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A comparative study on the damage initiation mechanism of elastomeric composites

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Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
Purpose: Modelling - Finite Element Analysis (FEA) of the damage initiation mechanisms in thin rubber sheet composites were carried out under static solicitation at room temperature. Natural rubber vulcanised and reinforced by carbon, NR is used in this study. Design/methodology/approach: Experimental results were compared with that of the Finite Element Analysis (FEA). Damage mechanism has been described with a threshold criterion to identify the tearing resistance, characteristic energy for tearing (T) and damage in the specimens was evaluated just at the beginning of the tearing by assuming large strain. A typical type of specimen geometry of thin sheet rubber composite materials was considered under static tensile tests conducted on the smooth and notched specimens with variable depths. In this way, the effects of the plane stress on the damage mechanism are characterized depending on the rubber materials. Findings: In this stage of this research, a finite element analysis (FEA) has been applied under the same conditions of this part in order to obtain the agreement between experimental and FEA results. The numerical modelling is a representation of a previous experimental study. The specimen is stretched more than once its initial size, so that large strains occur. A hyper elastic Mooney-Rivlin law and a Griffith criterion are chosen. The finite elements analysis was performed with ABAQUS code (V.6.4.4). The tearing energy is evaluated with contour integrals. The Griffith criterion states that a notch with an initial length will elongate of a differential length for a given strain state only if the variation of elastic energy is higher than the variation of the surface energy related to the newly created surface. Practical implications: A tearing criterion was suggested in the case of simple tension conditions by assuming large strain. In the next step of this study, a finite element analysis (FEA) will be applied under the same conditions of this part in order to obtain the agreement between experimental and FEA results. Originality/value: This study proposes a threshold criterion for the damage just at the beginning of the tearing for thin sheet rubber composites and gives a detail discussion for explaining the damage mechanisms. Comparison of FEA results with those of experimental studies gives many facilities for the sake of simplicity in industrial application.
Rocznik
Strony
112--119
Opis fizyczny
Bibliogr. 24 poz., tab., rys., wykr.
Twórcy
autor
autor
  • School of Mechanical and Manufacturing Engineering, Supmeca/LISMMA-Paris, EA 2336, St-Ouen, France, tony.dasylva@supmeca.fr
Bibliografia
  • [1] A.N. Gent, M.R. Kashani, Why do cracks turn sideways, Rubber Chemistry and Technology 76 (2001) 122-131.
  • [2] H.W. Greensmith, The change in Stored Energy on Making a Small Cut in a Test Piece held in Simple Extension, Journal Polymer Science 7 (1963) 993-1002.
  • [3] G.J. Lake, Fatigue and fracture of elastomers, Rubber Chemical Technology 66 (1995) 435-460.
  • [4] P.B. Lindley, Energy for crack growth in model rubber components, Journal Strain Analysis 7 (1972) 132-140.
  • [5] R.S. Rivlin, A.G. Thomas, Rupture of Rubber. Part 1: Characteristic energy for tearing, Journal of Polymers Sciences 10 (1953) 291-318.
  • [6] E. Bayraktar, F. Montembault, C. Bathias, Damage Mechanism of Elastomeric Matrix Composites, Proceedings of the Conference “Experimental Mechanics”, 2005, Portland, Oregon, USA.
  • [7] E. Bayraktar, K. Bessri, C. Bathias, Deformation behaviour of elastomeric matrix composites under static loading conditions, Journal of Engineering Fracture Mechanics 75/1 (2007) (On line).
  • [8] T. Da Silva Botelho, N. Isac, E. Bayraktar, Modelling of damage initiation mechanism in rubber sheet composites under the static loading, Journal of Achievements in Materials and Manufacturing Engineering 22/2 (2007) 55-58.
  • [9] J.R. Cho, J.I. Song, K.T. Noh, D.H. Jeon, Nonlinear finite element analysis of swaging process for automobile power steering hose, Journal of Materials Processing Technology 170/1-2 (2005) 50-57.
  • [10] H. Ghaemi, K. Behdinan, A. Spence, On the development of compressible pseudo-strain energy density function for elastomers: Part 1. Theory and experiment, Journal of Materials Processing Technology 178/1-3 (2006) 307-316.
  • [11] H. Ghaemi, K. Behdinan, A. Spence, On the development of compressible pseudo-strain energy density function for elastomers: Part 2. Application to FEM, Journal of Materials Processing Technology 178/1-3 (2006) 317-327.
  • [12] M.A. Helleboid, O. Thao, Modeling of tearing of the rubber specimens under static solicitations, BSc, SUPMECA-Paris/LISMMA, Paris, 2006.
  • [13] S. Jerrams, K. Sanders, K.B. Goo, Realistic modelling of earthquake-isolation bearings, Journal of Materials Processing Technology 118/1-3 (2001) 158-164.
  • [14] R. Luong, Study of the tearing of thin rubber sheets and double cantilever beam (DCB) rubber specimens under static solicitations, MSc, SUPMECA-Paris/LISMMA, Paris, 2005.
  • [15] R. Luong, N. Isac, E. Bayraktar, Damage initiation mechanism in rubber sheet composites during the static loading, Archives of Materials Science and Engineering 28/1 (2007) 19-26.
  • [16] R. Luong, N. Isac, E. Bayraktar, Failure mechanisms in thin rubber sheet composites under static solicitation, Journal of Achievements in Materials and Manufacturing Engineering 21/1 (2007) 43-46.
  • [17] M.H. Makled, T. Matsui, H. Tsuda, H. Mabuchi, M.K. El-Mansy, K. Morii, Magnetic and dynamic mechanical properties of barium ferrite-natural rubber composites, Journal of Materials Processing Technology 160/2 (2005) 229-233.
  • [18] R.M.V. Pidaparti, Finite element analysis of interface cracks in rubber materials, Engineering Fracture Mechanics 47 (1994) 309-316.
  • [19] R.M.V. Pidaparti, T.Y. Yang, W. Soedel, A plane stress FEA for the prediction of rubber fracture, International Journal of Fracture 39 (1989) 255-268.
  • [20] P.V.M. Rao S.G. Dhande, A flexible surface tooling for sheet-forming processes: conceptual studies and numerical simulation, Journal of Materials Processing Technology 124/1-2 (2002) 133-143.
  • [21] G. Wróbel, S. Pawlak, Ultrasonic evaluation of the fibre content in glass/epoxy composites, Journal of Achievements in Materials and Manufacturing Engineering 18 (2006) 187-190.
  • [22] J.H. Wu, J.L. Huang, N.S. Chen, C. Wei, Y. Chen, Preparation of modified ultra-fine mineral powder and interaction between mineral filler and silicone rubber, Journal of Materials Processing Technology 137/1-3 (2003) 40-44.
  • [23] J. Yan, J.S. Strenkowski, A finite element analysis of orthogonal rubber cutting, Journal of Materials Processing Technology 174/1-3 (2006) 102-108.
  • [24] R. Zulkifli, L.K. Fatt, C.H. Azhari, J. Sahari, Interlaminar fracture properties of fibre reinforced natural rubber/polypropylene composites, Journal of Materials Processing Technology 128/1-3 (2002) 33-37.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-PWA9-0042-0015
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