Experimental and Numerical Study on Perforated Plate Mitigation Capacity to Near-Field Blasts-Reference-Cited by-同舟云学术

Experimental and Numerical Study on Perforated Plate Mitigation Capacity to Near-Field Blasts

Published:2023-06-08 Issue:12 Volume:16 Page:4255
ISSN:1996-1944
Container-title:Materials
language:en
Short-container-title:Materials

Author:

Puică Constantin-Cristinel¹,Trană Eugen²^ORCID,Pupăză Cristina³,Turtoi Petrică⁴,Rotariu Adrian-Nicolae²,Pană Iuliana-Florina²

Affiliation:

1. Military Equipment and Technologies Research Agency, 16 Aeroportului, 077025 Clinceni, Romania

2. Military Technical Academy ‘Ferdinand I’, 39-49 George Coșbuc Avenue, 050141 Bucharest, Romania

3. Doctoral School of Industrial Engineering and Robotics, University Politehnica of Bucharest, 313 Splaiul Independenței, 060042 Bucharest, Romania

4. Department of Machine Elements and Tribology, University Politehnica of Bucharest, 313 Splaiul Independenței, 060042 Bucharest, Romania

Abstract

Based on the analysis of existing collective shockwave protection methods worldwide, this paper addresses the mitigation of shock waves by means of passive methods, namely the use of perforated plates. Employing specialized software for numerical analysis, such as ANSYS-AUTODYN 2022R1®, the interaction of shock waves with a protection structure has been studied. By using this cost-free approach, several configurations with different opening ratios were investigated, pointing out the peculiarities of the real phenomenon. The FEM-based numerical model was calibrated by employing live explosive tests. The experimental assessments were performed for two configurations, with and without a perforated plate. The numerical results were expressed in terms of force acting on an armor plate placed behind a perforated plate at a relevant distance for ballistic protection in engineering applications. By investigating the force/impulse acting on a witness plate instead of the pressure measured at a single point, a realistic scenario can be considered. For the total impulse attenuation factor, the numerical results suggest a power law dependence, with the opening ratio as a variable.

Publisher

MDPI AG

Subject

General Materials Science

Link

https://www.mdpi.com/1996-1944/16/12/4255/pdf

Reference33 articles.

1. Absil, L., and Bryntse, A. (2006). Blast Mitigation by Water, FOI-R-2049-SE Report; FOI.

2. Experimental investigation of the interaction between weak shock waves and granular layers;Britan;Exp. Fluids,1997

3. Uninstrumented measurement method for granular porous media blast mitigation assessment;Rotariu;Exp. Tech.,2016

4. Guéders, C., Van Roey, J., Gallant, J., and Coghe, F. (2011, January 23–24). Simulation of Shock Wave Mitigation in Granular Materials by Pressure and Impulse Characterization. Proceedings of the 8th European LS-DYNA Users Conference, Strasbourg, France. Session 15, Paper 3.

5. Shock-Wave Attenuation and Energy-Dissipation Potential of Granular Materials;Grujicic;J. Mater. Eng. Perform.,2012