Catalytic conversion of glucose to levulinic acid by solid heteropolyacid salts

doi:10.3969/j.issn.0438-1157.2012.12.020

CIESC Journal ›› 2012, Vol. 63 ›› Issue (12): 3875-3881.DOI: 10.3969/j.issn.0438-1157.2012.12.020

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Catalytic conversion of glucose to levulinic acid by solid heteropolyacid salts

ZENG Shanshan¹, LIN Lu^1,2, LIU Di¹, PENG Lincai¹

1. State Key Laboratory of Pulp and Paper Engineering, South China University of Technology, Guangzhou 510640, Guangdong, China;
2. Research Institute of Energy, Xiamen University, Xiamen 361005, Fujian, China

Received:2012-04-12 Revised:2012-07-11 Online:2012-07-17 Published:2012-12-05
Supported by:
supported by the National Basic Research Program of China(2010CB732201)and the National Natural Science Foundation of China(U0733001,50776035).

磷钨酸盐催化转化葡萄糖合成乙酰丙酸

曾珊珊¹, 林鹿^1,2, 刘娣¹, 彭林才¹

1. 华南理工大学制浆造纸工程国家重点实验室, 广东广州 510640;
2. 厦门大学能源研究院, 福建厦门 361005

通讯作者: 林鹿
作者简介:曾珊珊(1987-),女,硕士研究生。
基金资助:
国家重点基础研究发展计划项目(2010CB732201);国家自然科学基金项目(U0733001,50776035)。

Abstract

Abstract: A series of metal-modified heteropolyacid salt catalysts(M_XH_3-2XPW₁₂O₄₀,M=Zn,Cu,Cs,Ag)were prepared,and the solid heteropolyacid salt Ag₃W₁₂O₄₀ was used in hydrolysis of glucose to produce levulinic acid.The surface structures of different heteropolyacid salt catalysts were characterized by means of FTIR,XRD.The surface structures and element relative mass content change of the fresh and used Ag₃W₁₂O₄₀ catalyst were also analyzed by means of FTIR,XRD,SEM and EPMA.The effects of such factors as reaction temperature,reaction time,amount of catalyst and glucose concentration on the yield of levulinic acid were investigated.Experimental results showed that the M_XH_3-2XPW₁₂O₄₀ heteropolyacid salt catalysts kept primary Keggin structure,and Ag₃W₁₂O₄₀ catalyst had the structure of Keggin after reuse for several times.It was found that the highest yield of levulinic acid was 81.61%(mole) under the conditions of reaction temperature 200℃,reaction time 2 h,Ag₃PW₁₂O₄₀ catalyst dosage 0.7 g and glucose concentration 40 g·L^-1.The catalyst could be used repeatedly.

Key words: levulinic acid, glucose, solid heteropolyacid salt, catalysis

摘要： 制备了一系列金属离子修饰的磷钨酸盐(M_XH_3-2XPW₁₂O₄₀,M=Zn,Cu,Cs,Ag)催化剂,并将磷钨酸银盐(Ag₃PW₁₂O₄₀)用于水解葡萄糖制备乙酰丙酸的实验中。采用FTIR、XRD、SEM和EPMA等技术对磷钨酸盐性能进行了表征,并分析了磷钨酸银盐催化剂在反应前后结构和表面元素相对含量的变化。考察了反应温度、反应时间、催化剂用量和葡萄糖浓度等对乙酰丙酸得率的影响。结果表明:合成的磷钨酸盐具有磷钨酸的Keggin结构,并且Ag₃PW₁₂O₄₀催化剂在多次使用后Keggin结构没有被破坏。在催化合成反应中,在反应温度200℃、反应时间2 h、Ag₃PW₁₂O₄₀催化剂用量0.7 g和葡萄糖浓度40 g·L^-1的条件下,乙酰丙酸的最大得率可达到81.61%,催化剂可重复利用。

关键词: 乙酰丙酸, 葡萄糖, 磷钨酸盐, 催化

CLC Number:

TQ032.41

ZENG Shanshan, LIN Lu, LIU Di, PENG Lincai. Catalytic conversion of glucose to levulinic acid by solid heteropolyacid salts[J]. CIESC Journal, 2012, 63(12): 3875-3881.

曾珊珊, 林鹿, 刘娣, 彭林才. 磷钨酸盐催化转化葡萄糖合成乙酰丙酸[J]. 化工学报, 2012, 63(12): 3875-3881.

References 18

[1]	Girisuta B,Danon B,Manurung R,Janssen L P B M,Heeres H J.Experimental and kinetic modelling studies on the acid-catalysed hydrolysis of the water hyacinth plant to levulinic acid[J].Bioresour. Technol.,2008,99:8367-8375
[2]	Bozell J J,Moens L,Elliott D C,Wang Y,Fitzpatrick S W,Bilski R J,Jarnefeld J L.Production of levulinic acid and use as a platform chemical for derived products[J].Resour. Conserv. Recy.,2000,28:227-239
[3]	Cha J Y,Hanna M A.Levulinic acid production based on extrusion and pressurized batch reaction[J].Industrial Crop Sand Products,2002,16(2):109-118
[4]	Girsuta B,Janssen L P B M,Hceres H J.A kinetic study on the conversion of glucose to levulinic acid[J].Chemical Engineering Research and Design,2006,84(A5):339-349
[5]	Lü Xiuyang(吕秀阳),Peng Xinwen(彭新文),Lu Chongbing(卢崇兵),Jing Qi(荆琪).Decomposition kinetics of hexose catalyzed by strong acidic resins[J].CIESC Journal(化工学报),2009,60(3):634-640
[6]	Haber J,Pamn K,Matachowski L,Napruszewska,Poltowica J.Potassium and silver salts of tungstophosphoric acid as catalysts in dehydration of ethanol and hydration of ethylene[J].Journal of Catalysis,2002,207(2):296-306
[7]	Zhao Qian,Wang Lei,Zhao Shun,Wang Xiaohong,Wang Shentian.High selective production of 5-hydroymethylfurfural from fructose by a solid heteropolyacid catalyst[J].Fuel,2011,90:2289-2293
[8]	Fan Chuanyan,Guan Hongyu,Zhang Hang,Wang Jianghua,Wang Shentian,Wang xiaohong.Conversion of fructose and glucose into 5-hydroxymethylfurfural catalyzed by a solid heteropolyacid salt[J].Biomass and Bioenergy,2011,35(7):2659-2665
[9]	Shi Jiehua(施介华),Li Xiang(李祥),Zhou Liang(周亮).Application of transition metal-modified phosphotungstate catalysts in friedel-crafts acetylation[J].Petrochemical Technology(石油化工),2010,39(12):1354-1359
[10]	Chang Chun(常春),Ma Xiaojian(马晓键),Cen Peilin(岑沛霖).Technology for production of levulinic acid as new platform chemical from wheat straw[J].Transactions of the Chinese Society of Agricultural Engineering(农业工程学报),2006,22(6):161-164
[11]	Li Feng,He Jing,Du Yibo,et al.Study on layered structure intercalation and catalytic performance of zirconium sulfate tetrahydrate[J].Chinese Journal of Catalysis,1998,19(6):583-587
[12]	Wang Chunying(王春英),Wang Pan(王攀),Qi Xinhua(漆新华),Zhuang Yuanyi(庄源益).Preparation of levulinic acid from sucrose over solid acid catalyst[J].Industrial Catalysis(工业催化),2009,17(4):50-53
[13]	Liu Jingyan(刘京燕).Modification of catalyst supported phosphotungstic acid and characterization of its acidic catalysis performance[D].Beijing:China University of Petroleum,2009
[14]	Kang Shijie(亢世杰).The preparation and characterization and applied research of phosphotungstate catalyst[D].Harbin:Harbin Engineering University,2007
[15]	Zhang Zhihong(张治宏),Wang Xiaochang(王晓昌),Chang Zhemin(常哲敏),Lü Sujuan(吕素娟).Synthesis characterization of Ni-Mo-Zr heteropoly salt with Keggin structure and its ultrasonic degradation efficiency[J].Chinese Journal of Applied Chemistry(应用化学),2009,26(11):1324-1327
[16]	Wang Jing(王静),Liu Yajun(刘亚君),Cai Xingwei(蔡星伟).Synthesis and characterization of Keggin structure polyoxometalate particles[J].Chemistry(化学通报),2008,71(11):868
[17]	Wang Rui(王锐),Jiang Heng(姜恒).Synthesis,characterization and catalytic activity in the tetrahydropyranylation reaction of phosphotungstates[J].China Tungsten Industry(中国钨业),2008,23(3):28-30
[18]	Sui Xiaoyu(隋小玉),Lin Lu(林鹿).Clean conversion of glucose to levulinic acid catalyzed by ZSM-5[J].Chemical Reaction Engineering and Technology(化学反应工程与工艺),2010,26(1):74-78

Catalytic conversion of glucose to levulinic acid by solid heteropolyacid salts

磷钨酸盐催化转化葡萄糖合成乙酰丙酸

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