高校化学工程学报
高校化學工程學報
고교화학공정학보
JOURNAL OF CHEMICAL ENGINEERING OF CHINESE UNIVERSITIES
2013年
2期
236-242
,共7页
玉米芯%纤维素酶%糖化水解%还原糖得率
玉米芯%纖維素酶%糖化水解%還原糖得率
옥미심%섬유소매%당화수해%환원당득솔
corn cob%cellulose enzyme%enzymatic hydration%fermentation sugar yield
生物燃料将成为主要新能源之一,以玉米芯为原料,碱氧和稀酸为处理剂对其进行2步法预处理,使原料中纤维素相对含量增加,以提供转化乙醇的纤维素原料.采用扫描电镜表征2步法预处理玉米芯,其表面形成疏松、沟纹和孔洞形态,这有利于酶解.采用瑞氏木霉生产的纤维素酶水解该预处理玉米芯,利用正交实验得到酶水解优化条件为,酶用量75 FPU?g?1,底物质量浓度60 g?L?1,pH值4.8,反应温度50℃,还原糖得率可达69.3%.为提高纤维素酶中β-葡聚糖酶的酶活效率,并减少产物葡萄糖对β-葡聚糖酶的抑制作用,进一步优化β-葡聚糖酶加量.结果表明,当β-葡聚糖酶加量达6.5 CBU时,还原糖得率显著提高到78.2%.这表明该预处理玉米芯是有效降解的玉米芯原料,适于提高还原糖得率.
生物燃料將成為主要新能源之一,以玉米芯為原料,堿氧和稀痠為處理劑對其進行2步法預處理,使原料中纖維素相對含量增加,以提供轉化乙醇的纖維素原料.採用掃描電鏡錶徵2步法預處理玉米芯,其錶麵形成疏鬆、溝紋和孔洞形態,這有利于酶解.採用瑞氏木黴生產的纖維素酶水解該預處理玉米芯,利用正交實驗得到酶水解優化條件為,酶用量75 FPU?g?1,底物質量濃度60 g?L?1,pH值4.8,反應溫度50℃,還原糖得率可達69.3%.為提高纖維素酶中β-葡聚糖酶的酶活效率,併減少產物葡萄糖對β-葡聚糖酶的抑製作用,進一步優化β-葡聚糖酶加量.結果錶明,噹β-葡聚糖酶加量達6.5 CBU時,還原糖得率顯著提高到78.2%.這錶明該預處理玉米芯是有效降解的玉米芯原料,適于提高還原糖得率.
생물연료장성위주요신능원지일,이옥미심위원료,감양화희산위처리제대기진행2보법예처리,사원료중섬유소상대함량증가,이제공전화을순적섬유소원료.채용소묘전경표정2보법예처리옥미심,기표면형성소송、구문화공동형태,저유리우매해.채용서씨목매생산적섬유소매수해해예처리옥미심,이용정교실험득도매수해우화조건위,매용량75 FPU?g?1,저물질량농도60 g?L?1,pH치4.8,반응온도50℃,환원당득솔가체69.3%.위제고섬유소매중β-포취당매적매활효솔,병감소산물포도당대β-포취당매적억제작용,진일보우화β-포취당매가량.결과표명,당β-포취당매가량체6.5 CBU시,환원당득솔현저제고도78.2%.저표명해예처리옥미심시유효강해적옥미심원료,괄우제고환원당득솔.
Bio-fuel has become one of the most important sustainable energies. In this paper, corn cob was pretreated with two-step method including alkaline/oxidative and dilute sulphuric acid pretreatment process. This pretreatment has increased the content of cellulose, and provided the material of ethanol production. SEM shows that the surface of pretreated corn cob has porous morphology, which is benefit for enzymatic hydrolyzation. The pretreated corn cob was hydrolyzed by the cellulase produced from Trichodema reesei. Factors of enzyme dosage, pulp concentration, reaction temperature and pH value on its hydration behavior were investigated. The conditions optimized by orthogonal experiments are as follows: enzyme dosage is 75 FPU?g?1, pulp concentration is 60 g?L?1, pH value is 4.8, reaction temperature is 50℃. Under above conditions, the enzymatic hydrolyzation yield is 69.3%. Addition of β-glucosidase to enzymatic hydrolyzation of various lignocellulosic substrates can enhance its hydrolyzation efficiency and decreased the inhibitory effect of glucose onβ-glucosidase. Furthermore, asβ-glucosidase was added to enzymatic hydrolyzation of pretreated corn cob, the cellulose enzymatic hydrolyzation yield was enhanced to 78.2% when the added β- glucosidase dosage is 6.5 CBU. These results prove that the proposed two-step method is effective on corn cob conversion to ethanol.
