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Modeling of Confined Explosions: An Uncoupled Eulerian-Lagrangian Approach for Blast Wave Propagation and Structural Assessment

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Abstract:

The pressure histories resulting from blast wave interactions with structures are highly influenced by the level of confinement. Fully confined blast events are more severe than their unconfined counterparts due to multiple wave reflections and residual quasi-static pressures, which result in prolonged shock-structure interactions and complex pressure profiles. Most experimental studies have primarily focused on spherical or hemispherical blast waves in free-field conditions, supporting simplified models like the CONWEP algorithm commonly integrated into Finite Element (FE) solvers for unconfined explosions. However, this approach is unsuitable for more complicated scenarios, such as explosions in confined scenarios. The current study presents an approach that integrates CFD with a FE framework. This work focuses on extending the capabilities of the FE solver Abaqus/Explicit to handle these complex load histories, which are beyond the scope of its default built-in configurations. User-defined subroutines are developed to enable an Uncoupled Lagrangian-Eulerian (UEL) framework. CFD simulations are performed independently to calculate pressure histories, then they are subsequently mapped onto structural FE models as input loads. The results demonstrate that the proposed framework extends the range of scenarios that can be analysed for blast wave propagation and its effects on structures. By employing this uncoupled approach, diverse structural simulations can be performed using a single FE model. This study provides a numerical tool for simulating confined explosions, with applications in industrial safety and structural design facilitating improved engineering designs for mitigating blast effects.

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Periodical:

Advances in Science and Technology (Volume 171)

Pages:

177-184

DOI:

https://doi.org/10.4028/p-cUanM5

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Online since:

December 2025

Authors:

Edison Shehu*, Luca Lomazzi, Andrea Manes

Keywords:

Blast Wave, Confined Explosion, Structural Assessment, Uncoupled Eulerian Lagrangian

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© 2025 Trans Tech Publications Ltd. All Rights Reserved

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References

[1] Nurick, G. N., & Martin, J. B. (1989). Deformation of thin plates subjected to impulsive loading—A review: Part I: Theoretical considerations. International Journal of Impact Engineering, 8(2), 159–170.

DOI: 10.1016/0734-743x(89)90014-6

Google Scholar

[2] Nurick, G. N., & Martin, J. B. (1989). Deformation of thin plates subjected to impulsive loading—A review: Part II: Experimental studies. International Journal of Impact Engineering, 8(2), 171–186.

DOI: 10.1016/0734-743x(89)90015-8

Google Scholar

[3] Chung Kim Yuen, S., Nurick, G. N., Langdon, G. S., & Iyer, Y. (2017). Deformation of thin plates subjected to impulsive load: Part III – An update 25 years on. International Journal of Impact Engineering, 107, 108–117.

DOI: 10.1016/j.ijimpeng.2016.06.010

Google Scholar

[4] Lomazzi, L., Giglio, M., & Manes, A. (2021). Analytical and empirical methods for the characterization of the permanent transverse displacement of quadrangular metal plates subjected to blast load: Comparison of existing methods and development of a novel methodological approach. International Journal of Impact Engineering, 154, 103890.

DOI: 10.1016/j.ijimpeng.2021.103890

Google Scholar

[5] Kingery, C. N., & Bulmash, G. (1984). Air blast parameters from TNT spherical air burst and hemispherical surface burst. U.S. Army Ballistic Research Laboratory.

Google Scholar

[6] Hyde, D. (1988). Fundamentals of protective design for conventional weapons: Microcomputer programs CONWEP and FUNPRO, applications of TM 5-855-1 (User's Guide). Department of the Army, Waterways Experiment Station, Corps of Engineers.

Google Scholar

[7] Smith, M. (2009). ABAQUS/Standard User's Manual, Version 6.9. Dassault Systèmes.

Google Scholar

[8] Heylmun, J., Vonk, P., & Brewer, T. (2021). blastFoam 5.0 User Guide. Synthetik Applied Technologies LLC.

Google Scholar

[9] Stewart, D. S. (1993). Lectures on detonation physics: Introduction to the theory of detonation shock dynamics. University of Illinois, Urbana, Illinois.

DOI: 10.21236/ada301339

Google Scholar

[10] Zheng, Z., & Zhao, J. (2016). Unreacted equation of states of typical energetic materials under static compression: A review. Chinese Physics B, 25(7), 076202.

DOI: 10.1088/1674-1056/25/7/076202

Google Scholar

[11] Lee, E. L., Hornig, H. C., & Kury, J. W. (1968). Adiabatic expansion of high explosive detonation products (Lawrence Radiation Laboratory Report UCRL-50422).

DOI: 10.2172/4783904

Google Scholar

[12] Dobratz, B. M. (1985). LLNL explosives handbook: Properties of chemical explosives and explosive simulants (Lawrence Livermore National Laboratory Report UCRL-51319).

DOI: 10.2172/6530310

Google Scholar

[13] Pannell, J. J., Panoutsos, G., Cooke, S. B., Pope, D. J., & Rigby, S. (2021). Predicting specific impulse distributions for spherical explosives in the extreme near field using a Gaussian function. International Journal of Protective Structures, 12(4), 437–459.

DOI: 10.1177/2041419621993492

Google Scholar

[14] Feldgun, V. R., Karinski, Y. S., & Yankelevsky, D. Z. (2011). Some characteristics of an interior explosion within a room without venting. Structural Engineering and Mechanics, 38(5), 633–649.

DOI: 10.12989/sem.2011.38.5.633

Google Scholar

[15] SSAB. (2024, January 30). DOCOL steel grades. Retrieved from https://www.ssab.com/en /brands-and-products/docol

Google Scholar

[16] Aune, V. (2017). Behaviour and modelling of flexible structures subjected to blast loading (Doctoral thesis, Norwegian University of Science and Technology, NTNU).

Google Scholar

[17] Aune, V., Valsamos, G., Casadei, F., Langseth, M., & Børvik, T. (2017). On the dynamic response of blast-loaded steel plates with and without pre-formed holes. International Journal of Impact Engineering, 108, 27–46.

DOI: 10.1016/j.ijimpeng.2017.04.001

Google Scholar