High velocity impact behaviour of additively manufactured cellular core backed Kevlar

T. Fisher; J. H. S. Almeida Jr; Brian G. Falzon; Z. Kazancı

doi:10.5281/zenodo.15317038

High velocity impact behaviour of additively manufactured cellular core backed Kevlar

T. Fisher, J. H. S. Almeida Jr, Brian G. Falzon, Z. Kazancı

Research output: Chapter in Book / Conference Paper › Conference Paper › peer-review

Abstract

This work investigates the effect of several parameters of a cellular core, protected by a Kevlar plate, under ballistic impact. Three core geometries, two sizes, and four relative densities are explored and their effects quantified. Overall, auxetic geometries (re-entrant and double arrowhead) result in a significant reduction in transmitted force at the cost of increasing the maximum displacement compared to a non-auxetic hexagonal structure. The cell size has no effect on the maximum displacement for any of the geometries or the transmitted force for the auxetics. A smaller cell size does, nonetheless, increase the peak transmitted force for the hexagonal structure. Increasing the relative density of the structures increases the transmitted force whilst decreasing the maximum displacement across all unit cells considered. This work provides a basis for the parameter selection when using cellular structures in an impact mitigation setting.

Original language	English
Title of host publication	Proceedings of the 2023 International Conference on Composite Materials (ICCM 23), July 30 - August 4, 2023, Belfast, Northern Island
Place of Publication	U.K.
Publisher	Queen's University Belfast
Number of pages	7
DOIs	https://doi.org/10.5281/zenodo.15317038
Publication status	Published - 2023
Externally published	Yes
Event	International Conference on Composite Materials - Queen's University, Belfast, Ireland Duration: 30 Jul 2023 → 4 Aug 2023 Conference number: 23rd

Conference

Conference	International Conference on Composite Materials
Abbreviated title	ICCM
Country/Territory	Ireland
City	Belfast
Period	30/07/23 → 4/08/23

Keywords

Ballistic impact Cellular structures Finite element analysis Ballistics Cellular automata Finite element method Auxetics Cell-size Cellular structure Cellulars Finite element analyse Hexagonal structures High-velocity impact Maximum displacement Relative density Geometry

Access to Document

10.5281/zenodo.15317038

Cite this

@inproceedings{eef50410274f4179bdd570a18c31c77f,

title = "High velocity impact behaviour of additively manufactured cellular core backed Kevlar",

abstract = "This work investigates the effect of several parameters of a cellular core, protected by a Kevlar plate, under ballistic impact. Three core geometries, two sizes, and four relative densities are explored and their effects quantified. Overall, auxetic geometries (re-entrant and double arrowhead) result in a significant reduction in transmitted force at the cost of increasing the maximum displacement compared to a non-auxetic hexagonal structure. The cell size has no effect on the maximum displacement for any of the geometries or the transmitted force for the auxetics. A smaller cell size does, nonetheless, increase the peak transmitted force for the hexagonal structure. Increasing the relative density of the structures increases the transmitted force whilst decreasing the maximum displacement across all unit cells considered. This work provides a basis for the parameter selection when using cellular structures in an impact mitigation setting.",

keywords = "Ballistic impact Cellular structures Finite element analysis Ballistics Cellular automata Finite element method Auxetics Cell-size Cellular structure Cellulars Finite element analyse Hexagonal structures High-velocity impact Maximum displacement Relative density Geometry",

author = "T. Fisher and {Almeida Jr}, {J. H. S.} and Falzon, {Brian G.} and Z. Kazancı",

year = "2023",

doi = "10.5281/zenodo.15317038",

language = "English",

booktitle = "Proceedings of the 2023 International Conference on Composite Materials (ICCM 23), July 30 - August 4, 2023, Belfast, Northern Island",

publisher = "Queen's University Belfast",

note = "International Conference on Composite Materials, ICCM ; Conference date: 30-07-2023 Through 04-08-2023",

}

Fisher, T, Almeida Jr, JHS, Falzon, BG & Kazancı, Z 2023, High velocity impact behaviour of additively manufactured cellular core backed Kevlar. in Proceedings of the 2023 International Conference on Composite Materials (ICCM 23), July 30 - August 4, 2023, Belfast, Northern Island. Queen's University Belfast, U.K., International Conference on Composite Materials, Belfast, Ireland, 30/07/23. https://doi.org/10.5281/zenodo.15317038

High velocity impact behaviour of additively manufactured cellular core backed Kevlar. / Fisher, T.; Almeida Jr, J. H. S.; Falzon, Brian G. et al.
Proceedings of the 2023 International Conference on Composite Materials (ICCM 23), July 30 - August 4, 2023, Belfast, Northern Island. U.K.: Queen's University Belfast, 2023.

Research output: Chapter in Book / Conference Paper › Conference Paper › peer-review

TY - GEN

T1 - High velocity impact behaviour of additively manufactured cellular core backed Kevlar

AU - Fisher, T.

AU - Almeida Jr, J. H. S.

AU - Falzon, Brian G.

AU - Kazancı, Z.

N1 - Conference code: 23rd

PY - 2023

Y1 - 2023

N2 - This work investigates the effect of several parameters of a cellular core, protected by a Kevlar plate, under ballistic impact. Three core geometries, two sizes, and four relative densities are explored and their effects quantified. Overall, auxetic geometries (re-entrant and double arrowhead) result in a significant reduction in transmitted force at the cost of increasing the maximum displacement compared to a non-auxetic hexagonal structure. The cell size has no effect on the maximum displacement for any of the geometries or the transmitted force for the auxetics. A smaller cell size does, nonetheless, increase the peak transmitted force for the hexagonal structure. Increasing the relative density of the structures increases the transmitted force whilst decreasing the maximum displacement across all unit cells considered. This work provides a basis for the parameter selection when using cellular structures in an impact mitigation setting.

AB - This work investigates the effect of several parameters of a cellular core, protected by a Kevlar plate, under ballistic impact. Three core geometries, two sizes, and four relative densities are explored and their effects quantified. Overall, auxetic geometries (re-entrant and double arrowhead) result in a significant reduction in transmitted force at the cost of increasing the maximum displacement compared to a non-auxetic hexagonal structure. The cell size has no effect on the maximum displacement for any of the geometries or the transmitted force for the auxetics. A smaller cell size does, nonetheless, increase the peak transmitted force for the hexagonal structure. Increasing the relative density of the structures increases the transmitted force whilst decreasing the maximum displacement across all unit cells considered. This work provides a basis for the parameter selection when using cellular structures in an impact mitigation setting.

KW - Ballistic impact Cellular structures Finite element analysis Ballistics Cellular automata Finite element method Auxetics Cell-size Cellular structure Cellulars Finite element analyse Hexagonal structures High-velocity impact Maximum displacement Relative

U2 - 10.5281/zenodo.15317038

DO - 10.5281/zenodo.15317038

M3 - Conference Paper

BT - Proceedings of the 2023 International Conference on Composite Materials (ICCM 23), July 30 - August 4, 2023, Belfast, Northern Island

PB - Queen's University Belfast

CY - U.K.

T2 - International Conference on Composite Materials

Y2 - 30 July 2023 through 4 August 2023

ER -

High velocity impact behaviour of additively manufactured cellular core backed Kevlar

Abstract

Conference

Keywords

Access to Document

Fingerprint

Cite this