Clayton Copula as an Alternative Perspective of Multi-Reaction Model

Clayton Copula as an Alternative Perspective of Multi-Reaction Model

This study proposes to assess the effect of some relevant parameters of biomass pyrolysis on the numerical solutions of n order distributed activation energy model (DAEM) or multi reaction model (MRM). The two-step process mechanisms of pyrolysis is described by replacing the initial distribution fu...

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Veröffentlicht in:Environmental and Climate Technologies 2018-11, Vol.22 (1), p.83-106
Hauptverfasser: Dhaundiyal, Alok, Singh, Suraj B., Hanon, Muammel M., Schrempf, Norbert
Format: Artikel
Sprache:eng
Schlagworte:
Activation energy
Alternative energy sources
Asymptotic solution
Biomass
biomass pyrolysis
Bivariate analysis
bivariate function
Carbon dioxide
Decomposition
distributed activation energy model
Distribution functions
Energy resources
Gases
Heating rate
Mathematical models
non-isothermal kinetics
Parameters
Pyrolysis
Renewable resources
Thermogravimetric analysis
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Beschreibung
Zusammenfassung:This study proposes to assess the effect of some relevant parameters of biomass pyrolysis on the numerical solutions of n order distributed activation energy model (DAEM) or multi reaction model (MRM). The two-step process mechanisms of pyrolysis is described by replacing the initial distribution function of f (E) with the Clayton copula. The upper limit (E ) of ‘dE’ integral, activation energy (A), heating rate (m), and the shape and scale parameters of bivariate distribution function. Temperature ramp rate is assumed to vary linearly with time. Thermo-analytical data is obtained with the help of thermogravimetric (TG) analysis. Asymptotic technique is adopted to approximate double exponential and bivariate distribution function f (E , E ), where E and E are the activation energies for bivariate scheme.
ISSN:2255-8837
1691-5208
2255-8837
DOI:10.2478/rtuect-2018-0006