中国工程科学
中國工程科學
중국공정과학
ENGINEERING SCIENCE
2010年
1期
24-29
,共6页
生物柴油%酯交换反应%均相酸碱%固体酸碱%脂肪酶%超临界法
生物柴油%酯交換反應%均相痠堿%固體痠堿%脂肪酶%超臨界法
생물시유%지교환반응%균상산감%고체산감%지방매%초림계법
biodiesel%transesterification%homogeneous acid/base%solid acid/base%lipase%supercriticalmethod
生物柴油因其环境友好且可再生作为矿物柴油的替代燃料而备受关注,生物柴油主要通过均相酸碱催化、脂肪酶催化、超临界法和固体酸碱催化的酯交换反应制备得到,但各种制备方法各有优劣,均相酸碱催化法反应迅速,转化率高但存在后续处理复杂,污染严重等问题;脂肪酶催化法反应条件温和,对原料中的水和游离脂肪酸不敏感,不需要过量的甲醇参与反应,后续处理工序简单,但酶的成本过高,这是制约其商业化发展的最大阻碍;超临界法是制备生物柴油的新技术,反应迅速,不需要催化剂,油脂转化率非常高,但其反应需要高温高压且能耗很大;固体酸碱催化剂腐蚀性小可以重复使用,后续分离工序简单,对环境的冲击较弱.其中负载型固体碱催化剂催化油脂酯交换反应将成为制备生物柴油的一个主要发展方向.
生物柴油因其環境友好且可再生作為礦物柴油的替代燃料而備受關註,生物柴油主要通過均相痠堿催化、脂肪酶催化、超臨界法和固體痠堿催化的酯交換反應製備得到,但各種製備方法各有優劣,均相痠堿催化法反應迅速,轉化率高但存在後續處理複雜,汙染嚴重等問題;脂肪酶催化法反應條件溫和,對原料中的水和遊離脂肪痠不敏感,不需要過量的甲醇參與反應,後續處理工序簡單,但酶的成本過高,這是製約其商業化髮展的最大阻礙;超臨界法是製備生物柴油的新技術,反應迅速,不需要催化劑,油脂轉化率非常高,但其反應需要高溫高壓且能耗很大;固體痠堿催化劑腐蝕性小可以重複使用,後續分離工序簡單,對環境的遲擊較弱.其中負載型固體堿催化劑催化油脂酯交換反應將成為製備生物柴油的一箇主要髮展方嚮.
생물시유인기배경우호차가재생작위광물시유적체대연료이비수관주,생물시유주요통과균상산감최화、지방매최화、초림계법화고체산감최화적지교환반응제비득도,단각충제비방법각유우렬,균상산감최화법반응신속,전화솔고단존재후속처리복잡,오염엄중등문제;지방매최화법반응조건온화,대원료중적수화유리지방산불민감,불수요과량적갑순삼여반응,후속처리공서간단,단매적성본과고,저시제약기상업화발전적최대조애;초림계법시제비생물시유적신기술,반응신속,불수요최화제,유지전화솔비상고,단기반응수요고온고압차능모흔대;고체산감최화제부식성소가이중복사용,후속분리공서간단,대배경적충격교약.기중부재형고체감최화제최화유지지교환반응장성위제비생물시유적일개주요발전방향.
Biodiesel, an diesel alternative fuel. has attracted much attention because of its environmental benefits and renewability. Several transesterafication methods can be used to produce biodiesel, such as, homoge-neous acid/base catalysis, lipase-catalyzed reaction, supercritical method and solid acid/base catalysis. However each method has its advantages and disadvantages. Homogeneous acid/base catalysis is very fast and with high effi-ciency, but down-stream product is difficult to purify and with significant pollution; Lipase-catalyzed reaction can take place in mild conditions and do not need excess methanol. It is not sensitive to water and free fatty acids, and the down-stream process is easy. But Lipase is too expensive which blocks its commercial use. Supercritical method is a new technology that is fast, and do not need catalyst. It has high conversion efficiency, but it requires high temperature and high pressure, and so high energy consumption, therefore is not cost effective. Solid acid/base catalyst, which can be recycled, has less causticity and without pollution. The down-stream product is easy to sepa-rate, which has less impaction on the environment. Supported solid base catalysis will be the main trend for biodie-sel preparation by transesterification.
