Sage Journals: Discover world-class research

Abstract

In this paper ballistic behavior of natural rubber sheets is analyzed against the projectile impact through experimentation as well as numerical simulations. The size of natural rubber sheets was considered as 150 mm × 150 mm with varying thickness 5, 6, 8, and 10 mm. The rubber sheets were impacted against the 10 mm diameter hemispherical projectile having weight of 17 gm and length of 26 mm respectively. The ballistic tests were carried out with in the velocity range of 36–73 m/s. For the ballistic impact experiment on the natural rubber sheet, a pneumatic gas gun was used whereas numerical simulations were carried out through explicit ANSYS/ LS-DYNA. To simulate the damage behavior of the rubber material against such a complex loading condition, the Mooney-Rivlin damage model was considered. To obtain the material parameter value of the Mooney-Rivlin model for natural rubber sheets, uniaxial tensile test was performed. Moreover, the first and second invariant-based different strain energy density functions were used to define the hyperelastic behavior of this rubber sheet. The analytical results were compared with FEM hyperelastic model and prepared a single set of material parameters for the damage model which deal with the ballistic response against the projectile. The numerical model was validated against the experimental results in terms of residual velocity, energy absorption, ballistic limit, and damage pattern and the results were found to be in good correlation.

Keywords

ballistic impact natural rubber sheet energy absorption FEA analysis damage model

Get full access to this article

View all access options for this article.

References

Gao

Kedir

Hernandez

, et al. Dynamic failure of composite strips under reverse ballistic impact. Int J Mech Sci 2022; 234: 107700.

Zarei

Sadighi

Minak

Ballistic analysis of fiber metal laminates impacted by flat and conical impactors. Compos Struct 2017; 161: 65–72.

Luan

Sun

Ballistic impact damages of 3-D angle-interlock woven composites based on high strain rate constitutive equation of fiber tows. Int J Impact Eng 2013; 57: 145–158.

Singh

Tiwari

Performance of fibre composite laminates against ballistic impact: a review. J Strain Anal Eng Des 2025; 60: 543–585.

Bikakis

GSE

Dimou

Sideridis

. Ballistic impact response of fiber–metal laminates and monolithic metal plates consisting of different aluminum alloys. Aerosp Sci Technol 2017; 69: 201–208.

Anderson

Bodner

SR.

Ballistic impact: the status of analytical and numerical modeling. Int J Impact Eng 1988; 7: 9–35.

Andraskar

Tiwari

Goel

MD.

Impact response of ceramic structures - a review. Ceram Int 2022; 48: 27262–27279.

Gharde

Singh

Tiwari

Effect of ply stacking sequence and projectile’s nose shape on ballistic response of unidirectional CFRP composite laminates. Mech Solids 2025; 60: 1224–1237.

Alemán

Chadwick

, et al. Definitions of terms relating to the structure and processing of sols, gels, networks, and inorganic-organic hybrid materials (IUPAC recommendations 2007). Pure Appl Chem 2007; 79: 1801–1829.

10.

Muhr

AH.

Modeling the stress-strain behavior of rubber. Rubber Chem Technol 2005; 78: 391–425.

11.

Singh

Tiwari

Numerical study on ballistic impact behaviour of natural rubber. Procedia Struct Integr 2025; 71: 164–171.

12.

Bergström

Boyce

MC.

Mechanical behavior of particle filled elastomers. Rubber Chem Technol 1999; 72: 633–656.

13.

Marckmann

Verron

Comparison of hyperelastic models for rubber-like materials. Rubber Chem Technol 2006; 79: 835–858.

14.

Khajehsaeid

Arghavani

Naghdabadi

A hyperelastic constitutive model for rubber-like materials. European Journal of Mechanics - A/Solids 2013; 38: 144–151.

15.

Singh

Kumar

Yadav

Constitutive modeling of rubber-like materials: an alternative material model. Indian Chem Eng 2023; 65: 221–232.

16.

Destrade

Saccomandi

Sgura

Methodical fitting for mathematical models of rubber-like materials. Proc. R. Soc. A 2017; 473: 20160811.

17.

Sasso

Palmieri

Chiappini

, et al. Characterization of hyperelastic rubber-like materials by biaxial and uniaxial stretching tests based on optical methods. Polym Test 2008; 27: 995–1004.

18.

Long

Shanks

RA.

PP-elastomer-filler hybrids. I. Processing, microstructure, and mechanical properties. J Appl Polym Sci 1996; 61: 1877–1885.

19.

Fröhlich

Niedermeier

Luginsland

H-D.

The effect of filler–filler and filler–elastomer interaction on rubber reinforcement. Compos Part A: Appl Sci Manuf 2005; 36: 449–460.

20.

Ahmad

WYW

Salleh

, et al. Effect of fabric stitching on ballistic impact resistance of natural rubber coated fabric systems. Mater Des 2008; 29: 1353–1358.

21.

Khodadadi

Liaghat

Ahmadi

, et al. Impact response of Kevlar/rubber composite. Compos Sci Technol 2019; 184: 107880.

22.

Asemani

Liaghat

Ahmadi

, et al. The experimental and numerical analysis of the ballistic performance of elastomer matrix Kevlar composites. Polym Test 2021; 102: 107311.

23.

Singh

Tiwari

An experimental and numerical study for ballistic impact behavior of natural fiber-based laminated sheet against the hemispherical projectile. Fibers Polym 2025; 26: 4087–4114.

24.

Mahesh

Joladarashi

Kulkarni

, et al. Comparative study on ballistic impact response of neat fabric, compliant, hybrid compliant and stiff composite. Thin-Walled Struct 2021; 165: 107986.

25.

Steinmann

Hossain

Possart

Hyperelastic models for rubber-like materials: consistent tangent operators and suitability for Treloar’s data. Arch Appl Mech 2012; 82: 1183–1217.

26.

Diani

Brieu

Vacherand

J-M

, et al. Directional model for isotropic and anisotropic hyperelastic rubber-like materials. Mech Mater 2004; 36: 313–321.

27.

Rajole

Ravishankar

Kulkarni

SM.

Performance study of jute-epoxy composites/sandwiches under normal ballistic impact. Def Technol 2020; 16: 947–955.

28.

Yang

Zhang

, et al. Experimental and numerical investigations into the ballistic performance of ultra-high molecular weight polyethylene fiber-reinforced laminates. Compos Struct 2022; 290: 115499.

29.

Sangamesh

Ravishankar

Kulkarni . Ballistic impact study on Jute-Epoxy and natural rubber sandwich Composites. Mat Today Proc 5 (2018) 6916–6923.

30.

Zhu

Yang

, et al. A modified model to predict the ballistic limit of a cubic fragment penetrating Kevlar / titanium fiber metal laminate. Int J Impact Eng 2022; 168: 104292.

31.

Khodadadi

Liaghat

Ahmadi

, et al. Numerical and experimental study of impact on hyperelastic rubber panels. Iran Polym J 2019; 28: 113–122.

32.

Mahesh

Development and ballistic impact study on environment friendly sustainable jute reinforced carbon black/lignin-based elastomeric flexible composites. Proc Inst Mech Eng E J Process Mech Eng 2023; 09544 089231207411. DOI: 10.1177/09544089231207411

33.

Zhao

Modeling and verification of a new hyperelastic model for Rubber-Like materials. Math Probl Eng 2019; 2019(1): 10.

34.

Domun

Kaboglu

Paton

, et al. Ballistic impact behaviour of glass fibre reinforced polymer composite with 1D/2D nanomodified epoxy matrices. Compos B Eng 2019; 167: 497–506.

Ballistic response of natural rubber sheet against the hemispherical projectile: An experimental and numerical approach

Abstract

Keywords

Get full access to this article

References