Thermal decomposition characteristics and kinetics of methyl linoleate under nitrogen and oxygen atmospheres

Wang, Xuechun; Fang, Jianhua; Chen, Boshui; Wang, Jiu; Wu, Jerry J.; Xia, Di

doi:10.1007/s12182-015-0034-9

Cited by 4 publications

(2 citation statements)

References 16 publications

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“…There is a probability of temperature gradients that may exist within the sample, and thus the devolatilization rate will be faster than the volatile release, and consequently, various devolatilization stages may occur. 27 These results are in agreement with work reported in the literature such as that of Wang et al, 28 Unapumnuk et al, 29 and Chen et al 27 Figures S4 and S5 show that the peak height was shifted from 0.5 to 5.5 W•g −1 by increasing the heating rates from 2 to 8 °C•min −1 .…”

Section: ■ Materials and Methodssupporting

confidence: 90%

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Physicochemical Characterization and Kinetic Modeling Concerning Combustion of Waste Berry Pomace

Osman

Young

Farrell

et al. 2020

ACS Sustainable Chem. Eng.

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Herein waste biomass (blackberry pomace) was physicochemically characterized and its thermochemical products. This is coupled with the evaluation of the kinetic triplet (activation energy, pre-exponential constant and the rate of reaction) and thermal predictions for the combustion process for the first time via the AKTS thermokinetics package. The main kinetic modelling method employed was the differential iso-conversional analysis; however, the Flynn-Wall-Ozawa and ASTM E-698 methods were used as a comparison. The model was developed and validated from experimental DSC and TGA data; resulting in an excellent match (R 2 = 0.99544 and 0.99194, respectively). The activation energies were evaluated using the ASTM-E698 method (88.64 kJ.mol -1 ) and Ozawa-Flynn-Wall methods (50-140 kJ.mol -1 ). The differential iso-conversional method showed activation energy values were in the range of 84-197 kJ.mol -1 for the combustion of berry pomace. Isothermal predictions based on the model indicated at temperatures of 560 o C and 600 o C; the reaction had achieved 100% completion (=1) after 30 and 6 minutes, respectively. For the non-isothermal prediction, the heating rates of 50, 75 and 100 °C/min have a two-stage rate profile with a maximum peak in the first stage of the reaction. Thereafter, the reaction rate increases once again but not to the same effect as the first initial stage. For instance, at 100 °C/min, stage 1 and 2 are reported as 0.005381 and 0.005148 s -1 , respectively. Overall, this study demonstrates the success of the approach in modelling the thermochemical conversion of berry pomace as waste stream biomass.

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Section: ■ Materials and Methodssupporting

confidence: 90%

“…Arrhenius Equation k=k0 within the sample, and thus devolatilization rate will be faster than the volatile release, and consequently, various devolatilization stages may occur 27 . These results are in agreement with the work reported in the literature such as Wang et al 28 , Unapumnuk et al 29 and Chen et al…”

Section: Non-isothermalsupporting

confidence: 94%