A far-field blast loads high-fidelity numerical simulation after considering concepts from the defense simulation domain

Abstract

Blast-wave propagation and its interaction with protective equipment are a critical concern in defense and industrial safety applications. In this study, we present a comprehensive numerical investigation of blast loads on protective plates by utilizing OpenFOAM. We tested different parameters and their effects on blasting by conducting 42 different scenarios. These scenarios involve both TNT and C-4 explosives, three standoff distances of 5, 10 and 15 m, and masses ranging from 10 g to 2 kg. Also, we tested two target geometries, namely a rectangular plate and an octagonal plate. The numerical approach employed Eulerian, compressible fluid dynamics with ideal gas equations of state for air and Jones–Wilkins–Lee (JWL) equations for detonation products. Through the simulations, key blast parameters such as peak overpressure, impulse, decay coefficients and positive phase duration were extracted and analyzed. A hyperbolic relationship between overpressure and scaled distance was found for both types of explosives, which is consistent with established empirical methods. Also, the dependency of the blast-wave decay coefficient on explosive loading was found to be linear in the case of the rectangular target and following a power-law dependence for octagonal geometries. The peak overpressure and decay coefficient were found to be higher in the octagonal geometry compared with the rectangular plate, attributed to more coherent wave reflection and reduced edge effects. The study provides validated numerical results and parameters relevant to the development of blast protective equipment.

Keywords

Far field blast wave pressure profile decay coefficient detonation simulation OpenFOAM TNT C-4

Get full access to this article

View all access options for this article.

References

Zhang

G-S

Tang

M-J.

The investigation of a devastating accident—an accidental explosion of 40 tons of TNT. J Hazard Mater 1993; 34: 225–233.

Wang

Cui

Research on the evolution models and risk of disaster-induced storage tank explosions in a smart city. Electronics 2024; 13: 2078.

Kaya

Evaluation of the effects of explosions: a ten-year retrospective study. Turk J Trauma Emerg Surg 2025; 31: 233–241.

Chatterjee

Deb

Datta

, et al. Common explosives (TNT, RDX, HMX) and their fate in the environment: emphasizing bioremediation. Chemosphere 2017; 184: 438–451.

Mohotti

Wijesooriya

Weckert

A simplified approach to modelling blasts in computational fluid dynamics (CFD). Def Technol 2023; 23: 19–34.

Sedman

Hepper

Protection of the lung from blast overpressure by stress wave decouplers, buffer plates or sandwich panels. J R Army Med Corps 2019; 165: 22–26.

Shirbhate

Goel

MD.

A critical review of blast wave parameters and approaches for blast load mitigation. Arch Comput Methods Eng 2021; 28: 1713–1730.

Sekine

Saitoh

Yoshimura

, et al. Efficacy of body armor in protection against blast injuries using a swine model in a confined space with a blast tube. Ann Biomed Eng 2021; 49: 2944–2956.

Kiriu

Saitoh

Sekine

, et al. Effectiveness of body armor against shock waves: preventing blast injury in a confined space. Cureus 2024; 16: e57568.

10.

Lustig

Gefen

Epstein

Finite element modeling framework for evaluating the efficacy of protective plates in minimizing organ and tissue damage resulting from a blast wave impact. J Mech Behav Biomed Mater 2025; 169: 107070.

11.

Draganić

Varevac

Lukić

An overview of methods for blast load testing and devices for pressure measurement. Adv Civ Eng 2018; 2018: 3780482.

12.

Mihali

Rebelo

Cismaşiu

, et al. Impact of building model complexity on predicting external explosion consequences. Eng Struct 2025; 339: 120534.

13.

Marx

Werts

KM.

The application of pressure–impulse curves in a blast exceedance analysis. J Loss Prev Process Ind 2013; 26: 478–482.

14.

Lukić

Draganić

Gazić

, et al. Statistical analysis of blast wave decay coefficient and maximum pressure based on experimental results. In: Conference: SUSI, Edinburgh, 9–11 June 2020, pp. 65–78. Southampton: WIT Press.

15.

Hao

, et al. Review of the current practices in blast-resistant analysis and design of concrete structures. Adv Struct Eng 2016; 19: 1193–1223.

16.

Baker

WE.

Explosion hazards and evaluation. Amsterdam and New York: Elsevier, 1983.

17.

Dhir

and University of Dundee (eds). Application of codes, design and regulations. In: Proceedings of the international conference held at the University of Dundee, Scotland, 5–7 July 2005. London: Telford.

18.

Rigby

Tyas

Curry

, et al. Experimental measurement of specific impulse distribution and transient deformation of plates subjected to near-field explosive blasts. Exp Mech 2019; 59: 163–178.

19.

Wang

Ding

Zhao

, et al. Blasting vibration law and prediction in the near-field of tunnel. Shock Vib 2022; 2022: 1–11.

20.

Yang

Rocque

Katsabanis

, et al. Measurement and analysis of near-field blast vibration and damage. Geotech Geol Eng 1994; 12: 169–182.

21.

Ratcliff

Rigby

Clarke

, et al. A review of blast loading in the urban environment. Appl Sci 2023; 13: 5349.

22.

Stanislawek

Morka

Niezgoda

A composite consisting of a set of hexagonal ceramic bars—the numerical study of the ballistic resistance. Key Eng Mater 2011; 471–472: 1142–1146.

23.

Miranda

Pajares

Meyers

MA.

Bioinspired composite segmented armour: numerical simulations. J Mater Res Technol 2019; 8: 1274–1287.

24.

Jitarașu

Numerical investigation on the impact of various construction designs of ceramic mosaic armour on ballistic resistance. UPB Sci Bull Ser D 2024; 86: 181–196.

25.

Grisaro

Edri

Rigby

SE.

TNT equivalency analysis of specific impulse distribution from close-in detonations. Int J Prot Struct 2021; 12: 315–330.

26.

Ullah

Ahmad

Jang

H-W

, et al. Review of analytical and empirical estimations for incident blast pressure. KSCE J Civ Eng 2017; 21: 2211–2225.

27.

Trelat

Sturtzer

MO.

Predicting explosion and b; ast effects: a multi-scale experimental approach. Int. J Saf Secur Eng 2019; 9: 356–370.

28.

Lam

NTK

Mendis

Ngo

Response spectrum solutions for blast loading. Electron J Struct Eng 2004; 4: 28–44.

29.

Larcher

Pressure-time functions for the description of air blast waves. Report Number: JRC46829, 2008. Ispra: Joint Research Centre.

30.

Teich

Gebbeken

The influence of the underpressure phase on the dynamic response of structures subjected to blast loads. Int J Prot Struct 2010; 1: 219–233.

31.

Rigby

SE.

Blast wave clearing effects on finite-sized targets subjected to explosive loads. PhD Thesis, University of Sheffield, Department of Civil & Structural Engineering, 2014.

32.

Rigby

Tyas

Bennett

, et al. A numerical investigation of blast loading and clearing on small targets. Int J Prot Struct 2014; 5: 253–274.

33.

Chung Kim Yuen

Butler

Bornstein

, et al. The influence of orientation of blast loading on quadrangular plates. Thin-Walled Struct 2018; 131: 827–837.

34.

Bonorchis

Nurick

GN.

The analysis and simulation of welded stiffener plates subjected to localised blast loading. Int J Impact Eng 2010; 37: 260–273.

35.

Yin

Zhi

Fan

, et al. Blast loads and variability on cylindrical shells under different charge orientations. Sci Rep 2023; 13: 6719.

36.

Karlos

Solomos

Larcher

Analysis of the blast wave decay coefficient using the Kingery–Bulmash data. Int J Prot Struct 2016; 7: 409–429.

37.

Kingery

Bulmash

and Laboratory USABR. Airblast parameters from TNT spherical air burst and hemispherical surface burst. US Army Armament and Development Center, Ballistic Research Laboratory, 1984, https://books.google.gr/books?id=lg6cHAAACAAJ

38.

Isaac

Alshammari

Pickering

, et al. Blast wave interaction with structures—an overview. Int J Prot Struct 2023; 14: 584–630.