Kinetic Parameter Estimation from Thermogravimetry and Microscale Combustion Calorimetry
References:
[1] Keattch, CJ, Dollimore D (2000). An introduction to thermogravimetry. Heyden.
[2] ASTM E1641-16 (2016), Standard Test Method for Decomposition Kinetics by Thermogravimetry Using the Ozawa/Flynn/Wall Method, ASTM International, West Conshohocken, PA.
[3] Prime RB, Bair HE, Vyazovkin S, Gallagher PK, Riga A (2009). Thermogravimetric analysis (TG). Thermal analysis of polymers: Fundamentals and applications. 241-317.
[4] Kim, E., & Dembsey, N. (2012). Engineering guide for estimating material pyrolysis properties for fire modeling. Project Final Report, 382.
[5] Matala A, Lautenberger C, Hostikka S (2012). Generalized direct method for pyrolysis kinetic parameter estimation and comparison to existing methods. Journal of fire sciences. 30(4):339-56.
[6] Jiang L, Zhang D, Li M, He JJ, Gao ZH, Zhou Y, Sun JH. (2018). Pyrolytic behavior of waste extruded polystyrene and rigid polyurethane by multi kinetics methods and Py-GC/MS. Fuel, 222, 11-20.
[7] Jiao LL, Sun JH (2014). A thermal degradation study of insulation materials extruded polystyrene. Procedia Engineering, 71, 622-628.
[8] Mishra RK, Mohanty K (2018). Pyrolysis kinetics and thermal behavior of waste sawdust biomass using thermogravimetric analysis. Bioresource technology. 251:63-74.
[9] Lyon, R. E., & Walters, R. N. (1999). U.S. Patent No. 5,981,290. Washington, DC: U.S. Patent and Trademark Office.
[10] Walters RN, Lyon RE (2001), Heat release capacity. Fire & Materials Conference, San Francisco, CA.
[11] Lyon RE, Walters RN (2004), Pyrolysis combustion flow calorimetry. Journal of Analytical and Applied Pyrolysis. 71(1):27-46.
[12] Walters R.N, Lyon R.E (1997), Microscale combustion calorimeter for determining flammability parameters of materials. Evolving Technologies for the Competitive Edge. 42: 1335-1344.
[13] Asante-Okyere, S., Xu, Q., Mensah, R. A., Jin, C., & Ziggah, Y. Y. (2018). Generalized regression and feed forward back propagation neural networks in modelling flammability characteristics of polymethyl methacrylate (PMMA). Thermochimica Acta, 667, 79-92.
[14] Mensah, R. A., Xu, Q., Asante-Okyere, S., Jin, C., & Bentum-Micah, G. Correlation analysis of cone calorimetry and microscale combustion calorimetry experiments. Journal of Thermal Analysis and Calorimetry, 1-11.
[15] Snegirev AY, Talalov VA, Stepanov VV, Harris JN (2012). Formal kinetics of polystyrene pyrolysis in non-oxidizing atmosphere. Thermochimica acta. 548:17-26.
[16] Snegirev, A. Y. (2014). Generalized approach to model pyrolysis of flammable materials. Thermochimica Acta, 590, 242-250.
[17] Standard Test Method for Determining Flammability Characteristics of Plastic’s and Other Solid Materials Using Microscale Combustion Calorimetry. ASTM D7309-13.
[18] Lyon RE, Walters RN (2004). Pyrolysis combustion flow calorimetry. Journal of Analytical and Applied Pyrolysis. 71(1):27-46.
[19] Brems A, Baeyens J, Beerlandt J, Dewil R (2011). Thermogravimetric pyrolysis of waste polyethylene-terephthalate and polystyrene: A critical assessment of kinetics modelling. Resources, Conservation and Recycling. 55(8):772-81.
[20] Logan SR. (1982). The origin and status of the Arrhenius equation. Journal of Chemical Education, 59(4), 279.
[21] Chen Y, Wang Q (2007) Thermal oxidative degradation kinetics of flame-retarded polypropylene with intumescent flame-retardant master batches in situ prepared in twin-screw extruder. Polymer Degradation and Stability. 92:280–91.
[22] Bianchi O, Oliveira R, Fioro R, Martins J, Zattera A, Canto L (2008). Assessment of Avrami, Ozawa and Avrami–Ozawa equations for determination of EVA cross-linking kinetics from DSC measurements. Polymer Testing. 27:722–9.
[23] Lyon RE, Filipczak R, Walters RN, Crowley S, Stoliarov SI (2007). Thermal Analysis of Polymer Flammability, Report No. DOT/FAA/AR-07/2.
[24] Akahira T, Sunose T (1971). Method of determining activation deterioration constant of electrical insulating materials. Res Rep Chiba Inst Technol (Sci Technol). 16:22–31.