THE OXIDATION KINETICS FOR THE DISCONTINUOUS CARBON FIBERS COMPOSITE MATERIALS

The investigating results are given for the oxidation kinetics of the composite material on base of both the discontinuous carbon fibers and the phenolformaldehyde resin. According to the results of the thermal analyses amid the oxidation condition the oxidation model was elaborated both for single components and for the composite material in total. The fiber's oxidizing is one-stage, the resin's oxidizing is two-stage, the composite oxidizes in three stages. Based on the calculated parameters of the reaction the isothermal curves were plotted for the temperature within 220‒300 °C at intervals of 10 °C and holding at the heating time up to 5 hours. It was established that at 300 °C during 5 hours the composite material by oxidation lost no more than 5 % of its initial mass. Ill. 3. Ref. 14. Tab. 2. 

1. Morgan, P. Carbon fiber and their composites / P. Morgan. ― Boca Raton, Florida : Taylor & Francis Group, 2005. ― P. 1011‒1200.

2. Фиалков, А. С. Углерод, межслоевые соединения и композиты на его основе / А. С. Фиалков. ― М. : Аспект Пресс, 1997. ― 718 с.

3. Blanco, C. The stabilization of carbon fibers studied by micro-thermal analysis / C. Blanсo, S. Lu, S. Appleyard, B. Rand // Carbon. ― 2003. ― Vol. 41, № 1. ― P. 165‒171.

4. Boehm, H. Surface oxides on carbon and their analysis: a critical assessment / H. Boehm // Carbon. ― 2002. ― Vol. 40. ― P. 145‒149.

5. Cho, D. Microstructural evidence for the thermal oxidation protection of carbon/phenolic towpregs and composites / D. Cho, H. Ha, Y. Lim // Carbon. ― 1996. ‒ Vol. 34, № 7. ― P. 163‒190.

6. Fitzer, E. The future of carbon-carbon composites / E. Fitzer // Carbon. ― 1988. ― Vol. 24, № 2. ― P. 163‒190.

7. Говоров, А. В. Исследование кинетики окисления углеродных волокон различных типов / А. В. Говоров, А. А. Галигузов, Н. А. Тихонов [и др.] // Новые огнеуоры. ― 2015. ― № 11. ― С. 34‒39. Govorov, A. Study of different types of carbon fiber oxidation kinetics / A. Govorov, A. Galiguzov, N. Tikhonov [et al.] // Refractories and Industrial Ceramics. ― 2016. ― Vol. 56, № 6. ― P. 605‒609.

8. Kimberly, A. Mechanisms of the pyrolysis of phenolic resin in a carbon/phenolic composite / A. Kimberly, T. Saliba // Carbon. ― 1995. ― Vol. 33, № 11. ― P. 1509‒1515.

9. Wong, H. Measurement of pyrolysis products from phenolic polymer thermal decomposition / H. Wong, J. Peck, R. Edwarts [et al.] // AIAA SciTech. ― 2014.

10. ASTM D4102-82(2015). Standard test method for thermal oxidative resistance of carbon fibers, ASTM International : West Conshohocken, PA, 2015 (www. astm.org).

11. Friedman, H. Kinetics of thermal degradation of charforming plastics from thermogravimetry. Application to a phenolic plastic / H. Friedman // J. Polym. Sci. : Polymer Symposia.― 1964. ― Vol. 6, № 1. ― P. 183‒195.

12. Ozawa, T. A new method of analyzing termogravimetric data / T. Ozawa // Bull. Chem. Soc. ― 1965. ― Vol. 38, № 11. ― P. 1881‒1886.

13. Opfermann, J. Kinetic analysis using multivariate non-linear regression / J. Opfermann // J. Therm. Anal. Calorium. ― 2000. ― Vol. 60. ― P. 641‒658.

14. Guo, W. Kinetics and mechanisms of non-isothermal oxidation of graphite in air / W. Guo, H. Xiao, G. Zhang // Corros. Sci. ― 2008. ― Vol. 50. ― P. 2007‒2011