Lifetime prediction of NBR composite sheet in aviation kerosene by using nonlinear curve fitting of ATR-FTIR spectra

Ying Xiong; Guangshun Chen; Shaoyun Guo; Guangxian Li

Journal of Industrial and Engineering Chemistry, Vol.19, No.5, 1611-1616, September, 2013

DOI10.1016/j.jiec.2013.01.031 Export Citation

Lifetime prediction of NBR composite sheet in aviation kerosene by using nonlinear curve fitting of ATR-FTIR spectra

Ying Xiong, Guangshun Chen, Shaoyun Guo^†, and Guangxian Li

The State Key Laboratory of Polymer Materials Engineering, Polymer Research Institute of Sichuan University, Chengdu 610065, China

E-mail:

The accelerated thermal aging was performed for NBR composite sheet in aviation kerosene. It was observed by XPS and ATR-FTIR that some obvious changes related to silicon were caused by thermal aging. Based on careful analysis of ATR-FTIR spectra of various NBR samples, a probable aging mechanism for NBR composite sheet in aviation kerosene was proposed. With the help of nonlinear curve fitting of ATR-FTIR spectra and Arrhenius plot, the lifetime prediction equation of NBR composite sheet in aviation kerosene was obtained. The lifetime of NBR composite sheet in aviation kerosene at room temperature (25 ℃) was 6467 days.

Keywords:Thermal aging;NBR;Lifetime prediction;ATR-FTIR;Nonlinear curve fitting

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[2] Visser HA, Bor TC, Wolters M, Wismans JGF, Govaert LE, Macromolecular Materials and Engineering., 295, 1066 (2010)

[3] Li X, Yan R, Zhao Y, Journal of Systems Science and Complexity., 24, 753 (2011)

[4] Jin S, Han Y, Li H, Liv X, Integration the VLSI Journal., 44, 185 (2011)

[5] Nasdala L, Wei Y, Rothert H, Kaliske M, Tire Science and Technology., 36, 63 (2008)

[6] Bellenger V, Ganemt M, Mortaigne B, Verdu J, Polymer Degradation and Stability, 49, 91 (1995)

[7] Colin X, Verdu J, Plastics Rubber and Composites., 32, 349 (2003)

[8] Pinel B, Boutaud F, Nuclear Instruments & Methods in Physics Research Section B., 151, 471 (1999)

[9] Rowe BW, Pas SJ, Hill AJ, Suzuki R, Freeman BD, Paul DR, Polymer, 50(25), 6149 (2009)

[10] Laiarinandrasana L, Gaudichet E, Obertib S, Devilliers C, International Journal of Pressure Vessels and Piping., 88, 99 (2011)

[11] Finkestein MS, Reliability Engineering & System Safety., 76, 75 (2002)

[12] Youssef B, Dehbi AE, Hamou A, Saiter JM, Materials and Design., 29, 2017 (2008)

[13] Perera MCS, Ishiaku US, Ishak ZAM, Polymer Degradation and Stability., 68, 393 (2000)

[14] Woo CS, Choi SS, Lee SB, Kim HS, IEEE Transactions on Reliability., 59, 11 (2010)

[15] Pan J, Xu S, Chen W, Wang X, Qian P, Hu Q, Advances in Materials Research., 415-417, 184 (2012)

[16] Kahlen S, Wallner GM, Lang RW, Solar Energy., 84, 755 (2010)

[17] Colin X, Audouin L, Verdu J, Rozental-Evesque M, Rabaud B, Martin F, Bourgine F, Polym. Eng. Sci., 49(8), 1642 (2009)

[18] Choi SS, Kim JC, J. Ind. Eng. Chem., 18(3), 1166 (2012)

[19] Mostafa A, Abouel-Kasem A, Bayoumi MR, El-Sebaie MG, Materials and Design., 30, 791 (2009)

[20] Woo CS, Park HS, Engineering Failure Analysis., 18, 1645 (2011)

[21] Celina M, Gillen KT, Assink RA, Polymer Degradation and Stability., 90, 395 (2005)

[22] Puttnam NA, Lee S, Baxter BH, Journal of the Society of Cosmetic Chemists., 16, 607 (1965)

[23] Puttnam NA, Baxter BH, Lee S, Stott PL, Journal of the Society of Cosmetic Chemists., 17, 9 (1966)

[24] Barnette AL, Kim SH, Langmuir., 28, 15529 (2012)

[25] Kane SR, Ashby PD, Pruitt LA, Journal of Biomedical Materials Research-Applied Biomaterials., 91, 613 (2009)

[26] Vigano C, Manciu L, Buyse F, Goormaghtigh E, Ruysschaert JM, Biopolymers., 55, 373 (2000)

[27] Schuttlefield JD, Grassian VH, Journal of Chemical Education., 85, 279 (2008)