分别以水合化法和热缺陷法对CaO进行表面更新,用N2物理吸附(BET)、X射线衍射(XRD)、扫描电镜(SEM)和CO2吸附技术对表面更新后的CaO进行了结构表征,并利用制备的CaO在管式炉内对微拟球藻进行了催化热解研究。结果表明:两种更新方法均能明显提高CaO的比表面积、介孔数目及孔体积。CaO的表面更新处理没有改变基本的晶相结构,仍为立方晶型。两种更新方法均能显著提高CaO的催化活性,且改善了产物油品的性能。相比较而言,水合CaO的催化脱氧性能较高,催化热解得到的生物油产率为28.65%、含氧量为4.67%、热值高达38.600 kJ·g-1、运动黏度低(8.011 mm2·s-1)、含水率低(2.49%),且催化热解后的生物油以C12~C17饱和直链烷烃为主,适合进一步精制为生物柴油。%The surface of calcium oxide (CaO) was renewed by using hydration-calcination and thermal calcinations methods, respectively. The structure and property of renewed CaO was characterized by BET, XRD, SEM and CO2-TPD techniques. Meanwhile, the catalytic pyrolysis ofNannochloropsis sp. was investigated in a fixed-bed reactor. It is shown that two preparation methods for CaO obviously increase the specific surface area, meso-pore numbers, and pore volume. The renewed surface CaO catalysts were of typical face-centered structure and of higher catalyst activity, and could improve bio-oil product quantity. The yield of bio-oil produced on the hydration-calcination CaO was 28.65%, which was of higher calorific value (38.600 kJ·g-1), lower kinetic viscosity (8.011 mm2·s-1), and lower moisture content (2.49%). The main ingredients of bio-oil from catalytic pyrolysis ofNannochloropsis sp. were C12-C17 saturated normal alkanes, which are more suitable for being upgraded to bio-diesel.
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