Validation and Verification of ASYST Code for Predicting Condensation Phenomena in Nuclear Reactor Safety Systems

Satya Prakash Saraswat; Mubashir Hassan; Sameer Mohammad Osman; Chris Allison; Yacine Addad

doi:10.1115/ICONE31-134294

Validation and Verification of ASYST Code for Predicting Condensation Phenomena in Nuclear Reactor Safety Systems

Satya Prakash Saraswat, Mubashir Hassan, Sameer Mohammad Osman, Chris Allison, Yacine Addad

Mechanical & Nuclear Engineering

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

1 Scopus citations

Abstract

The ASYST (Adaptive System Thermal-Hydraulic) code series is a recent development that integrates the functionalities of SCDAPSIM and SAMPSON. It can simulate and analyze fluid and reactor systems with Best Estimate Plus Uncertainty (BEPU) capability. The proposed work involves conducting a thorough validation and verification process for the ASYST code model to predict the condensation phenomena using a condensation-separate effect test facility (present at the Department of Mechanical and Nuclear Engineering, Khalifa University), specifically focusing on the condensation phase. The condensation separate effect test's experimental facility was devised by members of the thermal-hydraulic team affiliated with the Nuclear Engineering Department at Khalifa University's Emirates Nuclear Technology Centre. This apparatus is specifically configured to acquire dependable data on condensation heat transfer analysis in a vertical tube simulating the condensing element within a Passive Containment Cooling System (PCCS), wherein steam and non-condensable gas mixtures are examined. The aim is to provide a detailed description of how the ASYST code aligns with and accurately represents the outcomes of the test facility. The condensation of the separate effect test facility is a critical benchmark for this validation and verification framework. By scrutinizing the code's performance concerning the test facility outcomes, this approach comprehensively evaluates the ASYST code's reliability and applicability to practical scenarios of nuclear reactors' passive safety systems.

Original language	British English
Title of host publication	Risk Assessments and Management; Computer Code Verification and Validation; Nuclear Education and Public Acceptance
ISBN (Electronic)	9780791888308
DOIs	https://doi.org/10.1115/ICONE31-134294
State	Published - 2024
Event	2024 31st International Conference on Nuclear Engineering, ICONE 2024 - Prague, Czech Republic Duration: 4 Aug 2024 → 8 Aug 2024

Publication series

Name	Proceedings of 2024 31st International Conference on Nuclear Engineering, ICONE 2024
Volume	10

Conference

Conference	2024 31st International Conference on Nuclear Engineering, ICONE 2024
Country/Territory	Czech Republic
City	Prague
Period	4/08/24 → 8/08/24

Keywords

ASYST code
Code validation and Verification
Condensation phenomena
Separate effect test facility

Access to Document

10.1115/ICONE31-134294

Cite this

Saraswat, S. P., Hassan, M., Osman, S. M., Allison, C., & Addad, Y. (2024). Validation and Verification of ASYST Code for Predicting Condensation Phenomena in Nuclear Reactor Safety Systems. In Risk Assessments and Management; Computer Code Verification and Validation; Nuclear Education and Public Acceptance Article v010t13a005 (Proceedings of 2024 31st International Conference on Nuclear Engineering, ICONE 2024; Vol. 10). https://doi.org/10.1115/ICONE31-134294

Saraswat, Satya Prakash ; Hassan, Mubashir ; Osman, Sameer Mohammad et al. / Validation and Verification of ASYST Code for Predicting Condensation Phenomena in Nuclear Reactor Safety Systems. Risk Assessments and Management; Computer Code Verification and Validation; Nuclear Education and Public Acceptance. 2024. (Proceedings of 2024 31st International Conference on Nuclear Engineering, ICONE 2024).

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title = "Validation and Verification of ASYST Code for Predicting Condensation Phenomena in Nuclear Reactor Safety Systems",

abstract = "The ASYST (Adaptive System Thermal-Hydraulic) code series is a recent development that integrates the functionalities of SCDAPSIM and SAMPSON. It can simulate and analyze fluid and reactor systems with Best Estimate Plus Uncertainty (BEPU) capability. The proposed work involves conducting a thorough validation and verification process for the ASYST code model to predict the condensation phenomena using a condensation-separate effect test facility (present at the Department of Mechanical and Nuclear Engineering, Khalifa University), specifically focusing on the condensation phase. The condensation separate effect test's experimental facility was devised by members of the thermal-hydraulic team affiliated with the Nuclear Engineering Department at Khalifa University's Emirates Nuclear Technology Centre. This apparatus is specifically configured to acquire dependable data on condensation heat transfer analysis in a vertical tube simulating the condensing element within a Passive Containment Cooling System (PCCS), wherein steam and non-condensable gas mixtures are examined. The aim is to provide a detailed description of how the ASYST code aligns with and accurately represents the outcomes of the test facility. The condensation of the separate effect test facility is a critical benchmark for this validation and verification framework. By scrutinizing the code's performance concerning the test facility outcomes, this approach comprehensively evaluates the ASYST code's reliability and applicability to practical scenarios of nuclear reactors' passive safety systems.",

keywords = "ASYST code, Code validation and Verification, Condensation phenomena, Separate effect test facility",

author = "Saraswat, \{Satya Prakash\} and Mubashir Hassan and Osman, \{Sameer Mohammad\} and Chris Allison and Yacine Addad",

note = "Publisher Copyright: Copyright {\textcopyright} 2024 by ASME.; 2024 31st International Conference on Nuclear Engineering, ICONE 2024 ; Conference date: 04-08-2024 Through 08-08-2024",

year = "2024",

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Saraswat, SP, Hassan, M, Osman, SM, Allison, C & Addad, Y 2024, Validation and Verification of ASYST Code for Predicting Condensation Phenomena in Nuclear Reactor Safety Systems. in Risk Assessments and Management; Computer Code Verification and Validation; Nuclear Education and Public Acceptance., v010t13a005, Proceedings of 2024 31st International Conference on Nuclear Engineering, ICONE 2024, vol. 10, 2024 31st International Conference on Nuclear Engineering, ICONE 2024, Prague, Czech Republic, 4/08/24. https://doi.org/10.1115/ICONE31-134294

Validation and Verification of ASYST Code for Predicting Condensation Phenomena in Nuclear Reactor Safety Systems. / Saraswat, Satya Prakash; Hassan, Mubashir; Osman, Sameer Mohammad et al.
Risk Assessments and Management; Computer Code Verification and Validation; Nuclear Education and Public Acceptance. 2024. v010t13a005 (Proceedings of 2024 31st International Conference on Nuclear Engineering, ICONE 2024; Vol. 10).

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

TY - GEN

T1 - Validation and Verification of ASYST Code for Predicting Condensation Phenomena in Nuclear Reactor Safety Systems

AU - Saraswat, Satya Prakash

AU - Hassan, Mubashir

AU - Osman, Sameer Mohammad

AU - Allison, Chris

AU - Addad, Yacine

PY - 2024

Y1 - 2024

N2 - The ASYST (Adaptive System Thermal-Hydraulic) code series is a recent development that integrates the functionalities of SCDAPSIM and SAMPSON. It can simulate and analyze fluid and reactor systems with Best Estimate Plus Uncertainty (BEPU) capability. The proposed work involves conducting a thorough validation and verification process for the ASYST code model to predict the condensation phenomena using a condensation-separate effect test facility (present at the Department of Mechanical and Nuclear Engineering, Khalifa University), specifically focusing on the condensation phase. The condensation separate effect test's experimental facility was devised by members of the thermal-hydraulic team affiliated with the Nuclear Engineering Department at Khalifa University's Emirates Nuclear Technology Centre. This apparatus is specifically configured to acquire dependable data on condensation heat transfer analysis in a vertical tube simulating the condensing element within a Passive Containment Cooling System (PCCS), wherein steam and non-condensable gas mixtures are examined. The aim is to provide a detailed description of how the ASYST code aligns with and accurately represents the outcomes of the test facility. The condensation of the separate effect test facility is a critical benchmark for this validation and verification framework. By scrutinizing the code's performance concerning the test facility outcomes, this approach comprehensively evaluates the ASYST code's reliability and applicability to practical scenarios of nuclear reactors' passive safety systems.

AB - The ASYST (Adaptive System Thermal-Hydraulic) code series is a recent development that integrates the functionalities of SCDAPSIM and SAMPSON. It can simulate and analyze fluid and reactor systems with Best Estimate Plus Uncertainty (BEPU) capability. The proposed work involves conducting a thorough validation and verification process for the ASYST code model to predict the condensation phenomena using a condensation-separate effect test facility (present at the Department of Mechanical and Nuclear Engineering, Khalifa University), specifically focusing on the condensation phase. The condensation separate effect test's experimental facility was devised by members of the thermal-hydraulic team affiliated with the Nuclear Engineering Department at Khalifa University's Emirates Nuclear Technology Centre. This apparatus is specifically configured to acquire dependable data on condensation heat transfer analysis in a vertical tube simulating the condensing element within a Passive Containment Cooling System (PCCS), wherein steam and non-condensable gas mixtures are examined. The aim is to provide a detailed description of how the ASYST code aligns with and accurately represents the outcomes of the test facility. The condensation of the separate effect test facility is a critical benchmark for this validation and verification framework. By scrutinizing the code's performance concerning the test facility outcomes, this approach comprehensively evaluates the ASYST code's reliability and applicability to practical scenarios of nuclear reactors' passive safety systems.

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KW - Code validation and Verification

KW - Condensation phenomena

KW - Separate effect test facility

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DO - 10.1115/ICONE31-134294

M3 - Conference contribution

AN - SCOPUS:85209213672

T3 - Proceedings of 2024 31st International Conference on Nuclear Engineering, ICONE 2024

BT - Risk Assessments and Management; Computer Code Verification and Validation; Nuclear Education and Public Acceptance

T2 - 2024 31st International Conference on Nuclear Engineering, ICONE 2024

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Saraswat SP, Hassan M, Osman SM, Allison C, Addad Y. Validation and Verification of ASYST Code for Predicting Condensation Phenomena in Nuclear Reactor Safety Systems. In Risk Assessments and Management; Computer Code Verification and Validation; Nuclear Education and Public Acceptance. 2024. v010t13a005. (Proceedings of 2024 31st International Conference on Nuclear Engineering, ICONE 2024). doi: 10.1115/ICONE31-134294

Validation and Verification of ASYST Code for Predicting Condensation Phenomena in Nuclear Reactor Safety Systems

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