Analysing Mechanical Behaviors of Carbon Fiber Reinforced Silicone Matrix Composite Materials after Static Folding

İsmail Sinan Atlı; Atilla Evcin

Research Article

Analysing Mechanical Behaviors of Carbon Fiber Reinforced Silicone Matrix Composite Materials after Static Folding

Year 2020, Volume: 23 Issue: 2, 351 - 359, 01.06.2020

İsmail Sinan Atlı Atilla Evcin

Abstract

Subject of this paper is to provide information about
mechanical behavior of a novel material to the literature: carbon fiber
reinforced silicone matrix composite (CFRS-C). Under a mechanical load,
silicone matrix allows large elastic deformations while carbon fiber
reinforcement can bear high tensile stresses. This rare behavior of CFRS-C allows
us to design foldable materials without being in a bind for mechanical hinges
which bring additional weights. Foldable materials are used in space structures
to gain advantage of smaller volumes. In this study, CFRS-C were manufactured
with two different silicone type can be found in market and one type of plain
weave unidirectional carbon fiber fabric. Specimens were prepared and kept folded
90º statically in various periods of time. They were subjected to tensile
testing afterwards, to investigate effect of number of layers, silicone type
and duration of folding to mechanical behavior.

Keywords

Foldable materials, composite, silicone, elastic

References

Referans 1. Dano M.L., Gendron G., Picard A., Mechanical Behavior of a Triaxial Woven Fabric Composite, Mechanics of Composite Materials and Structures, 7:207-224, (2000).
Referans 2. Benarcyk B.A., Arnold S.M., ‘’Micromechanics-Based Modeling of Woven Polymer Matrix Composites’’, AIAA Journal, 41(9):1788-1796, (2003).
Referans 3. Le Page, B.H., Guild, F.J., Ogin, S.L. and Smith, P.A., ‘’Finite Element Simulation of Woven Fabric Composites’’, Composites: Part A, 35:861 - 872, (2004).
Referans 4. Hackett, R.M., ‘’Finite Elasticity’’, Hyperelasticity Primer, Springer International Publishing, USA, (2016)
Referans 5. Manuel J. Garcia R., Oscar E. Ruiz S., Carlos Lopez, "Hyperelastic Material Modeling", Technical Report, Laboratorio CAD/CAM/CAE, Departamento de Ingenieria Mecanica, Universidad EAFIT, Medellin, (2005).
Referans 6. T. W. Murphey, T. Meink, and M. M. Mikulas, ‘’Some micromechanics considerations of the folding of rigidizable composite materials’’ In 42nd AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference, AIAA:2001-1418, (2001).
Referans 7. W. H. Francis, M.S. Lake, and J. Steven Mayes, ‘’A review of classical _ber microbuckling analytical solutions for use with elastic memory composites’’, In 47th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference, Newport, RI ,AIAA-2006:1764, (2006).
Referans 8. Lopez Jimenez, F., ‘’Mechanics of thin carbon fiber composites with a silicone matrix’’, Doctoral dissertation, California Institute of Technology, (2011).
Referans 9. Baier, H., L. Datashvili, and J. Hoffmann. "Mechanically reconfigurable and massively shape morphing space structures." Proceedings of the 11th European Spacecraft Structures, Materials and Mechanical Testing Conference, (2009).
Referans 10. Murphey, T. W., ‘’Large Strain Composite Materials in Deployable Space Structures’’ In 17th International Conference on Composite Materials(Vol. 28). Edinburgh, UK: The British Composites Soc., (2009)
Referans 11. Campbell, D., Lake, M.S. and Mallick, K., "A study of the bending mechanics of elastic memory composites." In AIAA. 45th Structures, Structural Dynamics, and Materials Conference. California: Palm Springs: 1323-1331, (2004).
Referans 12. Datashvili, L., Baier, H., Wehrle, E., Kuhn, T., & Hoffmann, J.’’ Large shell-membrane space reflectors’’ In Proceedings of AIAA Structures, Dynamics, and Materials Conference, Honolulu, Hawaii, (2010).
Referans 13. ‘’Tembo Deployable Structures’’: https://www.ctd-materials.com/engineered-materials/tembo/ (accessed July 2018).
Referans 14. Vocke III, R.D., Kothera, C.S., Woods, B.K., Bubert, E.A. and Wereley, N.M.,’’One dimensional morphing structures for advanced aircraft’’ In Recent Advances in Aircraft Technology. IntechOpen, (2012).
Referans 15. Guynn, E.G., Bradley, W.L. and Ochoa, O.O., ‘’A parametric study of variables that affect fiber microbuckling initiation in composite laminates: Part 2—Experiments’’ Journal of Composite Materials, 26(11):1617-1643, (1992).
Referans 16. Drapier, S., Gardin, C., Grandidier, J.C. and Potier-Ferry, M., ‘’Structure effect and microbuckling’’ Composites Science and Technology, 56(7):861-867, (1996).
Referans 17. Drapier, S., Grandidier, J.C. and Potier-Ferry, M., ‘’A structural approach of plastic microbuckling in long fibre composites: comparison with theoretical and experimental results’’ International Journal of Solids and Structures, 38(22-23): 3877-3904, (2001).
Referans 18. Francis, W., Lake, M. and Mayes, J.S., ‘’A review of classical fiber microbuckling analytical solutions for use with elastic memory composites’’ In 47th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference 14th AIAA/ASME/AHS Adaptive Structures Conference 7th:1764 , (2006).
Referans 19. Marissen, R., and H. R. Brouwer. "The significance of fibre microbuckling for the flexural strength of a composite" Composites Science and Technology 59:3 (1999): 327-330, (1999).
Referans 20. Composites World. ‘’Advances in sizings and surface treatments for carbon fibers.’’. compositeworld.com: https://www.compositesworld.com/articles/advances-in-sizings-and-surface-treatments-for-carbon-fibers. (accessed May 2018).
Referans 21. Wu, Zhihong, Charles U. Pittman Jr, and Steven D. Gardner. "Nitric acid oxidation of carbon fibers and the effects of subsequent treatment in refluxing aqueous NaOH." Carbon33, 5: 597-605, (1995).
Referans 22. Mejia-Ariza, J., Guidanean, K., Murphey, T. and Biskner, A., "Mechanical characterization of L'Garde elastomeric resin composite materials." In 51st AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference 18th AIAA/ASME/AHS Adaptive Structures Conference 12th: 2701, (2010).
Referans 23. Jiménez, F.L. and Pellegrino, S., "Folding of fiber composites with a hyperelastic matrix." International Journal of Solids and Structures, 49(3-4):395-407, (2012).
Referans 24. Maqueda I, Pellegrino S, Mejia-Ariza J. "Characterization of a high strain composite material." In 53rd AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference 20th AIAA/ASME/AHS Adaptive Structures Conference 14th AIAA, p. 1909.(2012).

Analysing Mechanical Behaviors of Carbon Fiber Reinforced Silicone Matrix Composite Materials after Static Folding

Year 2020, Volume: 23 Issue: 2, 351 - 359, 01.06.2020

İsmail Sinan Atlı Atilla Evcin

Abstract

Subject of this paper is to provide information about mechanical behavior of a novel material to the literature: carbon fiber reinforced silicone matrix composite (CFRS-C). Under a mechanical load, silicone matrix allows large elastic deformations while carbon fiber reinforcement can bear high tensile stresses. This rare behavior of CFRS-C allows us to design foldable materials without being in a bind for mechanical hinges which bring additional weights. Foldable materials are used in space structures to gain advantage of smaller volumes. In this study, CFRS-C were manufactured with two different silicone type can be found in market and one type of plain weave unidirectional carbon fiber fabric. Specimens were prepared and kept folded 90º statically in various periods of time. They were subjected to tensile testing afterwards, to investigate effect of number of layers, silicone type and duration of folding to mechanical behavior.

Keywords

Foldable materials, composite, silicone, elastic, carbon fiber

References

Referans 1. Dano M.L., Gendron G., Picard A., Mechanical Behavior of a Triaxial Woven Fabric Composite, Mechanics of Composite Materials and Structures, 7:207-224, (2000).
Referans 2. Benarcyk B.A., Arnold S.M., ‘’Micromechanics-Based Modeling of Woven Polymer Matrix Composites’’, AIAA Journal, 41(9):1788-1796, (2003).
Referans 3. Le Page, B.H., Guild, F.J., Ogin, S.L. and Smith, P.A., ‘’Finite Element Simulation of Woven Fabric Composites’’, Composites: Part A, 35:861 - 872, (2004).
Referans 4. Hackett, R.M., ‘’Finite Elasticity’’, Hyperelasticity Primer, Springer International Publishing, USA, (2016)
Referans 5. Manuel J. Garcia R., Oscar E. Ruiz S., Carlos Lopez, "Hyperelastic Material Modeling", Technical Report, Laboratorio CAD/CAM/CAE, Departamento de Ingenieria Mecanica, Universidad EAFIT, Medellin, (2005).
Referans 6. T. W. Murphey, T. Meink, and M. M. Mikulas, ‘’Some micromechanics considerations of the folding of rigidizable composite materials’’ In 42nd AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference, AIAA:2001-1418, (2001).
Referans 7. W. H. Francis, M.S. Lake, and J. Steven Mayes, ‘’A review of classical _ber microbuckling analytical solutions for use with elastic memory composites’’, In 47th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference, Newport, RI ,AIAA-2006:1764, (2006).
Referans 8. Lopez Jimenez, F., ‘’Mechanics of thin carbon fiber composites with a silicone matrix’’, Doctoral dissertation, California Institute of Technology, (2011).
Referans 9. Baier, H., L. Datashvili, and J. Hoffmann. "Mechanically reconfigurable and massively shape morphing space structures." Proceedings of the 11th European Spacecraft Structures, Materials and Mechanical Testing Conference, (2009).
Referans 10. Murphey, T. W., ‘’Large Strain Composite Materials in Deployable Space Structures’’ In 17th International Conference on Composite Materials(Vol. 28). Edinburgh, UK: The British Composites Soc., (2009)
Referans 11. Campbell, D., Lake, M.S. and Mallick, K., "A study of the bending mechanics of elastic memory composites." In AIAA. 45th Structures, Structural Dynamics, and Materials Conference. California: Palm Springs: 1323-1331, (2004).
Referans 12. Datashvili, L., Baier, H., Wehrle, E., Kuhn, T., & Hoffmann, J.’’ Large shell-membrane space reflectors’’ In Proceedings of AIAA Structures, Dynamics, and Materials Conference, Honolulu, Hawaii, (2010).
Referans 13. ‘’Tembo Deployable Structures’’: https://www.ctd-materials.com/engineered-materials/tembo/ (accessed July 2018).
Referans 14. Vocke III, R.D., Kothera, C.S., Woods, B.K., Bubert, E.A. and Wereley, N.M.,’’One dimensional morphing structures for advanced aircraft’’ In Recent Advances in Aircraft Technology. IntechOpen, (2012).
Referans 15. Guynn, E.G., Bradley, W.L. and Ochoa, O.O., ‘’A parametric study of variables that affect fiber microbuckling initiation in composite laminates: Part 2—Experiments’’ Journal of Composite Materials, 26(11):1617-1643, (1992).
Referans 16. Drapier, S., Gardin, C., Grandidier, J.C. and Potier-Ferry, M., ‘’Structure effect and microbuckling’’ Composites Science and Technology, 56(7):861-867, (1996).
Referans 17. Drapier, S., Grandidier, J.C. and Potier-Ferry, M., ‘’A structural approach of plastic microbuckling in long fibre composites: comparison with theoretical and experimental results’’ International Journal of Solids and Structures, 38(22-23): 3877-3904, (2001).
Referans 18. Francis, W., Lake, M. and Mayes, J.S., ‘’A review of classical fiber microbuckling analytical solutions for use with elastic memory composites’’ In 47th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference 14th AIAA/ASME/AHS Adaptive Structures Conference 7th:1764 , (2006).
Referans 19. Marissen, R., and H. R. Brouwer. "The significance of fibre microbuckling for the flexural strength of a composite" Composites Science and Technology 59:3 (1999): 327-330, (1999).
Referans 20. Composites World. ‘’Advances in sizings and surface treatments for carbon fibers.’’. compositeworld.com: https://www.compositesworld.com/articles/advances-in-sizings-and-surface-treatments-for-carbon-fibers. (accessed May 2018).
Referans 21. Wu, Zhihong, Charles U. Pittman Jr, and Steven D. Gardner. "Nitric acid oxidation of carbon fibers and the effects of subsequent treatment in refluxing aqueous NaOH." Carbon33, 5: 597-605, (1995).
Referans 22. Mejia-Ariza, J., Guidanean, K., Murphey, T. and Biskner, A., "Mechanical characterization of L'Garde elastomeric resin composite materials." In 51st AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference 18th AIAA/ASME/AHS Adaptive Structures Conference 12th: 2701, (2010).
Referans 23. Jiménez, F.L. and Pellegrino, S., "Folding of fiber composites with a hyperelastic matrix." International Journal of Solids and Structures, 49(3-4):395-407, (2012).
Referans 24. Maqueda I, Pellegrino S, Mejia-Ariza J. "Characterization of a high strain composite material." In 53rd AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference 20th AIAA/ASME/AHS Adaptive Structures Conference 14th AIAA, p. 1909.(2012).

There are 24 citations in total.

Details

Primary Language	English
Subjects	Engineering
Journal Section	Research Article
Authors	İsmail Sinan Atlı 0000-0002-5899-4082 Atilla Evcin 0000-0002-0163-5097
Publication Date	June 1, 2020
Submission Date	April 3, 2019
Published in Issue	Year 2020 Volume: 23 Issue: 2

Cite

APA	Atlı, İ. S., & Evcin, A. (2020). Analysing Mechanical Behaviors of Carbon Fiber Reinforced Silicone Matrix Composite Materials after Static Folding. Politeknik Dergisi, 23(2), 351-359.
AMA	Atlı İS, Evcin A. Analysing Mechanical Behaviors of Carbon Fiber Reinforced Silicone Matrix Composite Materials after Static Folding. Politeknik Dergisi. June 2020;23(2):351-359.
Chicago	Atlı, İsmail Sinan, and Atilla Evcin. “Analysing Mechanical Behaviors of Carbon Fiber Reinforced Silicone Matrix Composite Materials After Static Folding”. Politeknik Dergisi 23, no. 2 (June 2020): 351-59.
EndNote	Atlı İS, Evcin A (June 1, 2020) Analysing Mechanical Behaviors of Carbon Fiber Reinforced Silicone Matrix Composite Materials after Static Folding. Politeknik Dergisi 23 2 351–359.
IEEE	İ. S. Atlı and A. Evcin, “Analysing Mechanical Behaviors of Carbon Fiber Reinforced Silicone Matrix Composite Materials after Static Folding”, Politeknik Dergisi, vol. 23, no. 2, pp. 351–359, 2020.
ISNAD	Atlı, İsmail Sinan - Evcin, Atilla. “Analysing Mechanical Behaviors of Carbon Fiber Reinforced Silicone Matrix Composite Materials After Static Folding”. Politeknik Dergisi 23/2 (June 2020), 351-359.
JAMA	Atlı İS, Evcin A. Analysing Mechanical Behaviors of Carbon Fiber Reinforced Silicone Matrix Composite Materials after Static Folding. Politeknik Dergisi. 2020;23:351–359.
MLA	Atlı, İsmail Sinan and Atilla Evcin. “Analysing Mechanical Behaviors of Carbon Fiber Reinforced Silicone Matrix Composite Materials After Static Folding”. Politeknik Dergisi, vol. 23, no. 2, 2020, pp. 351-9.
Vancouver	Atlı İS, Evcin A. Analysing Mechanical Behaviors of Carbon Fiber Reinforced Silicone Matrix Composite Materials after Static Folding. Politeknik Dergisi. 2020;23(2):351-9.

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