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Purpose: Mechanical behaviour and damage mechanisms in thin rubber sheet composites investigated under static solicitation at room temperature. Two types of rubber are used in this study; Natural rubber, NR vulcanised and reinforced by carbon black and Synthetic rubber (Styrene-butadiene-rubber, SBR). Design/methodology/approach: A comprehensive study has been carried out in order to identify a threshold criterion for the damage mechanism to explain a tearing criterion for the concept of tearing energy of the elastomers and also to give a detail for the damage mechanism depending on the loading conditions. A typical type of specimen geometry of thin rubber composite materials was studied 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: Damage mechanisms during tensile test have been described for both of rubber types and the criteria which characterize the tearing resistance, characteristic energy for tearing (T) was explained. Damage in the specimens were evaluated just at the beginning of the tearing by means of the observations in the scanning electron microscopy (SEM). 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 by SEM results. This type of study gives many facilities for the sake of simplicity in industrial application.
Wydawca
Rocznik
Tom
Strony
43--46
Opis fizyczny
Bibliogr. 15 poz., fot., rys., tab.
Twórcy
autor
autor
autor
- Supmeca/LISMMA-Paris, School of Mechanical and Manufacturing Engineering, EA 2336, St-Quen, France, bayraktar@supmeca.fr
Bibliografia
- [1] R.S. Rivlin, A.G.Thomas, Rupture of Rubber. Part 1: Characteristic energy for tearing. Journal of Polymers Sciences. 10 (1953) 291-318.
- [2] G.J. Lake, Fatigue and fracture of elastomers. Rubber Chemical. Technology. 66 (1995), 435-460.
- [3] 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.
- [4] R. Luong, MSc thesis, SUPMECA-Paris/LISMMA, EA-2336, St-Quen, Paris/FRANCE, 2004.
- [5] P.B. Lindley, Energy for crack growth in model rubber components. Journal Strain Anal. 7 (1972), 132-140.
- [6] R. Zulkifli, L.K. Fatt, C.H. Azhari, J. Sahari, Interlaminar fracture properties of fibre reinforced natural rubber/polypropylene composites, J. Mat. Proc. Tech., 128, 1-3 (2002), 33-37.
- [7] R.M.V. Pidaparti, T.Y. Yang, W.A. Soedel, A plane stress FEA for the prediction of rubber fracture, International Journal of Fracture 39 (1989), 255-268.
- [8] P.V.M. Rao G. Sanjay, A. Dhande, A flexible surface tooling for sheet-forming processes: conceptual studies and numerical simulation, J. Mat. Proc. Tech., 124, 1-2, 10, (2002), 133-143.
- [9] E. Bayraktar, F. Montembault, С. Bathias, Damage Mechanism of Elastomeric Matrix Composites, Proceedings of experimental mechanics 2005, 7-9 Juin 2005; Paper n°353, session 057, SEM-2005 Portland Oregon USA.
- [10] O.H. Yeoh, 2001, Relation between crack surface displacements and strain energy release rate in thin rubber sheets, Mechanics of Materials 34 (2002), 459-474.
- [11] Jihuai Wu, Jinling Huang, Naisheng Chen, Congrong Wei Yike Chen, Preparation of modified ultra-fine mineral powder and interaction between mineral filler and silicone rubber, J. Mat. Proc. Tech., 137, 1-3, (2003), 40-44.
- [12] E. Bayraktar, F. Montembault, С Bathias, Multiscale Observation of Polymer Materials in order to explain Mechanical Behaviour and Damage Mechanism by x-ray Computed Tomography, J. Mat. Proc. Tech., Vol. 20 (1), pp. 27-31, 2004.
- [13] Hamid Ghaemi, K. Behdinan, A. Spence, On the development of compressible pseudo-strain energy density function for elastomers: Part I. Theory and experiment, J. Mat. Proc. Tech., 178, 1-3 (2006), 307-316.
- [14] 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. J. Mat. Proc. Tech., 160, 2, 20 (2005), 229-233.
- [15] E. Bayraktar, K. Bessri, C. Bathias, Deformation behaviour of elastomeric matrix composites under static loading conditions, Euromech-473, Porto, Portugal, 27-29 October 2005.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-article-BOS3-0016-0063