Consideration of Alternative Coolants in AGR-like FHR Designs

Marat Margulis; Paul Cosgrove; Eugene Shwageraus

doi:10.13182/PHYSOR22-37788

Consideration of Alternative Coolants in AGR-like FHR Designs

Marat Margulis, Paul Cosgrove, Eugene Shwageraus

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Replacing carbon-dioxide coolant in AGR-like reactor with molten salt significantly affects the reactor performance characteristics. Hence, a new core design is needed. In this work, a Multi-Objective Particle Swarm Optimisation is used to identify the most favourable configurations for a new system layout. The performed analysis examines each configuration with respect to its thermal-hydraulic performance to assess the power uprate potential which is limited by multiple temperature constraints (e.g. fuel centreline and cladding temperatures as well as the coolant freezing/boiling). The estimated maximum power was then used in the fuel burnup calculations, from which a discharge burnup and cycle average Coolant Temperature Coefficients (CTC) were obtained. As a result of the optimisation process, several families of possible solutions were identified, which form an optimal Pareto Front. The most attractive configurations in terms of achievable power density, however, were not necessarily on the Pareto front. Several coolant options are examined and compared in this paper. The newly identified design options have the potential to achieve power density that is higher than that of a typical AGR by up to a factor of five while maintaining negative CTC through the burnup cycle.

Original language	English
Title of host publication	Proceedings of the International Conference on Physics of Reactors, PHYSOR 2022
Publisher	American Nuclear Society
Pages	134-142
Number of pages	9
ISBN (Electronic)	9780894487873
DOIs	https://doi.org/10.13182/PHYSOR22-37788
State	Published - 1 Jan 2022
Externally published	Yes
Event	2022 International Conference on Physics of Reactors, PHYSOR 2022 - Pittsburgh, United States Duration: 15 May 2022 → 20 May 2022

Publication series

Name	Proceedings of the International Conference on Physics of Reactors, PHYSOR 2022

Conference

Conference	2022 International Conference on Physics of Reactors, PHYSOR 2022
Country/Territory	United States
City	Pittsburgh
Period	15/05/22 → 20/05/22

Keywords

AGR
AGRESR
FHR
FLiBe
MOPSO
NaFZrF

ASJC Scopus subject areas

Nuclear Energy and Engineering
Safety, Risk, Reliability and Quality
Nuclear and High Energy Physics
Radiation

Access to Document

10.13182/PHYSOR22-37788

Cite this

@inproceedings{2df4af738e634b6591914ef8d0091faf,

title = "Consideration of Alternative Coolants in AGR-like FHR Designs",

abstract = "Replacing carbon-dioxide coolant in AGR-like reactor with molten salt significantly affects the reactor performance characteristics. Hence, a new core design is needed. In this work, a Multi-Objective Particle Swarm Optimisation is used to identify the most favourable configurations for a new system layout. The performed analysis examines each configuration with respect to its thermal-hydraulic performance to assess the power uprate potential which is limited by multiple temperature constraints (e.g. fuel centreline and cladding temperatures as well as the coolant freezing/boiling). The estimated maximum power was then used in the fuel burnup calculations, from which a discharge burnup and cycle average Coolant Temperature Coefficients (CTC) were obtained. As a result of the optimisation process, several families of possible solutions were identified, which form an optimal Pareto Front. The most attractive configurations in terms of achievable power density, however, were not necessarily on the Pareto front. Several coolant options are examined and compared in this paper. The newly identified design options have the potential to achieve power density that is higher than that of a typical AGR by up to a factor of five while maintaining negative CTC through the burnup cycle.",

keywords = "AGR, AGRESR, FHR, FLiBe, MOPSO, NaFZrF",

author = "Marat Margulis and Paul Cosgrove and Eugene Shwageraus",

note = "Publisher Copyright: {\textcopyright} 2022 Proceedings of the International Conference on Physics of Reactors, PHYSOR 2022. All Rights Reserved.; 2022 International Conference on Physics of Reactors, PHYSOR 2022 ; Conference date: 15-05-2022 Through 20-05-2022",

year = "2022",

month = jan,

day = "1",

doi = "10.13182/PHYSOR22-37788",

language = "English",

series = "Proceedings of the International Conference on Physics of Reactors, PHYSOR 2022",

publisher = "American Nuclear Society",

pages = "134--142",

booktitle = "Proceedings of the International Conference on Physics of Reactors, PHYSOR 2022",

address = "United States",

}

Margulis, M, Cosgrove, P & Shwageraus, E 2022, Consideration of Alternative Coolants in AGR-like FHR Designs. in Proceedings of the International Conference on Physics of Reactors, PHYSOR 2022. Proceedings of the International Conference on Physics of Reactors, PHYSOR 2022, American Nuclear Society, pp. 134-142, 2022 International Conference on Physics of Reactors, PHYSOR 2022, Pittsburgh, United States, 15/05/22. https://doi.org/10.13182/PHYSOR22-37788

Consideration of Alternative Coolants in AGR-like FHR Designs. / Margulis, Marat; Cosgrove, Paul; Shwageraus, Eugene.
Proceedings of the International Conference on Physics of Reactors, PHYSOR 2022. American Nuclear Society, 2022. p. 134-142 (Proceedings of the International Conference on Physics of Reactors, PHYSOR 2022).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Consideration of Alternative Coolants in AGR-like FHR Designs

AU - Margulis, Marat

AU - Cosgrove, Paul

AU - Shwageraus, Eugene

PY - 2022/1/1

Y1 - 2022/1/1

N2 - Replacing carbon-dioxide coolant in AGR-like reactor with molten salt significantly affects the reactor performance characteristics. Hence, a new core design is needed. In this work, a Multi-Objective Particle Swarm Optimisation is used to identify the most favourable configurations for a new system layout. The performed analysis examines each configuration with respect to its thermal-hydraulic performance to assess the power uprate potential which is limited by multiple temperature constraints (e.g. fuel centreline and cladding temperatures as well as the coolant freezing/boiling). The estimated maximum power was then used in the fuel burnup calculations, from which a discharge burnup and cycle average Coolant Temperature Coefficients (CTC) were obtained. As a result of the optimisation process, several families of possible solutions were identified, which form an optimal Pareto Front. The most attractive configurations in terms of achievable power density, however, were not necessarily on the Pareto front. Several coolant options are examined and compared in this paper. The newly identified design options have the potential to achieve power density that is higher than that of a typical AGR by up to a factor of five while maintaining negative CTC through the burnup cycle.

AB - Replacing carbon-dioxide coolant in AGR-like reactor with molten salt significantly affects the reactor performance characteristics. Hence, a new core design is needed. In this work, a Multi-Objective Particle Swarm Optimisation is used to identify the most favourable configurations for a new system layout. The performed analysis examines each configuration with respect to its thermal-hydraulic performance to assess the power uprate potential which is limited by multiple temperature constraints (e.g. fuel centreline and cladding temperatures as well as the coolant freezing/boiling). The estimated maximum power was then used in the fuel burnup calculations, from which a discharge burnup and cycle average Coolant Temperature Coefficients (CTC) were obtained. As a result of the optimisation process, several families of possible solutions were identified, which form an optimal Pareto Front. The most attractive configurations in terms of achievable power density, however, were not necessarily on the Pareto front. Several coolant options are examined and compared in this paper. The newly identified design options have the potential to achieve power density that is higher than that of a typical AGR by up to a factor of five while maintaining negative CTC through the burnup cycle.

KW - AGR

KW - AGRESR

KW - FHR

KW - FLiBe

KW - MOPSO

KW - NaFZrF

UR - http://www.scopus.com/inward/record.url?scp=85184962242&partnerID=8YFLogxK

U2 - 10.13182/PHYSOR22-37788

DO - 10.13182/PHYSOR22-37788

M3 - Conference contribution

AN - SCOPUS:85184962242

T3 - Proceedings of the International Conference on Physics of Reactors, PHYSOR 2022

SP - 134

EP - 142

BT - Proceedings of the International Conference on Physics of Reactors, PHYSOR 2022

PB - American Nuclear Society

T2 - 2022 International Conference on Physics of Reactors, PHYSOR 2022

Y2 - 15 May 2022 through 20 May 2022

ER -

Consideration of Alternative Coolants in AGR-like FHR Designs

Abstract

Publication series

Conference

Keywords

ASJC Scopus subject areas

Access to Document

Other files and links

Fingerprint

Cite this