Home Articles List Article Information
Journal of Petroleum and Mining Engineering
Journal Archive
Volume Volume 23 (2021)
Volume Volume 22 (2020)
Volume Volume 21 (2019)
Volume Volume 20 (2018)
Volume Volume 19 (2017)
Volume Volume 18 (2016)
Volume Volume 17 (2015)
Ahmed Elgharbawy, A. (2020). Production of biodiesel from used cooking using linear regression analysis. Journal of Petroleum and Mining Engineering, 22(2), 92-99. doi: 10.21608/jpme.2020.39252.1044
Abdallah Sayed Ahmed Elgharbawy. "Production of biodiesel from used cooking using linear regression analysis". Journal of Petroleum and Mining Engineering, 22, 2, 2020, 92-99. doi: 10.21608/jpme.2020.39252.1044
Ahmed Elgharbawy, A. (2020). 'Production of biodiesel from used cooking using linear regression analysis', Journal of Petroleum and Mining Engineering, 22(2), pp. 92-99. doi: 10.21608/jpme.2020.39252.1044
Ahmed Elgharbawy, A. Production of biodiesel from used cooking using linear regression analysis. Journal of Petroleum and Mining Engineering, 2020; 22(2): 92-99. doi: 10.21608/jpme.2020.39252.1044

Production of biodiesel from used cooking using linear regression analysis

Article 10, Volume 22, Issue 2, Summer and Autumn 2020, Page 92-99  XML PDF (491.13 K)
Document Type: Original Article
DOI: 10.21608/jpme.2020.39252.1044
Author
Abdallah Sayed Ahmed Elgharbawy email orcid
material science, Institute of Graduate Studies and Research, alexandria
Abstract
Biodiesel represents a closed carbon dioxide cycle (approximately 78%) because it is derived from renewable biomass sources. "Bio" means its biological and renewable source, and "diesel" represents its use as a fuel on diesel engines. Biodiesel is defined as “mono-alkyl esters of long chain fatty acids derived from vegetable oils and animal fats”. The present study was carried out in order to identify an effective treatment of used cooking oil to get the ideal specification condition to obtain high yield of biodiesel and get the best conversion ratio of used cooking oil to biodiesel. The linear regression analysis concluded that methanol to oil ratio and catalyst concentration have a high positive statistical significant effect. Temperature has a positive statistical significant effect. The process time had a non statistical significant negative effect on the biodiesel yield and the mixing rate had a highly negative statistical significant effect. The best methyl ester conversion obtained was 99.2 wt.% based on the following conditions : methanol to oil molar ratio of 7.54:1, catalyst concentration of 0.875% , 1.17 hr. of reaction time, temperature of 52 °C, mixing rate 266 rpm.
Keywords
biodiesel; linear regression; biodiesel specifications
Main Subjects
Renewable Energy
Statistics
Article View: 160
PDF Download: 188