A Complementary Biodiesel Blend from Soapnut Oil and Free Fatty Acids

  • chair:

    Chien, Y. / Tang, T. / Chiang, T. / Huang, B. / Chang, C. / Chiang, P. / Shie, J. / Franzreb, M. / Chen, L. (2012)

  • place:

     Energies 5 (2012), 8, 3137–3148

  • Date: 2012
  • Chien, Y. / Tang, T. / Chiang, T. / Huang, B. / Chang, C. / Chiang, P. / Shie, J. / Franzreb, M. / Chen, L. (2012): „A Complementary Biodiesel Blend from Soapnut Oil and Free Fatty Acids“. In: Energies 5 (2012), 8, 3137–3148

Abstract

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Blends of biodiesels produced from soapnut oil and high-oleic free fatty acids (FFAs), which are potential non-edible oil feedstocks, were investigated with respect to their fuel properties. The soapnut oil methyl esters (SNME) had satisfactory fuel properties with the exception of its high cold filter plugging point.

In contrast, the biodiesel from the FFAs had favorable fuel properties such as a low cold filter plugging point of -6 °C; however, it exhibits poor oxidation stability with an induction period (IP) of 0.2 h. The complementary blend of the SNME and the FFA-based biodiesel at various weight ratios was studied to improve the fuel properties.

As a result, the biodiesel blend at a weight ratio of 70:30 can successfully meet all the biodiesel specifications, except the marginal oxidation stability. Furthermore, the effectiveness of N,N’-di-sec-butyl-p-phenylenediamine at the concentration between 100 and 500 ppm on the improvement in the oxidation stability of the biodiesel blend was examined.

The relationship between the IP values associated with the consumption of antioxidants in the biodiesel blends was described by first-order reaction rate kinetics. In addition, the natural logarithm of IP (ln IP) at various concentrations of antioxidant presented a linear relation with the test temperature. The IP at ambient temperature can be predicted based on the extrapolation of the temperature dependence relation.