TY - JOUR
T1 - Synergistic effect on co-pyrolysis of rice husk and sewage sludge by thermal behavior, kinetics, thermodynamic parameters and artificial neural network
AU - Naqvi, Salman Raza
AU - Hameed, Zeeshan
AU - Tariq, Rumaisa
AU - Taqvi, Syed A.
AU - Ali, Imtiaz
AU - Niazi, M. Bilal Khan
AU - Noor, Tayyaba
AU - Hussain, Arshad
AU - Iqbal, Naseem
AU - Shahbaz, M.
PY - 2019/2/15
Y1 - 2019/2/15
N2 - This study investigates the thermal decomposition, thermodynamic and kinetic behavior of rice-husk (R), sewage sludge (S) and their blends during co-pyrolysis using thermogravimetric analysis at a constant heating rate of 20 °C/min. Coats-Redfern integral method is applied to mass loss data by employing seventeen models of five major reaction mechanisms to calculate the kinetics and thermodynamic parameters. Two temperature regions: I (200–400 °C) and II (400–600 °C) are identified and best fitted with different models. Among all models, diffusion models show high activation energy with higher R2(0.99) of rice husk (66.27–82.77 kJ/mol), sewage sludge (52.01–68.01 kJ/mol) and subsequent blends (45.10–65.81 kJ/mol) for region I and for rice husk (7.31–25.84 kJ/mol), sewage sludge (1.85–16.23 kJ/mol) and blends (4.95–16.32 kJ/mol) for region II, respectively. Thermodynamic parameters are calculated using kinetics data to assess the co-pyrolysis process enthalpy, Gibbs-free energy, and change in entropy. Artificial neural network (ANN) models are developed and employed on co-pyrolysis thermal decomposition data to study the reaction mechanism by calculating Mean Absolute Error (MAE), Root Mean Square Error (RMSE) and coefficient of determination (R2). The co-pyrolysis results from a thermal behavior and kinetics perspective are promising and the process is viable to recover organic materials more efficiently.
AB - This study investigates the thermal decomposition, thermodynamic and kinetic behavior of rice-husk (R), sewage sludge (S) and their blends during co-pyrolysis using thermogravimetric analysis at a constant heating rate of 20 °C/min. Coats-Redfern integral method is applied to mass loss data by employing seventeen models of five major reaction mechanisms to calculate the kinetics and thermodynamic parameters. Two temperature regions: I (200–400 °C) and II (400–600 °C) are identified and best fitted with different models. Among all models, diffusion models show high activation energy with higher R2(0.99) of rice husk (66.27–82.77 kJ/mol), sewage sludge (52.01–68.01 kJ/mol) and subsequent blends (45.10–65.81 kJ/mol) for region I and for rice husk (7.31–25.84 kJ/mol), sewage sludge (1.85–16.23 kJ/mol) and blends (4.95–16.32 kJ/mol) for region II, respectively. Thermodynamic parameters are calculated using kinetics data to assess the co-pyrolysis process enthalpy, Gibbs-free energy, and change in entropy. Artificial neural network (ANN) models are developed and employed on co-pyrolysis thermal decomposition data to study the reaction mechanism by calculating Mean Absolute Error (MAE), Root Mean Square Error (RMSE) and coefficient of determination (R2). The co-pyrolysis results from a thermal behavior and kinetics perspective are promising and the process is viable to recover organic materials more efficiently.
UR - http://www.scopus.com/inward/record.url?eid=2-s2.0-85059093171&partnerID=MN8TOARS
U2 - 10.1016/j.wasman.2018.12.031
DO - 10.1016/j.wasman.2018.12.031
M3 - Article
SN - 0956-053X
VL - 85
SP - 131
EP - 140
JO - Waste Management
JF - Waste Management
ER -