Numerical modelling of interaction between aluminium structure and explosion in soil

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Jian Yu Chen
  • Dian Lei Feng
  • Fue Sang Lien
  • Eugene Yee
  • Shu Xin Deng
  • Fei Gao
  • Chong Peng

Organisationseinheiten

Externe Organisationen

  • Nanjing University of Science and Technology
  • University of Waterloo
  • Universität für Bodenkultur Wien (BOKU)
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Details

OriginalspracheEnglisch
Seiten (von - bis)760-784
Seitenumfang25
FachzeitschriftApplied mathematical modelling
Jahrgang99
Frühes Online-Datum18 Juli 2021
PublikationsstatusVeröffentlicht - Nov. 2021

Abstract

In this paper, a graphics processing unit-accelerated smoothed particle hydrodynamics solver is presented to simulate the three-dimensional explosions in soils and their damage to aluminium structures. To achieve this objective, a number of equations of state and constitutive models required to close the governing equations are incorporated into the proposed smoothed particle hydrodynamics framework, including the Jones-Wilkins-Lee equation of state for explosive materials, the Grüneisen equation of state for metals, the elastic-perfectly plastic constitutive model for metals, and the elastoplastic and elasto-viscoplastic constitutive models for soils. The proposed smoothed particle hydrodynamics methodology was implemented using the Compute Unified Device Architecture programming interface on an NVIDIA graphics processing unit in order to improve the computational efficiency. The various components of the proposed methodology were validated using four test cases, namely, a C4 detonation and an aluminium bar expanded by denotation to validate the modelling of explosion, a cylindrical Taylor bar impact test case to validate the modelling of large deformation in metals, a sand collapse test for the modelling of soils. Following the validation, the proposed method was used to simulate the detonation of an explosive material (C4) in soil and the concomitant deformation of an aluminium plate resulting from this explosion. The predicted results of this simulation are shown to be in good conformance with available experimental data. Finally, it is shown that the proposed graphics processing unit-accelerated SPH solver is able to model interaction problems involving millions of particles in a reasonable time.

ASJC Scopus Sachgebiete

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Numerical modelling of interaction between aluminium structure and explosion in soil. / Chen, Jian Yu; Feng, Dian Lei; Lien, Fue Sang et al.
in: Applied mathematical modelling, Jahrgang 99, 11.2021, S. 760-784.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Chen, J. Y., Feng, D. L., Lien, F. S., Yee, E., Deng, S. X., Gao, F., & Peng, C. (2021). Numerical modelling of interaction between aluminium structure and explosion in soil. Applied mathematical modelling, 99, 760-784. https://doi.org/10.1016/j.apm.2021.07.010
Chen JY, Feng DL, Lien FS, Yee E, Deng SX, Gao F et al. Numerical modelling of interaction between aluminium structure and explosion in soil. Applied mathematical modelling. 2021 Nov;99:760-784. Epub 2021 Jul 18. doi: 10.1016/j.apm.2021.07.010
Chen, Jian Yu ; Feng, Dian Lei ; Lien, Fue Sang et al. / Numerical modelling of interaction between aluminium structure and explosion in soil. in: Applied mathematical modelling. 2021 ; Jahrgang 99. S. 760-784.
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title = "Numerical modelling of interaction between aluminium structure and explosion in soil",
abstract = "In this paper, a graphics processing unit-accelerated smoothed particle hydrodynamics solver is presented to simulate the three-dimensional explosions in soils and their damage to aluminium structures. To achieve this objective, a number of equations of state and constitutive models required to close the governing equations are incorporated into the proposed smoothed particle hydrodynamics framework, including the Jones-Wilkins-Lee equation of state for explosive materials, the Gr{\"u}neisen equation of state for metals, the elastic-perfectly plastic constitutive model for metals, and the elastoplastic and elasto-viscoplastic constitutive models for soils. The proposed smoothed particle hydrodynamics methodology was implemented using the Compute Unified Device Architecture programming interface on an NVIDIA graphics processing unit in order to improve the computational efficiency. The various components of the proposed methodology were validated using four test cases, namely, a C4 detonation and an aluminium bar expanded by denotation to validate the modelling of explosion, a cylindrical Taylor bar impact test case to validate the modelling of large deformation in metals, a sand collapse test for the modelling of soils. Following the validation, the proposed method was used to simulate the detonation of an explosive material (C4) in soil and the concomitant deformation of an aluminium plate resulting from this explosion. The predicted results of this simulation are shown to be in good conformance with available experimental data. Finally, it is shown that the proposed graphics processing unit-accelerated SPH solver is able to model interaction problems involving millions of particles in a reasonable time.",
keywords = "Aluminium plate damage, Explosive detonation in soil, Graphics processing unit acceleration, Smoothed particle hydrodynamics",
author = "Chen, {Jian Yu} and Feng, {Dian Lei} and Lien, {Fue Sang} and Eugene Yee and Deng, {Shu Xin} and Fei Gao and Chong Peng",
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T1 - Numerical modelling of interaction between aluminium structure and explosion in soil

AU - Chen, Jian Yu

AU - Feng, Dian Lei

AU - Lien, Fue Sang

AU - Yee, Eugene

AU - Deng, Shu Xin

AU - Gao, Fei

AU - Peng, Chong

N1 - Funding information: The authors acknowledge the financial support provided by the National Natural Science Foundation of China (grant agreement no. 51909120).

PY - 2021/11

Y1 - 2021/11

N2 - In this paper, a graphics processing unit-accelerated smoothed particle hydrodynamics solver is presented to simulate the three-dimensional explosions in soils and their damage to aluminium structures. To achieve this objective, a number of equations of state and constitutive models required to close the governing equations are incorporated into the proposed smoothed particle hydrodynamics framework, including the Jones-Wilkins-Lee equation of state for explosive materials, the Grüneisen equation of state for metals, the elastic-perfectly plastic constitutive model for metals, and the elastoplastic and elasto-viscoplastic constitutive models for soils. The proposed smoothed particle hydrodynamics methodology was implemented using the Compute Unified Device Architecture programming interface on an NVIDIA graphics processing unit in order to improve the computational efficiency. The various components of the proposed methodology were validated using four test cases, namely, a C4 detonation and an aluminium bar expanded by denotation to validate the modelling of explosion, a cylindrical Taylor bar impact test case to validate the modelling of large deformation in metals, a sand collapse test for the modelling of soils. Following the validation, the proposed method was used to simulate the detonation of an explosive material (C4) in soil and the concomitant deformation of an aluminium plate resulting from this explosion. The predicted results of this simulation are shown to be in good conformance with available experimental data. Finally, it is shown that the proposed graphics processing unit-accelerated SPH solver is able to model interaction problems involving millions of particles in a reasonable time.

AB - In this paper, a graphics processing unit-accelerated smoothed particle hydrodynamics solver is presented to simulate the three-dimensional explosions in soils and their damage to aluminium structures. To achieve this objective, a number of equations of state and constitutive models required to close the governing equations are incorporated into the proposed smoothed particle hydrodynamics framework, including the Jones-Wilkins-Lee equation of state for explosive materials, the Grüneisen equation of state for metals, the elastic-perfectly plastic constitutive model for metals, and the elastoplastic and elasto-viscoplastic constitutive models for soils. The proposed smoothed particle hydrodynamics methodology was implemented using the Compute Unified Device Architecture programming interface on an NVIDIA graphics processing unit in order to improve the computational efficiency. The various components of the proposed methodology were validated using four test cases, namely, a C4 detonation and an aluminium bar expanded by denotation to validate the modelling of explosion, a cylindrical Taylor bar impact test case to validate the modelling of large deformation in metals, a sand collapse test for the modelling of soils. Following the validation, the proposed method was used to simulate the detonation of an explosive material (C4) in soil and the concomitant deformation of an aluminium plate resulting from this explosion. The predicted results of this simulation are shown to be in good conformance with available experimental data. Finally, it is shown that the proposed graphics processing unit-accelerated SPH solver is able to model interaction problems involving millions of particles in a reasonable time.

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