用铜掺杂氧化锌异质纳米催化剂从印楝油中生产生物柴油的工艺优化及动力学研究。

Process optimization and kinetics of biodiesel production from neem oil using copper doped zinc oxide heterogeneous nanocatalyst.

机构信息

Department of Biotechnology, St. Joseph's College of Engineering, Chennai 600 119, India.

出版信息

Bioresour Technol. 2015 Aug;190:424-8. doi: 10.1016/j.biortech.2015.04.101. Epub 2015 Apr 30.

DOI:10.1016/j.biortech.2015.04.101

Abstract

Heterogeneous nanocatalyst has become the choice of researchers for better transesterification of vegetable oils to biodiesel. In the present study, transesterification reaction was optimized and kinetics was studied for biodiesel production from neem oil using CZO nanocatalyst. The highly porous and non-uniform surface of the CZO nanocatalyst was confirmed by AFM analysis, which leads to the aggregation of CZO nanoparticles in the form of multi layered nanostructures. The 97.18% biodiesel yield was obtained in 60min reaction time at 55°C using 10% (w/w) CZO nanocatalyst and 1:10 (v:v) oil:methanol ratio. Biodiesel yield of 73.95% was obtained using recycled nanocatalyst in sixth cycle. The obtained biodiesel was confirmed using GC-MS and (1)H NMR analysis. Reaction kinetic models were tested on biodiesel production, first order kinetic model was found fit with experimental data (R(2)=0.9452). The activation energy of 233.88kJ/mol was required for transesterification of neem oil into biodiesel using CZO nanocatalyst.

摘要

用于更好地将植物油酯化为生物柴油的异质纳米催化剂已成为研究人员的选择。在本研究中，使用 CZO 纳米催化剂对从印楝油生产生物柴油的酯交换反应进行了优化和动力学研究。AFM 分析证实了 CZO 纳米催化剂具有高度多孔和不均匀的表面，这导致 CZO 纳米颗粒以多层纳米结构的形式聚集。在 55°C 下，使用 10%（w/w）的 CZO 纳米催化剂和 1:10（v:v）的油:甲醇比，在 60min 的反应时间内可获得 97.18%的生物柴油产率。在第六个循环中，使用回收的纳米催化剂可获得 73.95%的生物柴油产率。使用 GC-MS 和 (1)H NMR 分析对生物柴油进行了确认。在生物柴油生产中测试了反应动力学模型，发现一级动力学模型与实验数据拟合良好（R(2)=0.9452）。使用 CZO 纳米催化剂将印楝油转化为生物柴油需要 233.88kJ/mol 的活化能。

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用铜掺杂氧化锌异质纳米催化剂从印楝油中生产生物柴油的工艺优化及动力学研究。

Process optimization and kinetics of biodiesel production from neem oil using copper doped zinc oxide heterogeneous nanocatalyst.

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