Safety of nuclear reactors part A: Unsteady state temperature history mathematical model

A nuclear reactor structure under abnormal operations of near meltdown will be exposed to a tremendous amount of heat flux in addition to the stress field applied under normal operation. Temperature encountered in such case is assumed to be beyond 1000�C. A mathematical model has been developed for...

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Main Authors: El-Shayeb M., Yusoff M.Z., Boosroh M.H., Bondok A., Ideris F., Hassan S.H.A.
Other Authors: 55241188800
Format: Conference paper
Published: American Society of Mechanical Engineers 2023
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spelling my.uniten.dspace-298752023-12-28T16:58:01Z Safety of nuclear reactors part A: Unsteady state temperature history mathematical model El-Shayeb M. Yusoff M.Z. Boosroh M.H. Bondok A. Ideris F. Hassan S.H.A. 55241188800 7003976733 6506812468 6602622813 7801415444 7201618347 Accident prevention Columns (structural) Core meltdown Finite difference method Fire resistance Heat flux Heat transfer Mathematical models Partial differential equations Steel structures Stress analysis Thermal effects Nuclear radiation Steel columns Stress fields Temperature history Nuclear reactors A nuclear reactor structure under abnormal operations of near meltdown will be exposed to a tremendous amount of heat flux in addition to the stress field applied under normal operation. Temperature encountered in such case is assumed to be beyond 1000�C. A mathematical model has been developed for the fire resistance calculation of a concrete-filled square steel column with respect to its temperature history. Effects due to nuclear radiation and mechanical vibrations will be explored in a later future model. The temperature rise in each element can be derived from its heat balance by applying the parabolic unsteady state, partial differential equation and numerical solution into the steel region. Calculation of the temperature of the elementary regions needs to satisfy the symmetry conditions and the relevant material properties. The developed mathematical model is capable to predict the temperature history in the column and on the surface with respect to time. Final 2023-12-28T08:58:01Z 2023-12-28T08:58:01Z 2004 Conference paper 10.1115/icone12-49409 2-s2.0-10644295375 https://www.scopus.com/inward/record.uri?eid=2-s2.0-10644295375&doi=10.1115%2ficone12-49409&partnerID=40&md5=4a36c3f1d5254662100e03160fec473e https://irepository.uniten.edu.my/handle/123456789/29875 2 485 493 American Society of Mechanical Engineers Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Accident prevention
Columns (structural)
Core meltdown
Finite difference method
Fire resistance
Heat flux
Heat transfer
Mathematical models
Partial differential equations
Steel structures
Stress analysis
Thermal effects
Nuclear radiation
Steel columns
Stress fields
Temperature history
Nuclear reactors
spellingShingle Accident prevention
Columns (structural)
Core meltdown
Finite difference method
Fire resistance
Heat flux
Heat transfer
Mathematical models
Partial differential equations
Steel structures
Stress analysis
Thermal effects
Nuclear radiation
Steel columns
Stress fields
Temperature history
Nuclear reactors
El-Shayeb M.
Yusoff M.Z.
Boosroh M.H.
Bondok A.
Ideris F.
Hassan S.H.A.
Safety of nuclear reactors part A: Unsteady state temperature history mathematical model
description A nuclear reactor structure under abnormal operations of near meltdown will be exposed to a tremendous amount of heat flux in addition to the stress field applied under normal operation. Temperature encountered in such case is assumed to be beyond 1000�C. A mathematical model has been developed for the fire resistance calculation of a concrete-filled square steel column with respect to its temperature history. Effects due to nuclear radiation and mechanical vibrations will be explored in a later future model. The temperature rise in each element can be derived from its heat balance by applying the parabolic unsteady state, partial differential equation and numerical solution into the steel region. Calculation of the temperature of the elementary regions needs to satisfy the symmetry conditions and the relevant material properties. The developed mathematical model is capable to predict the temperature history in the column and on the surface with respect to time.
author2 55241188800
author_facet 55241188800
El-Shayeb M.
Yusoff M.Z.
Boosroh M.H.
Bondok A.
Ideris F.
Hassan S.H.A.
format Conference paper
author El-Shayeb M.
Yusoff M.Z.
Boosroh M.H.
Bondok A.
Ideris F.
Hassan S.H.A.
author_sort El-Shayeb M.
title Safety of nuclear reactors part A: Unsteady state temperature history mathematical model
title_short Safety of nuclear reactors part A: Unsteady state temperature history mathematical model
title_full Safety of nuclear reactors part A: Unsteady state temperature history mathematical model
title_fullStr Safety of nuclear reactors part A: Unsteady state temperature history mathematical model
title_full_unstemmed Safety of nuclear reactors part A: Unsteady state temperature history mathematical model
title_sort safety of nuclear reactors part a: unsteady state temperature history mathematical model
publisher American Society of Mechanical Engineers
publishDate 2023
_version_ 1806427416057348096
score 13.214268