1. IntroductionThe demand of energy

1. Introduction
The demand of energy has increased rapidly with growing of world population. The reserves of fossil fuels are being depleted, while the environmental problems caused by their use have become serious. Thus, the renewable energies have been promptly developed (Mori, 2009; Werther, 2009). Among the applicable renewable energies, biodiesel has attracted much attention. The transesterification of vegetable oil or animal fat with alcohol such as methanol and ethanol is commonly applied to produce the biodiesel, which is an alternative fuel used for diesel engines. A strong base such as sodium or potassium hydroxide is used to
* Corresponding author at: Graduate Institute of Environmental Engineering, National Taiwan University, Taipei, Taiwan. Tel.: +886 223638994;
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E-mail address: cychang3@ntu.edu.tw (C.-Y. Chang).
catalyze the production of biodiesel. The reaction between triacylglycerol and alcohol releases three fatty acids from the glycerol skeleton which then combine with the alcohol to yield fatty acid alkyl esters. Glycerol is produced as a by-product. Normally, methanol and ethanol are most favorable alcohols for the use because of their low expense (Hanh et al., 2009). Ultrasound application in the extraction field and biodiesel production was shown to dramatically enhance the yield of the extract and the homogenization for the production process (Cravotto et al., 2008; Deng et al., 2010; Stavarache et al., 2007; Teixeira et al., 2009). Obviously, the biodiesel no doubt exhibits some advantages over the petroleum-based diesel. Biodiesel is biodegradable. It is less toxic, emitting lower particles, smoke and carbon monoxide while more friendly with the environment than the petroleum based diesel. Moreover, the biodiesel as an alternative fuel can be produced from the renewable materials that are potential feedstocks for the green energy production today (Koc, 2009). The alternative use of renewable fuel is not only
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Table 1
Some properties of Tung, canola and palm oils.
Property
AV
Iodine value (IV) KV 408C
Density 15 8C CFPP
Unit
mg KOH/g mg I2/100 g mm2/s kg/m3
8C
CNS No. (TBOS, 2010) CNS 14906
CNS 15060 CNS 3390 CNS 14474 CNS 15061
D. Van Manh et al. / Journal of the Taiwan Institute of Chemical Engineers 42 (2011) 640–644 641
adapted in the energy policy by each country but also greatly concerned by all nations over the world aiming at reducing the globe warming now. Advanced synthetic routes and cheaper raw materials have been intended. Routes employed included reducing the reaction time, catalyst and energy consumption, while enhancing the yield of ester for production (Deshmane et al., 2009). Up to now, there are many materials used for a large-scale biodiesel production such as rapeseed oil in Europe, soybean oil in the United States of America and palm oil in Southeast Asia (Chung, 2010). However, biodiesel production has some obstacles, especially the high cost of feedstocks for the production and the post-treatment of byproducts. Tung oil (Vernicia fordii) also called China’s wood oil is non-edible oil extracted from the seed of Tung tree, which spreads widely in the southwest of China and Taiwan. Shang et al. (2010) indicated that it is a promising raw material for the biodiesel production in the future. Many studies have been intensively conducted on the production of biodiesel using edible oils but few using Tung oil. Park et al. (2008) investigated the influence of the production condition on the unsaturated structure of Tung oil. Li et al. (2010) examined the transesterification reaction of Tung oil with alcohol using the solid acid catalyst in the fixed bed. Xu et al. (2006) applied bio-enzyme as a catalyst for the transesterification of Tung oil. For avoiding employing the edible oils for the production of biodiesel that would increase the price of foods, the use of non-foodstuff materials as bio-energy resource becomes the common consensus of the renewable energy policy. The non-edible Tung oil was thus chosen as the raw material to produce the biodiesel in this study. The high viscosity of Tung oil can be reduced by blending with other oils of low viscosity such as canola and palm oils. The blending also aimed at some targets such as improving the performance, and reducing the kinematic viscosity (KV) and cold filter plugging point (CFPP) for the biodiesel product. The blended oil is consisted of 20, 50 and 30% of Tung, canola and palm oils, respectively. The effect of power of ultrasonic irradiation (PWUS) and irradiation time (tUS) on the transesterifica- tion yield (YF) and some major properties of biodiesels produced from Tung and blended oils such as acid value (AV), iodine value (IV), KV, density and CFPP, were elucidated.