Ultrasonic-microwave assisted citric acid catalytic hydrolysis of cellulose

Abstract

Abstract: Using citric acid as catalyst，straw cellulose was hydrolyzed by ultrasonic-microwave assisted technique. The influence of acid concentration，ultrasonic treatment time and microwave heating time was discussed with reducing sugar yield as index. On the basis of single factor test，the results were analyzed through orthogonal test of three factors with three levels. The highest yield of reducing sugar obtained was up to 64.46%，when citric acid concentration was 20%，ultrasonic treatment time and microwave heating time were 120min and 30min，and microwave power was 500W. IR characterization showed that hydrolysis residue still existed in the form of cellulose and could be re-hydrolyzed to increase the utilization rate of raw materials.

Key words: citric acid, ultrasonic, microwave, cellulose, hydrolysis

摘要： 以柠檬酸为催化剂，采用超声波-微波相结合的辅助手法对自制稻草纤维素进行了水解研究。以还原糖得率为指标，在单因素试验的基础上，通过3因素3水平的正交试验考察了酸浓度、超声波处理时间和微波加热时间对指标的影响。对实验结果进行了极差分析和方差分析，结果表明，最佳反应条件为：柠檬酸浓度20%、超声波处理90 min、微波500 W加热30 min，此时还原糖得率最高，达64.46%。对稻草纤维素原料和水解残渣进行了红外表征，结果显示，水解残渣仍以纤维素的形式存在，可重新水解，提高原料利用率。

关键词: 柠檬酸, 超声波, 微波, 稻草纤维素, 水解

WANG Xia，WU Yu’e，YAN Jie，CHEN Shixue. Ultrasonic-microwave assisted citric acid catalytic hydrolysis of cellulose[J]. Chemical Industry and Engineering Progree.

王霞，吴玉娥，颜洁，陈仕学. 超声波-微波辅助柠檬酸催化纤维素水解条件[J]. 化工进展.

[1]	LI You, WU Yue, ZHONG Yu, LIN Qixuan, REN Junli. Pretreatment of wheat straw with acidic molten salt hydrate for xylose production and its effect on enzymatic hydrolysis efficiency [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4974-4983.
[2]	WANG Darui, SUN Hongmin, XUE Mingwei, WANG Yiyan, LIU Wei, YANG Weimin. Efficient synthesis of fully crystalline ZSM-5 zeolite catalyst by microwave method and its catalytic performance [J]. Chemical Industry and Engineering Progress, 2023, 42(7): 3582-3588.
[3]	WANG Jiuheng, RONG Nai, LIU Kaiwei, HAN Long, SHUI Taotao, WU Yan, MU Zhengyong, LIAO Xuqing, MENG Wenjia. Enhanced CO₂ capture performance and strength of cellulose-templated CaO-based pellets with steam reactivation [J]. Chemical Industry and Engineering Progress, 2023, 42(6): 3217-3225.
[4]	WANG Guangyu, MENG Jinghui, ZHANG Kai. Simulation of intermittent microwave drying of coal slime and dielectric properties [J]. Chemical Industry and Engineering Progress, 2023, 42(4): 1779-1786.
[5]	XIE Yingchun, WANG Qianqian, MA Yongli, SUN Guoqiang, LIU Mingyan. Ultrasonic and ultraviolet coupling degassing and sterilization [J]. Chemical Industry and Engineering Progress, 2023, 42(3): 1629-1637.
[6]	TANG Chunxia, LI Meng, WANG Yuxi, ZONG Yongzhong, FU Shaohai. Progress in structural design of functionalized cellulose nanomaterials for Cr(Ⅵ) removal [J]. Chemical Industry and Engineering Progress, 2023, 42(2): 585-594.
[7]	LI Dongxian, WANG Jia, JIANG Jianchun. Producing aliphatic acids via pressurized hydrolysis of soapstock assisted by ultrasound [J]. Chemical Industry and Engineering Progress, 2023, 42(1): 409-416.
[8]	SUN Peiqin, CHEN Yanqing, KONG Xiangbei, JIN Manping, LIU Fufang. Application of acetic anhydride and water in the confirmation of chemical reaction calorimetry [J]. Chemical Industry and Engineering Progress, 2022, 41(S1): 91-96.
[9]	LIU Nan, HU Yiming, YANG Ying, LI Hongjin, GAO Zhuqing, HAO Xiuli. Microwave assisted co-pyrolysis of waste polypropylene /activated carbon to produce combustible pyrolysis gas and light pyrolysis oil [J]. Chemical Industry and Engineering Progress, 2022, 41(S1): 150-159.
[10]	HUANG Yuefeng, MA Lisha, ZHANG Lili, WANG Zhiguo. Research progress on functional application of lignocellulose composite biomass film materials [J]. Chemical Industry and Engineering Progress, 2022, 41(9): 4840-4854.
[11]	LIU Chang, LI Yubao, ZUO Yi, LI Jidong. Compare and analysis on different loading methods of hydroxyapatite loaded baicalin [J]. Chemical Industry and Engineering Progress, 2022, 41(9): 4995-5002.
[12]	YANG Chengyu, LIU Min, YUAN Lin, HU Xuan, CHEN Ying. Adsorption of low-concentration phosphorus after cross-linked modification of bamboo-based cellulose nanofibrils [J]. Chemical Industry and Engineering Progress, 2022, 41(9): 5074-5084.
[13]	HAN Mingyang, QIAO Hui, FU Jiaming, MA Zewen, WANG Yan, OUYANG Jia. Research progress of non-aqueous solvents on the pretreatment of lignocellulose [J]. Chemical Industry and Engineering Progress, 2022, 41(8): 4086-4097.
[14]	ZHAN Xun, CHEN Jian, YANG Zhaozhe, WU Guomin, KONG Zhenwu, SHEN Kuizhong. Progress on superhydrophobic materials from nanocellulose [J]. Chemical Industry and Engineering Progress, 2022, 41(8): 4303-4313.
[15]	QIU Yijuan, LIN Jiawei, QIN Jirui, WU Jiayin, LIN Fengcai, LU Beili, TANG Lirong, HUANG Biao. Double dynamic covalent bond crosslinked nano-cellulose conductive hydrogel for a flexible sensor [J]. Chemical Industry and Engineering Progress, 2022, 41(8): 4406-4416.

Ultrasonic-microwave assisted citric acid catalytic hydrolysis of cellulose

超声波-微波辅助柠檬酸催化纤维素水解条件

Knowledge

Abstract

Cite this article

share this article

References

Related Articles 15

Recommended Articles

Metrics

Comments