On models of blast overpressure effects to the thorax

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  • Fraunhofer Institute for High-Speed Dynamics, Ernst Mach Institute (EMI)
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Original languageEnglish
Article number2076
JournalSN Applied Sciences
Volume2
Issue number12
Early online date25 Nov 2020
Publication statusPublished - Dec 2020
Externally publishedYes

Abstract

Shock waves from explosions can cause lethal injuries to humans. Current state-of the-art models for pressure induced lung injuries were typically empirically derived and are only valid for detonations in free-field conditions. In built-up environments, though, pressure–time histories differ significantly from this idealization and not all explosions exhibit detonation characteristics. Hence, those approaches cannot be deployed. However, the actual correlation between dynamic shock wave characteristics and gradual degree of injury have yet to be fully described. In an attempt to characterize the physical response of the human body to complex shock-wave effects, viscoelastic models were developed in the past (Axelsson and Yelverton, in J Trauma Acute Care Surg 40, 31S–37S, 1996; Stuhmiller et al., in J Biomech. https://doi.org/10.1016/0021-9290(95)00039-9, 1996). We discuss those existing modeling approaches especially in view of their viscoelastic behavior and point out drawbacks regarding their response to standard stimuli. Further, we suggest to fully acknowledge the experimentally anticipated viscoelastic behavior of the effective thorax models by using a newly formulated standard model for viscoelastic solids instead of damped harmonic oscillators. Concerning injury assessment, we discuss the individual injury criteria proposed along with existing models pointing out desirable improvements with respect to complex blast situations, e.g. the necessity to account for repeated exposure (criteria with time-memory), and further adaption with respect to nonlinear gas dynamics inside the lung. Finally, we present an improved modeling approach for complex blast overpressure effects to the thorax with few parameters that is more suitable for the characteristics of complex blast wave propagation than other current models.

Keywords

    Blast overpressure, Blast test device, Complex blast propagation, Explosion effects, Injury model, Viscoelastic behavior

ASJC Scopus subject areas

Cite this

On models of blast overpressure effects to the thorax. / Stottmeister, Alexander; von Ramin, Malte; Schneider, Johannes M.
In: SN Applied Sciences, Vol. 2, No. 12, 2076, 12.2020.

Research output: Contribution to journalArticleResearchpeer review

Stottmeister, A, von Ramin, M & Schneider, JM 2020, 'On models of blast overpressure effects to the thorax', SN Applied Sciences, vol. 2, no. 12, 2076. https://doi.org/10.1007/s42452-020-03834-4
Stottmeister, A., von Ramin, M., & Schneider, J. M. (2020). On models of blast overpressure effects to the thorax. SN Applied Sciences, 2(12), Article 2076. https://doi.org/10.1007/s42452-020-03834-4
Stottmeister A, von Ramin M, Schneider JM. On models of blast overpressure effects to the thorax. SN Applied Sciences. 2020 Dec;2(12):2076. Epub 2020 Nov 25. doi: 10.1007/s42452-020-03834-4
Stottmeister, Alexander ; von Ramin, Malte ; Schneider, Johannes M. / On models of blast overpressure effects to the thorax. In: SN Applied Sciences. 2020 ; Vol. 2, No. 12.
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title = "On models of blast overpressure effects to the thorax",
abstract = "Shock waves from explosions can cause lethal injuries to humans. Current state-of the-art models for pressure induced lung injuries were typically empirically derived and are only valid for detonations in free-field conditions. In built-up environments, though, pressure–time histories differ significantly from this idealization and not all explosions exhibit detonation characteristics. Hence, those approaches cannot be deployed. However, the actual correlation between dynamic shock wave characteristics and gradual degree of injury have yet to be fully described. In an attempt to characterize the physical response of the human body to complex shock-wave effects, viscoelastic models were developed in the past (Axelsson and Yelverton, in J Trauma Acute Care Surg 40, 31S–37S, 1996; Stuhmiller et al., in J Biomech. https://doi.org/10.1016/0021-9290(95)00039-9, 1996). We discuss those existing modeling approaches especially in view of their viscoelastic behavior and point out drawbacks regarding their response to standard stimuli. Further, we suggest to fully acknowledge the experimentally anticipated viscoelastic behavior of the effective thorax models by using a newly formulated standard model for viscoelastic solids instead of damped harmonic oscillators. Concerning injury assessment, we discuss the individual injury criteria proposed along with existing models pointing out desirable improvements with respect to complex blast situations, e.g. the necessity to account for repeated exposure (criteria with time-memory), and further adaption with respect to nonlinear gas dynamics inside the lung. Finally, we present an improved modeling approach for complex blast overpressure effects to the thorax with few parameters that is more suitable for the characteristics of complex blast wave propagation than other current models.",
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author = "Alexander Stottmeister and {von Ramin}, Malte and Schneider, {Johannes M.}",
note = "Funding Information: Open Access funding enabled and organized by Projekt DEAL. The research reported herein has received funding from the German Bundeswehr Technical Center for Protective and Special Technologies (WTD 52) as part of the project “Development of ESQRA-GE—Explosives Safety Quantitative Risk Analysis Germany 2017–2019” under grant C/E520/HF003/GF027. This support is gratefully acknowledged. ",
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AU - Stottmeister, Alexander

AU - von Ramin, Malte

AU - Schneider, Johannes M.

N1 - Funding Information: Open Access funding enabled and organized by Projekt DEAL. The research reported herein has received funding from the German Bundeswehr Technical Center for Protective and Special Technologies (WTD 52) as part of the project “Development of ESQRA-GE—Explosives Safety Quantitative Risk Analysis Germany 2017–2019” under grant C/E520/HF003/GF027. This support is gratefully acknowledged.

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N2 - Shock waves from explosions can cause lethal injuries to humans. Current state-of the-art models for pressure induced lung injuries were typically empirically derived and are only valid for detonations in free-field conditions. In built-up environments, though, pressure–time histories differ significantly from this idealization and not all explosions exhibit detonation characteristics. Hence, those approaches cannot be deployed. However, the actual correlation between dynamic shock wave characteristics and gradual degree of injury have yet to be fully described. In an attempt to characterize the physical response of the human body to complex shock-wave effects, viscoelastic models were developed in the past (Axelsson and Yelverton, in J Trauma Acute Care Surg 40, 31S–37S, 1996; Stuhmiller et al., in J Biomech. https://doi.org/10.1016/0021-9290(95)00039-9, 1996). We discuss those existing modeling approaches especially in view of their viscoelastic behavior and point out drawbacks regarding their response to standard stimuli. Further, we suggest to fully acknowledge the experimentally anticipated viscoelastic behavior of the effective thorax models by using a newly formulated standard model for viscoelastic solids instead of damped harmonic oscillators. Concerning injury assessment, we discuss the individual injury criteria proposed along with existing models pointing out desirable improvements with respect to complex blast situations, e.g. the necessity to account for repeated exposure (criteria with time-memory), and further adaption with respect to nonlinear gas dynamics inside the lung. Finally, we present an improved modeling approach for complex blast overpressure effects to the thorax with few parameters that is more suitable for the characteristics of complex blast wave propagation than other current models.

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