Preliminary Scaling Analysis of Reactivity Initiated Accidents

Alexander M Duenas; Musa Abdennour Ahmed Moussaoui; Ramon Ken Yoshiura; Hongbin Zhang; Daniel M Wachs

Preliminary Scaling Analysis of Reactivity Initiated Accidents

Alexander M Duenas, Musa Abdennour Ahmed Moussaoui, Ramon Ken Yoshiura, Hongbin Zhang, Daniel M Wachs

Research output: Contribution to conference › Presentation › peer-review

Abstract

The life cycle for new fuel development requires extensive modeling and testing of the fuel concept from benchtop scale experiments to full scale assemblies in prototypical conditions. As a result, the timeline to develop new fuel types can extend up to 20 years and hinders the ability to develop a diverse assortment of fuel types. The licensing of recent reactor designs such as Westinghouse's AP-600/1000 designs utilized a scaling methodology to perform nuclear safety code validation on experimental test data from scaled down thermal hydraulic facilities. The advantage of using a scaling methodology was a significant cost decrease in the testing program because it avoided needing to build full scale prototypes and focused on improving safety code's ability to predict test data. This study investigates how to apply a scaling hierarchy for fuel performance during a Reactivity Initiated Accident that could be implemented with scaling methods such as Hierarchical Two Tiered Scaling (H2TS), Fractional Scaling Analysis (FSA), and Dynamical System Scaling (DSS) .

Original language	English
State	Published - Aug 8 2019
Event	2019 INL Intern Poster Session - Idaho Falls, United States Duration: Aug 8 2019 → Aug 8 2019

Conference

Conference	2019 INL Intern Poster Session
Country/Territory	United States
City	Idaho Falls
Period	08/8/19 → 08/8/19

INL Publication Number

INL/EXP-19-54976

Access to Document

https://www.osti.gov/biblio/1547340

Cite this

@conference{59488c956ca34734a0f1640143b1d43b,

title = "Preliminary Scaling Analysis of Reactivity Initiated Accidents",

abstract = "The life cycle for new fuel development requires extensive modeling and testing of the fuel concept from benchtop scale experiments to full scale assemblies in prototypical conditions. As a result, the timeline to develop new fuel types can extend up to 20 years and hinders the ability to develop a diverse assortment of fuel types. The licensing of recent reactor designs such as Westinghouse's AP-600/1000 designs utilized a scaling methodology to perform nuclear safety code validation on experimental test data from scaled down thermal hydraulic facilities. The advantage of using a scaling methodology was a significant cost decrease in the testing program because it avoided needing to build full scale prototypes and focused on improving safety code's ability to predict test data. This study investigates how to apply a scaling hierarchy for fuel performance during a Reactivity Initiated Accident that could be implemented with scaling methods such as Hierarchical Two Tiered Scaling (H2TS), Fractional Scaling Analysis (FSA), and Dynamical System Scaling (DSS) .",

author = "Duenas, {Alexander M} and {Ahmed Moussaoui}, {Musa Abdennour} and Yoshiura, {Ramon Ken} and Hongbin Zhang and Wachs, {Daniel M}",

year = "2019",

month = aug,

day = "8",

language = "English",

note = "2019 INL Intern Poster Session ; Conference date: 08-08-2019 Through 08-08-2019",

}

TY - CONF

T1 - Preliminary Scaling Analysis of Reactivity Initiated Accidents

AU - Duenas, Alexander M

AU - Ahmed Moussaoui, Musa Abdennour

AU - Yoshiura, Ramon Ken

AU - Zhang, Hongbin

AU - Wachs, Daniel M

PY - 2019/8/8

Y1 - 2019/8/8

N2 - The life cycle for new fuel development requires extensive modeling and testing of the fuel concept from benchtop scale experiments to full scale assemblies in prototypical conditions. As a result, the timeline to develop new fuel types can extend up to 20 years and hinders the ability to develop a diverse assortment of fuel types. The licensing of recent reactor designs such as Westinghouse's AP-600/1000 designs utilized a scaling methodology to perform nuclear safety code validation on experimental test data from scaled down thermal hydraulic facilities. The advantage of using a scaling methodology was a significant cost decrease in the testing program because it avoided needing to build full scale prototypes and focused on improving safety code's ability to predict test data. This study investigates how to apply a scaling hierarchy for fuel performance during a Reactivity Initiated Accident that could be implemented with scaling methods such as Hierarchical Two Tiered Scaling (H2TS), Fractional Scaling Analysis (FSA), and Dynamical System Scaling (DSS) .

AB - The life cycle for new fuel development requires extensive modeling and testing of the fuel concept from benchtop scale experiments to full scale assemblies in prototypical conditions. As a result, the timeline to develop new fuel types can extend up to 20 years and hinders the ability to develop a diverse assortment of fuel types. The licensing of recent reactor designs such as Westinghouse's AP-600/1000 designs utilized a scaling methodology to perform nuclear safety code validation on experimental test data from scaled down thermal hydraulic facilities. The advantage of using a scaling methodology was a significant cost decrease in the testing program because it avoided needing to build full scale prototypes and focused on improving safety code's ability to predict test data. This study investigates how to apply a scaling hierarchy for fuel performance during a Reactivity Initiated Accident that could be implemented with scaling methods such as Hierarchical Two Tiered Scaling (H2TS), Fractional Scaling Analysis (FSA), and Dynamical System Scaling (DSS) .

M3 - Presentation

T2 - 2019 INL Intern Poster Session

Y2 - 8 August 2019 through 8 August 2019

ER -

Preliminary Scaling Analysis of Reactivity Initiated Accidents

Abstract

Conference

INL Publication Number

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