important factor in decision making in the current trend of extend...

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Seismic Fragility Analysis of a Condensate Storage Tank with Age-Related Degradations

Nie

Braverman

Hofmayer

et al. 2011

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The Korea Atomic Energy Research Institute (KAERI) is conducting a five-year research project to develop a realistic seismic risk evaluation system which includes the consideration of aging of structures and components in nuclear power plants (NPPs). The KAERI research project includes three specific areas that are essential to seismic probabilistic risk assessment (PRA): (1) probabilistic seismic hazard analysis, (2) seismic fragility analysis including the effects of aging, and (3) a plant seismic risk analysis. Since 2007, Brookhaven National Laboratory (BNL) has entered into a collaboration agreement with KAERI to support its development of seismic capability evaluation technology for degraded structures and components. The collaborative research effort is intended to continue over a five year period. The goal of this collaboration endeavor is to assist KAERI to develop seismic fragility analysis methods that consider the potential effects of age-related degradation of structures, systems, and components (SSCs). The research results of this multi-year collaboration will be utilized as input to seismic PRAs.In the Year 1 scope of work, BNL collected and reviewed degradation occurrences in US NPPs and identified important aging characteristics needed for the seismic capability evaluations. This information is presented in the Annual Report for the Year 1 Task, identified as BNL Report-81741-2008 and also designated as KAERI/RR-2931/2008. The report presents results of the statistical and trending analysis of this data and compares the results to prior aging studies. In addition, the report provides a description of U.S. current regulatory requirements, regulatory guidance documents, generic communications, industry standards and guidance, and past research related to aging degradation of SSCs.In the Year 2 scope of work, BNL carried out a research effort to identify and assess degradation models for the long-term behavior of dominant materials that are determined to be risk significant to NPPs. Multiple models have been identified for concrete, carbon and low-alloy steel, and stainless steel. These models are documented in the Annual Report for the Year 2 Task, identified as BNL Report-82249-2009 and also designated as KAERI/TR-3757/2009.In the Year 3 scope of work, BNL developed the seismic fragility capacities for a condensate storage tank with various degradation scenarios. The conservative deterministic failure margin (CDFM) method was utilized for the undegraded case and was modified to accommodate the degraded cases. A total of five seismic fragility analysis cases were considered: (1) undegraded case, (2) degraded stainless tank shell, (3) degraded anchor bolts, (4) anchorage concrete cracking, and (5) a perfect correlation of the three degradation scenarios. The design water level was used in these studies. The results and insights from these fragility analyses were described in the Annual Report for the Year 3 Task, identified as BNL-93771-2010 and also designated as KAERI/TR-4068/2010. This report des...

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Identification and Assessment of Material Models for Age-Related Degradation of Structures and Passive Components in Nuclear Power Plants

Cited by 3 publications

References 31 publications

A Procedure for Determination of Degradation Acceptance Criteria for Structures and Passive Components in Nuclear Power Plants

A Procedure for Determination of Degradation Acceptance Criteria for Structures and Passive Components in Nuclear Power Plants

Icone19-43630 Seismic Fragility Analysis of a Degraded Condensate Storage Tank

Seismic Fragility Analysis of a Condensate Storage Tank with Age-Related Degradations

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