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NUMERICAL SIMULATION OF CONCRETE WITH RUBBER AGGREGATES

Assist. Dr. Sergiu Andrei Baetu, Assist. Dr. Vasile Mircea Venghiac

First published: 2015https://doi.org/10.5593/sgem2015/b41/s17.045View metrics

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Publication details

Title
NUMERICAL SIMULATION OF CONCRETE WITH RUBBER AGGREGATES
Authors
Assist. Dr. Sergiu Andrei Baetu, Assist. Dr. Vasile Mircea Venghiac
Proceedings
SGEM International Multidisciplinary Scientific GeoConference EXPO Proceedings; 15th International Multidisciplinary Scientific GeoConference SGEM2015, ENERGY AND CLEAN TECHNOLOGIES
Publisher
Stef92 Technology
Year
2015
Pages
345-352
ISSN
1314-2704
ISBN
978-619-7105-38-4
Language
en
Publication type
Conference Paper
References28
  1. http://www.polymer-search.com/rubber.html

  2. Muhammad, B. (2012), Technology, Properties and Application of NRL Elastomers, Publisher InTech.

  3. Berselli, G., Vertechy, R., Pellicciari, M., Vassura, G. (2011), Rapid Prototyping Technology - Principles and Functional Requirements, Hyperelastic Modeling of Rubber- Like Photopolymers for Additive Manufacturing Processes, ISBN 978-953-307-970- 7, Publisher InTech.

  4. http://ansys.net/ansys/papers/nonlinear/conflong_hyperel.pdf

  5. Brodersen, B. (2004), Ogden type materials in non-linear continuum mechanics, Technische Universitat Braunschweig, Institut fur Angewandte Mechanik, Mat.- Nr. 2569716, Germany.

  6. Amin, A., Wiraguna, S., Okui Z. 2006, Hyperelasticity Model for Finite Element Analysis of Natural and High Damping Rubbers in Compression and Shear, Journal of engineering mechanics © ASCE, 132 (1), pp. 54 - 64.

  7. Mills, N. (2007), Polymer Foams Handbook, Elsevier, Oxford.

  8. Briody, C., Duignan, B., Jerrams, S., Tiernan, J. (2012), The Implementation of a Visco- hyperelastic Numerical Material Model for Simulating the Behaviour of Polymer Foam Materials, Journal of Computational Material Science, in press.

  9. Ali, A., Hosseini, M., Sahari, B.B. (2010), A Review of Constitutive Models for Rubber- Like Materials, American J. of Engineering and Applied Sciences 3 (1), pp. 232-239.

  10. Souza Neto, E.A., Peric, D., Owen, D.R.J. (2008), Computational Methods for Plasticity: Theory and Applications, John Wiley & Sons Ltd, ISBN 978-0-470-69452-7.

  11. Ogden, R.W. (2001), Nonlinear elasticity, Cambridge University Press, Cambridge.

  12. Yeoh O.H. (1993), Some forms of the strain energy function for rubber, Rubber Chem. Technol, 66, pp. 754–771.

  13. Ihueze, C.C., Mgbemena, C.O. (2014), Modeling Hyperelastic Behavior of Natural Rubber/ Organomodified Kaolin Composites Oleochemically Derived from Tea Seed Oils for Automobile Tire Side Walls Application, Journal of Scientific Research & Reports, 3(19).

  14. ANSYS 14 Structural Analysis Guide, 2013. International Multidisciplinary Scientific GeoConfenferences SGEM 2015 www.sgem.org

  15. http://www.polymer-search.com/rubber.html

  16. Muhammad, B. (2012), Technology, Properties and Application of NRL Elastomers, Publisher InTech.

  17. Berselli, G., Vertechy, R., Pellicciari, M., Vassura, G. (2011), Rapid Prototyping Technology - Principles and Functional Requirements, Hyperelastic Modeling of Rubber- Like Photopolymers for Additive Manufacturing Processes, ISBN 978-953-307-970- 7, Publisher InTech.

  18. http://ansys.net/ansys/papers/nonlinear/conflong_hyperel.pdf

  19. Brodersen, B. (2004), Ogden type materials in non-linear continuum mechanics, Technische Universitat Braunschweig, Institut fur Angewandte Mechanik, Mat.- Nr. 2569716, Germany.

  20. Amin, A., Wiraguna, S., Okui Z. 2006, Hyperelasticity Model for Finite Element Analysis of Natural and High Damping Rubbers in Compression and Shear, Journal of engineering mechanics © ASCE, 132 (1), pp. 54 - 64.

  21. Mills, N. (2007), Polymer Foams Handbook, Elsevier, Oxford.

  22. Briody, C., Duignan, B., Jerrams, S., Tiernan, J. (2012), The Implementation of a Visco- hyperelastic Numerical Material Model for Simulating the Behaviour of Polymer Foam Materials, Journal of Computational Material Science, in press.

  23. Ali, A., Hosseini, M., Sahari, B.B. (2010), A Review of Constitutive Models for Rubber- Like Materials, American J. of Engineering and Applied Sciences 3 (1), pp. 232-239.

  24. Souza Neto, E.A., Peric, D., Owen, D.R.J. (2008), Computational Methods for Plasticity: Theory and Applications, John Wiley & Sons Ltd, ISBN 978-0-470-69452-7.

  25. Ogden, R.W. (2001), Nonlinear elasticity, Cambridge University Press, Cambridge.

  26. Yeoh O.H. (1993), Some forms of the strain energy function for rubber, Rubber Chem. Technol, 66, pp. 754–771.

  27. Ihueze, C.C., Mgbemena, C.O. (2014), Modeling Hyperelastic Behavior of Natural Rubber/ Organomodified Kaolin Composites Oleochemically Derived from Tea Seed Oils for Automobile Tire Side Walls Application, Journal of Scientific Research & Reports, 3(19).

  28. ANSYS 14 Structural Analysis Guide, 2013. International Multidisciplinary Scientific GeoConfenferences SGEM 2015 www.sgem.org

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