A cleaner route of biodiesel production from waste frying oil using novel potassium tin oxide catalyst: A smart liquid-waste management

[Display omitted] •Valorization of waste frying oil into biodiesel.•A novel potassium tin oxide (KSO 800) catalyst was used for biodiesel production.•The catalyst showed no leaching of K-species upto 5th cycle.•98% FAME conversion and 96% yield was achieved within 35 min.•This catalytic process foll...

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Published inWaste management (Elmsford) Vol. 135; pp. 243 - 255
Main Authors Roy, Tania, Ágarwal, Avinash Kumar, Sharma, Yogesh Chandra
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.11.2021
Subjects
activation energy
biodiesel
catalysts
catalytic activity
combustion
enthalpy
entropy
Gibbs free energy
Green parameters
Kinetics
Optimization
polymers
potassium
Potassium tin oxide
Reusability
temperature
tin dioxide
transesterification
waste management
Green parameters
Potassium tin oxide
Reusability
Kinetics
Optimization
Online AccessGet full text
ISSN0956-053X
1879-2456
1879-2456
DOI10.1016/j.wasman.2021.08.046

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Abstract [Display omitted] •Valorization of waste frying oil into biodiesel.•A novel potassium tin oxide (KSO 800) catalyst was used for biodiesel production.•The catalyst showed no leaching of K-species upto 5th cycle.•98% FAME conversion and 96% yield was achieved within 35 min.•This catalytic process followed a cleaner and greener route. The valorization of waste frying oil (WFO) to biodiesel has been carried out via solid base catalyzed transesterification reaction. A novel potassium tin oxide (KSO) catalyst was synthesized via polymer precursor auto combustion method. The catalyst showed the best physicochemical properties when it was calcined at 800 °C. Using KSO 800 catalyst, the highest FAME conversion (99.5%) of WFO found at moderated reaction condition within very short time (35 min); moreover, no leaching of K-species was observed in reusability test upto 5th cycle. Kinetics proved that the above catalytic reaction followed pseudo-first-order kinetics and the rate of the reaction was doubled with increasing 10 °C reaction temperature. The reaction activation energy, enthalpy of activation, entropy of activation, and Gibb's free energy of activation of the reaction were found to be 66.52 kJ/mol, 62.95 kJ/mol, −74.07 J/mol/K and 88 kJ/mol respectively. Evaluation of the green parameters revealed that KSO 800 catalyzed transesterification process approached a cleaner route with excellent efficacy in terms of turnover frequency and yield. KSO 800 helped to produce high quality biodiesel from WFO adopting faster and greener reaction pathway. Thus, KSO 800 was considered as a potential and green catalyst for transforming waste oil into biofuel.
AbstractList The valorization of waste frying oil (WFO) to biodiesel has been carried out via solid base catalyzed transesterification reaction. A novel potassium tin oxide (KSO) catalyst was synthesized via polymer precursor auto combustion method. The catalyst showed the best physicochemical properties when it was calcined at 800 °C. Using KSO 800 catalyst, the highest FAME conversion (99.5%) of WFO found at moderated reaction condition within very short time (35 min); moreover, no leaching of K-species was observed in reusability test upto 5ᵗʰ cycle. Kinetics proved that the above catalytic reaction followed pseudo-first-order kinetics and the rate of the reaction was doubled with increasing 10 °C reaction temperature. The reaction activation energy, enthalpy of activation, entropy of activation, and Gibb's free energy of activation of the reaction were found to be 66.52 kJ/mol, 62.95 kJ/mol, −74.07 J/mol/K and 88 kJ/mol respectively. Evaluation of the green parameters revealed that KSO 800 catalyzed transesterification process approached a cleaner route with excellent efficacy in terms of turnover frequency and yield. KSO 800 helped to produce high quality biodiesel from WFO adopting faster and greener reaction pathway. Thus, KSO 800 was considered as a potential and green catalyst for transforming waste oil into biofuel.
[Display omitted] •Valorization of waste frying oil into biodiesel.•A novel potassium tin oxide (KSO 800) catalyst was used for biodiesel production.•The catalyst showed no leaching of K-species upto 5th cycle.•98% FAME conversion and 96% yield was achieved within 35 min.•This catalytic process followed a cleaner and greener route. The valorization of waste frying oil (WFO) to biodiesel has been carried out via solid base catalyzed transesterification reaction. A novel potassium tin oxide (KSO) catalyst was synthesized via polymer precursor auto combustion method. The catalyst showed the best physicochemical properties when it was calcined at 800 °C. Using KSO 800 catalyst, the highest FAME conversion (99.5%) of WFO found at moderated reaction condition within very short time (35 min); moreover, no leaching of K-species was observed in reusability test upto 5th cycle. Kinetics proved that the above catalytic reaction followed pseudo-first-order kinetics and the rate of the reaction was doubled with increasing 10 °C reaction temperature. The reaction activation energy, enthalpy of activation, entropy of activation, and Gibb's free energy of activation of the reaction were found to be 66.52 kJ/mol, 62.95 kJ/mol, −74.07 J/mol/K and 88 kJ/mol respectively. Evaluation of the green parameters revealed that KSO 800 catalyzed transesterification process approached a cleaner route with excellent efficacy in terms of turnover frequency and yield. KSO 800 helped to produce high quality biodiesel from WFO adopting faster and greener reaction pathway. Thus, KSO 800 was considered as a potential and green catalyst for transforming waste oil into biofuel.
The valorization of waste frying oil (WFO) to biodiesel has been carried out via solid base catalyzed transesterification reaction. A novel potassium tin oxide (KSO) catalyst was synthesized via polymer precursor auto combustion method. The catalyst showed the best physicochemical properties when it was calcined at 800 °C. Using KSO 800 catalyst, the highest FAME conversion (99.5%) of WFO found at moderated reaction condition within very short time (35 min); moreover, no leaching of K-species was observed in reusability test upto 5th cycle. Kinetics proved that the above catalytic reaction followed pseudo-first-order kinetics and the rate of the reaction was doubled with increasing 10 °C reaction temperature. The reaction activation energy, enthalpy of activation, entropy of activation, and Gibb's free energy of activation of the reaction were found to be 66.52 kJ/mol, 62.95 kJ/mol, -74.07 J/mol/K and 88 kJ/mol respectively. Evaluation of the green parameters revealed that KSO 800 catalyzed transesterification process approached a cleaner route with excellent efficacy in terms of turnover frequency and yield. KSO 800 helped to produce high quality biodiesel from WFO adopting faster and greener reaction pathway. Thus, KSO 800 was considered as a potential and green catalyst for transforming waste oil into biofuel.The valorization of waste frying oil (WFO) to biodiesel has been carried out via solid base catalyzed transesterification reaction. A novel potassium tin oxide (KSO) catalyst was synthesized via polymer precursor auto combustion method. The catalyst showed the best physicochemical properties when it was calcined at 800 °C. Using KSO 800 catalyst, the highest FAME conversion (99.5%) of WFO found at moderated reaction condition within very short time (35 min); moreover, no leaching of K-species was observed in reusability test upto 5th cycle. Kinetics proved that the above catalytic reaction followed pseudo-first-order kinetics and the rate of the reaction was doubled with increasing 10 °C reaction temperature. The reaction activation energy, enthalpy of activation, entropy of activation, and Gibb's free energy of activation of the reaction were found to be 66.52 kJ/mol, 62.95 kJ/mol, -74.07 J/mol/K and 88 kJ/mol respectively. Evaluation of the green parameters revealed that KSO 800 catalyzed transesterification process approached a cleaner route with excellent efficacy in terms of turnover frequency and yield. KSO 800 helped to produce high quality biodiesel from WFO adopting faster and greener reaction pathway. Thus, KSO 800 was considered as a potential and green catalyst for transforming waste oil into biofuel.
Author Roy, Tania
Ágarwal, Avinash Kumar
Sharma, Yogesh Chandra
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  surname: Roy
  fullname: Roy, Tania
  organization: Department of Chemistry, Indian Institute of Technology (BHU) Varanasi, Varanasi 221005, India
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  givenname: Avinash Kumar
  surname: Ágarwal
  fullname: Ágarwal, Avinash Kumar
  organization: Department of Mechanical Engineering, Indian Institute of Technology Kanpur, Kanpur 208016 India
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  givenname: Yogesh Chandra
  surname: Sharma
  fullname: Sharma, Yogesh Chandra
  email: ysharma.apc@itbhu.ac.in
  organization: Department of Chemistry, Indian Institute of Technology (BHU) Varanasi, Varanasi 221005, India
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Kinetics
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Snippet [Display omitted] •Valorization of waste frying oil into biodiesel.•A novel potassium tin oxide (KSO 800) catalyst was used for biodiesel production.•The...
The valorization of waste frying oil (WFO) to biodiesel has been carried out via solid base catalyzed transesterification reaction. A novel potassium tin oxide...
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SubjectTerms activation energy
biodiesel
catalysts
catalytic activity
combustion
enthalpy
entropy
Gibbs free energy
Green parameters
Kinetics
Optimization
polymers
potassium
Potassium tin oxide
Reusability
temperature
tin dioxide
transesterification
waste management
Title A cleaner route of biodiesel production from waste frying oil using novel potassium tin oxide catalyst: A smart liquid-waste management
URI https://dx.doi.org/10.1016/j.wasman.2021.08.046
https://www.proquest.com/docview/2575065521
https://www.proquest.com/docview/2636598772
Volume 135
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