Comparison of TNO multienergy and Baker-Strehlow-Tang models

Ali Sari

doi:10.1002/prs.10424

Comparison of TNO multienergy and Baker-Strehlow-Tang models

Ali Sari^*

^*Corresponding author for this work

Atkins Global

Research output: Contribution to journal › Article › peer-review

18 Citations (Scopus)

Abstract

Vapor cloud explosions (VCEs) cause considerable problems in the chemical and petrochemical industries. They generate damaging levels of overpressure and the possibility of human injury/death, and building/equipment damage. Predicting the possible consequences of VCEs is important to ensure the safe design of existing and new structures. Prediction of the overpressures resulting from a VCE is typically done using simplified (empirical) models, phenomenological models, and computational fluid dynamics models. The focus of this article is on two of the most frequently used simplified prediction methods: TNO multienergy and Baker-Strehlow-Tang models. These models are compared in terms of structural response and vulnerability of damage caused by an explosion.

Original language	English
Pages (from-to)	23-26
Number of pages	4
Journal	Process Safety Progress
Volume	30
Issue number	1
DOIs	https://doi.org/10.1002/prs.10424
Publication status	Published - Mar 2011
Externally published	Yes

Keywords

Blast overpressure
Explosion hazard
Structural damage
Structural response
Vapor cloud explosions

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10.1002/prs.10424

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abstract = "Vapor cloud explosions (VCEs) cause considerable problems in the chemical and petrochemical industries. They generate damaging levels of overpressure and the possibility of human injury/death, and building/equipment damage. Predicting the possible consequences of VCEs is important to ensure the safe design of existing and new structures. Prediction of the overpressures resulting from a VCE is typically done using simplified (empirical) models, phenomenological models, and computational fluid dynamics models. The focus of this article is on two of the most frequently used simplified prediction methods: TNO multienergy and Baker-Strehlow-Tang models. These models are compared in terms of structural response and vulnerability of damage caused by an explosion.",

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AB - Vapor cloud explosions (VCEs) cause considerable problems in the chemical and petrochemical industries. They generate damaging levels of overpressure and the possibility of human injury/death, and building/equipment damage. Predicting the possible consequences of VCEs is important to ensure the safe design of existing and new structures. Prediction of the overpressures resulting from a VCE is typically done using simplified (empirical) models, phenomenological models, and computational fluid dynamics models. The focus of this article is on two of the most frequently used simplified prediction methods: TNO multienergy and Baker-Strehlow-Tang models. These models are compared in terms of structural response and vulnerability of damage caused by an explosion.

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Comparison of TNO multienergy and Baker-Strehlow-Tang models

Abstract

Keywords

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