Danish Mohammed, Kale Pradeep, Ahmad Tanweer, Ayoub Muhammad, Geremew Belete, Adeloju Samuel
Bioengineering Technology Section, Malaysian Institute of Chemical and Bioengineering Technology (MICET), Universiti Kuala Lumpur, Lot 1988, Kawasan Perindustrian Bandar Vendor, Taboh Naning, 78000, Alor Gajah, Melaka, Malaysia.
Department of Mechanical Engineering, JSPM's Bhivrabai Sawant Polytechnic, Wagholi, Pune, 412207, India.
Data Brief. 2020 Feb 4;29:105225. doi: 10.1016/j.dib.2020.105225. eCollection 2020 Apr.
The dataset presented here are part of the data planned to produce biodiesel from flaxseed. Biodiesel production from flaxseed oil through transesterification process using KOH as catalyst, and the operating parameters were optimized with the help of face-centered central composite design (FCCD) of response surface methodology (RSM). The operating independent variables selected such as, methanol oil ratio (4:1 to 6:1), catalyst (KOH) weight (0.40-1.0%), temperature (35 °C-65 °C), and reaction time (30 min-60 min) were optimized against biodiesel yield as response. The maximum yield (98.6%) of biodiesel from flaxseed can achieved at optimum methanol oil ratio (5.9:1), catalyst (KOH) weight (0.51%), reaction temperature (59.2 °C), and reaction time (33 min). The statistical significance of the data set was tested through the analysis of variance (ANOVA). These data were the part of the results reported in "Optimization of process variables for biodiesel production by transesterification of flaxseed oil and produced biodiesel characterizations" Renewable Energy [1].
此处展示的数据集是计划用于从亚麻籽生产生物柴油的数据的一部分。通过使用氢氧化钾作为催化剂,经由酯交换过程从亚麻籽油生产生物柴油,并借助响应面法(RSM)的面心中央复合设计(FCCD)对操作参数进行了优化。所选择的操作自变量,如甲醇与油的比例(4:1至6:1)、催化剂(氢氧化钾)重量(0.40 - 1.0%)、温度(35℃ - 65℃)和反应时间(30分钟 - 60分钟),以生物柴油产率作为响应进行了优化。在最佳甲醇与油的比例(5.9:1)、催化剂(氢氧化钾)重量(0.51%)、反应温度(59.2℃)和反应时间(33分钟)下,可实现亚麻籽生物柴油的最大产率(98.6%)。通过方差分析(ANOVA)对数据集的统计显著性进行了检验。这些数据是发表于《可再生能源》[1]的“亚麻籽油酯交换生产生物柴油的工艺变量优化及所产生物柴油特性”报告结果的一部分。
