Progress in preparation of methyl methacrylate by ethylene route

doi:10.16085/j.issn.1000-6613.2018-0839

Abstract

Abstract:

Methyl methacrylate (MMA) is an important raw material in organic industry. It is widely used in the production of organic glass (PMMA), plastic modifier and surface coating and so on. It has a very broad development prospect and many synthetic routes have been adopted for its production. This paper reviews the development of the ethylene route for the preparation MMA. Ethylene is used as the starting material the intermediates such as propionaldehyde, propionic acid and methyl propionate may be obtained through the carboxylation reaction. Therefore, there are three routes to prepare MMA by the aldol condensation reaction based on these intermediates, and their development trend is also summarized. The aldol condensation reaction of these intermediates with formaldehyde is the key step of ethylene route, so the research status of aldol condensation reaction and its catalysts are emphasized in this paper. At present, V, Si, P based acid catalysts and K, Cs based basic catalysts are often used in the gas phase catalytic aldol condensation reaction. Among them, the Cs-based catalysts are the most widely studied. The activity, selectivity, stability of the catalysts are affected by the supports, promoters, preparations and process conditions. To improve the performance of the catalysts, it is necessary to strengthen the basic researches on the mechanism for aldol condensation reaction, and the acid-base composite catalysts are also the key research direction in the future.

Key words: methyl methacrylate, ethylene, aldol condensation, catalyst

摘要：

甲基丙烯酸甲酯（MMA）是一种重要的基础有机化工原料，主要用于生产有机玻璃、塑料改性剂及表面涂料等诸多行业，具有非常广阔的发展前景，MMA 合成路线众多。本文综述了以乙烯为起始原料，经过羰基化反应制备丙醛、丙酸和丙酸甲酯等中间产物，然后经羟醛缩合反应制备MMA的研究进展。概述了乙烯制备MMA的3条工艺路线及其发展趋势，指出中间产物与甲醛的缩合反应是乙烯路线的关键步骤，重点介绍了羟醛缩合反应及其催化剂的研究现状。目前用于气相催化羟醛缩合反应的催化剂主要有V、Si、P酸性催化剂和K、Cs碱性催化剂，其中以Cs为主活性组分的碱性催化剂研究最为广泛，载体种类、助剂、制备方法、反应条件等对催化剂的活性、选择性和寿命等具有较大影响。为进一步改善催化剂的性能，需加强对羟醛缩合反应催化机理的研究，具有酸碱两性的复合催化剂是今后重点研究方向。

关键词: 甲基丙烯酸甲酯, 乙烯, 羟醛缩合, 催化剂

CLC Number:

TQ032.4

Bin LI, Ming XIE, Xiang QI, Le ZHANG, Guangyuan WANG, Lihong SHEN, Bo WANG. Progress in preparation of methyl methacrylate by ethylene route[J]. Chemical Industry and Engineering Progress, 2019, 38(04): 1739-1745.

李斌, 解铭, 齐翔, 张乐, 王光远, 申利红, 王博. 乙烯路线制备甲基丙烯酸甲酯研究进展[J]. 化工进展, 2019, 38(04): 1739-1745.

Figures/Tables 3

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研究者	催化剂	酸醛摩尔比	转化率/%		选择性/%		收率/%
研究者	催化剂	酸醛摩尔比	PA	HCHO	PA	HCHO	PA	HCHO
Mamoru^[19]	V₂O₂ (P₂O₇)	2∶1		50.0		78.0		39.0
Mamoru^[20]	V/Si₈/P_2.2	2∶1		70.7		82.0		58.0
Spivey等^[21]	Nb₂O₅/SiO₂	5∶1						71.0
Mamoru等^[22]	Sn/Si₈/P_2.3	2∶1		68.6		69		47.2
Pearson^[23]	KOH/SiO₂	4.5∶1		72.0		78.0		56.0
Bailey等^[24]	CsOH/SiO₂	3∶2	30.0		89.0			27.0
Yoo^[25]	Cs/Bi/SiO₂	3∶2	32.3		89.4		28.8
Montag等^[26]	Cs/SiO₂-SnO₂	3∶2	39.0		91.0		35.5
Mitsubish^[27]	Si-Cs-W-Ag-O	2∶1	40.5		98.8		40.0
Tai等^[28]	Cs/SiO₂	3∶2	12.9		96.0		12.4

研究者	催化剂	酸醛摩尔比	转化率/%		选择性/%		收率/%
研究者	催化剂	酸醛摩尔比	PA	HCHO	PA	HCHO	PA	HCHO
Mamoru^[19]	V₂O₂ (P₂O₇)	2∶1		50.0		78.0		39.0
Mamoru^[20]	V/Si₈/P_2.2	2∶1		70.7		82.0		58.0
Spivey等^[21]	Nb₂O₅/SiO₂	5∶1						71.0
Mamoru等^[22]	Sn/Si₈/P_2.3	2∶1		68.6		69		47.2
Pearson^[23]	KOH/SiO₂	4.5∶1		72.0		78.0		56.0
Bailey等^[24]	CsOH/SiO₂	3∶2	30.0		89.0			27.0
Yoo^[25]	Cs/Bi/SiO₂	3∶2	32.3		89.4		28.8
Montag等^[26]	Cs/SiO₂-SnO₂	3∶2	39.0		91.0		35.5
Mitsubish^[27]	Si-Cs-W-Ag-O	2∶1	40.5		98.8		40.0
Tai等^[28]	Cs/SiO₂	3∶2	12.9		96.0		12.4

开发者	催化剂	酯醛摩尔比	转化率/%		选择性/%		收率/%
开发者	催化剂	酯醛摩尔比	MP	HCHO	MP	HCHO	MP	HCHO
Giancarlo等^[29]	Ta₂O₅/SiO₂	6∶1	7.1		39.8		5.1
Mamoru^[19]	V₂O₂ (P₂O₇)	2∶1		29.5		86.4		25.5
Mamoru^[20]	VSi₈P_2.8	2∶1		51.7		81.2		42.0
Pearson^[23]	Cs₂CO₃/SiO₂	4.5∶1		67.1		92.0		61.6
Mamoru^[20]	CsOH/SiO₂	5∶1	14.0		91.5		12.8
冯裕发等^[30]	K/γ-Al₂O₃	1∶1	51.5		76.1		39.2
Li等^[31]	Zr-Mg-Cs/ SiO₂	1∶1	18.0		88.0		15.8
Li等^[32]	Zr-Fe-Cs/SBA-15	1∶1	26.0		93.0		24.2
Wang等^[33]	La-Cs/SBA-15	1∶1	29.2		90.4		26.4

开发者	催化剂	酯醛摩尔比	转化率/%		选择性/%		收率/%
开发者	催化剂	酯醛摩尔比	MP	HCHO	MP	HCHO	MP	HCHO
Giancarlo等^[29]	Ta₂O₅/SiO₂	6∶1	7.1		39.8		5.1
Mamoru^[19]	V₂O₂ (P₂O₇)	2∶1		29.5		86.4		25.5
Mamoru^[20]	VSi₈P_2.8	2∶1		51.7		81.2		42.0
Pearson^[23]	Cs₂CO₃/SiO₂	4.5∶1		67.1		92.0		61.6
Mamoru^[20]	CsOH/SiO₂	5∶1	14.0		91.5		12.8
冯裕发等^[30]	K/γ-Al₂O₃	1∶1	51.5		76.1		39.2
Li等^[31]	Zr-Mg-Cs/ SiO₂	1∶1	18.0		88.0		15.8
Li等^[32]	Zr-Fe-Cs/SBA-15	1∶1	26.0		93.0		24.2
Wang等^[33]	La-Cs/SBA-15	1∶1	29.2		90.4		26.4

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