Microchannel continuous process for synthesis of m-methyl benzoic acid

doi:10.16085/j.issn.1000-6613.2018-0471

Abstract

Abstract: At present, the research on synthesis of m-methyl benzoic acid is mainly limited to the intermittent reaction process of the oxidation vessel, and there are few reports on the continuous flow reaction process. In response to this problem, a continuous flow process for the synthesis of m-methyl benzoic acid in liquid-phase oxidation in pulsed hybrid microchannel reactors was proposed. Using m-xylene as the raw material, peracetic acid as the oxidant, cobalt acetate and sodium bromide as catalysts. Through the inspection of the reaction material ratio, the amount of catalyst, the reaction residence time, the reaction temperature and the amount of solvent, etc, the optimum process conditions were obtained. When n(m-xylene):n(peracetic acid):n(cobalt acetate):n(sodium bromide):n(acetic acid)=1:4:0.015:0.02:5, reaction temperature at 120℃, the residence time at 15min, the reaction performance was the best. The results showed that this process takes full advantage of the excellent mass and heat transfer characteristics of the microchannel continuous flow reactor, greatly shortens the reaction time, increases the reaction rate, expands the selection range of the process conditions, increases the safety factor and realizes the effective control of the oxidation reaction process.

Key words: microchannel reactor, continuous flow process, oxidation, mass transfer, heat transfer

摘要： 目前，对合成间甲基苯甲酸的研究主要局限于氧化釜的间歇反应工艺，对连续流反应工艺少有报道。针对这一问题，本文提出了在脉冲混合结构微通道反应器中液相氧化合成间甲基苯甲酸的连续流工艺。采用间二甲苯为原料，过氧乙酸为氧化剂，乙酸钴和溴化钠为催化剂，通过对反应物料比、催化剂的用量、反应停留时间、反应温度、溶剂用量等条件的考察，获得最佳工艺条件。得出当n（间二甲苯）∶n（过氧乙酸）∶n（乙酸钴）∶n（溴化钠）∶n（乙酸）=1∶4∶0.015∶0.02∶5、反应温度120℃、反应停留时间15min时，反应效果最佳。研究结果表明：此工艺充分利用微通道连续流反应器优良的传质传热特点，大大缩短了反应时间，提高了反应速率，扩大工艺条件选择区间，增加了安全系数，实现对氧化反应过程的有效控制。

关键词: 微通道反应器, 连续流, 氧化, 传质, 传热

CLC Number:

O625.51

CHENG Hao, YAN Shenghu, ZHANG Yue, LIU Jianwu, ZHANG Yongchao, SHEN Jiefa, CHEN Daixiang, WEI Jin. Microchannel continuous process for synthesis of m-methyl benzoic acid[J]. Chemical Industry and Engineering Progress, 2018, 37(11): 4168-4173.

程昊, 严生虎, 张跃, 刘建武, 张勇超, 沈介发, 陈代祥, 魏进. 合成间甲基苯甲酸的微通道连续流工艺[J]. 化工进展, 2018, 37(11): 4168-4173.

References

[1] 丁音琴, 陈天明. 驱蚊剂N,N-二乙基间甲基苯甲酰胺的合成条件[J]. 福州大学学报(自然科学版), 1999, 27(2):101-103. DING Y Q, CHEN T M. Synthesis conditions of mosquito repellent N,N-diethyl-m-methyl benzamide[J]. Journal of Fuzhou University (Natural Science), 1999, 27(2):101-103.
[2] SUN W Z, SUN J H, XU Z M, et al. Experimental study and modeling of homogenous catalytic oxidation of m-xylene to isophthalic acid[J]. Ind. Eng. Chem. Res., 2015, 54:3293-3298.
[3] 潘志彦, 林春绵. 间甲基苯甲酸的合成研究[J]. 浙江工业大学学报, 1996(2):154-159. PAN Z Y, LIN C M. Synthesis of m-methyl benzoic acid[J]. Journal of Zhejiang University of Technology, 1996(2):154-159.
[4] 钟敏, 马玉龙, 廖振宇. 液相氨氧化法一步合成间甲苯甲腈[J]. 武汉大学学报(理学版), 2004, 50(6):707-710. ZHONG M, MA Y L, LIAO Z Y. One-step synthesis of m-tolunitrile using liquid ammonia oxidation method[J]. Journal of Wuhan University (Science Edition), 2004, 50(6):707-710.
[5] 于水仙. 间二甲苯气相选择性氧化催化剂的研究[D]. 兰州:兰州大学, 2007. YU S X. Study on the gas-phase selective oxidation catalyst of m-xylene[D]. Lanzhou:Lanzhou University, 2007.
[6] 朱益民. 间甲基苯甲酸连续生产工艺:CN105061187A[P]. 2015-11-18. ZHU Y M. Continuous production process of m-methyl benzoic acid:CN105061187A[P]. 2015-11-18.
[7] 刘冠颖, 方玉诚, 郭辉进, 等. 微反应器发展概况[J]. 当代化工, 2010, 39(3):315-318. LIU G Y, FANG Y C, GUO H J, et al. Overview of the development of microreactors[J]. Contemporary Chemicals, 2010, 39(3):315-318.
[8] 严生虎, 陈代祥, 沈卫,等. 微通道反应器中苄亚甲基二氯水解制苯甲醛连续流工艺[J]. 化工进展, 2013, 32(2):299-302. YAN S H, CHEN D X, SHEN W, et al. Process for the continuous flow of benzaldehyde from benzylidene dichloride hydrolysis in microchannel reactors[J]. Chemical Industry and Engineering Progress, 2013, 32(2):299-302.
[9] 严生虎, 沈卫, 张跃, 等. 微通道反应器内乙苯连续氧化反应工艺研究[J]. 现代化工, 2012, 32(4):94-97. YAN S H, SHEN W, ZHANG Y, et al. Study on continuous oxidation of ethylbenzene in microchannel reactor[J]. Modern Chemical Industry, 2012, 32(4):94-97.
[10] 李伟, 林素琴, 肖文德. 高效液相色谱法分析间二甲苯氧化过程的产物[J]. 聚酯工业, 2004, 17(6):36-37. LI W, LIN S Q, XIAO W D. High-performance liquid chromatographic analysis of metaxylene oxidation products[J]. Polyester Industry, 2004, 17(6):36-37.
[11] 周洁. 高效液相色谱法测定间苯二甲酸残留[J]. 科技创新与应用, 2016(32):75. ZHOU J. Determination of isophthalic acid residue by high performance liquid chromatography[J]. Science, Technology and Innovation, 2016(32):75.
[12] 王忠元, 阎丽梅. 间二甲苯氧化制间甲基苯甲酸的研究[J]. 化学与粘合, 1998(2):92-94. WANG Z Y, YAN L M. Study on the oxidation of m-xylene to m-methyl benzoic acid[J]. Chemistry and Adhesives, 1998(2):92-94.

[1]	XIAO Hui, ZHANG Xianjun, LAN Zhike, WANG Suhao, WANG Sheng. Advances in flow and heat transfer research of liquid metal flowing across tube bundles [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 10-20.
[2]	SHENG Weiwu, CHENG Yongpan, CHEN Qiang, LI Xiaoting, WEI Jia, LI Linge, CHEN Xianfeng. Operating condition analysis of the microbubble and microdroplet dual-enhanced desulfurization reactor [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 142-147.
[3]	ZHAO Chen, MIAO Tianze, ZHANG Chaoyang, HONG Fangjun, WANG Dahai. Heat transfer characteristics of ethylene glycol aqueous solution in slit channel under negative pressure [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 148-157.
[4]	HUANG Yiping, LI Ting, ZHENG Longyun, QI Ao, CHEN Zhenglin, SHI Tianhao, ZHANG Xinyu, GUO Kai, HU Meng, NI Zeyu, LIU Hui, XIA Miao, ZHU Kai, LIU Chunjiang. Hydrodynamics and mass transfer characteristics of a three-stage internal loop airlift reactor [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 175-188.
[5]	YANG Hanyue, KONG Lingzhen, CHEN Jiaqing, SUN Huan, SONG Jiakai, WANG Sicheng, KONG Biao. Decarbonization performance of downflow tubular gas-liquid contactor of microbubble-type [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 197-204.
[6]	WANG Fu'an. Consumption and emission reduction of the reactor of 300kt/a propylene oxide process [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 213-218.
[7]	CHEN Kuangyin, LI Ruilan, TONG Yang, SHEN Jianhua. Structure design of gas diffusion layer in proton exchange membrane fuel cell [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 246-259.
[8]	ZHANG Mingyan, LIU Yan, ZHANG Xueting, LIU Yake, LI Congju, ZHANG Xiuling. Research progress of non-noble metal bifunctional catalysts in zinc-air batteries [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 276-286.
[9]	GAO Yufei, LU Jinfeng. Mechanism of heterogeneous catalytic ozone oxidation:A review [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 430-438.
[10]	GU Yongzheng, ZHANG Yongsheng. Dynamic behavior and kinetic model of Hg⁰ adsorption by HBr-modified fly ash [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 498-509.
[11]	SHAO Boshi, TAN Hongbo. Simulation on the enhancement of cryogenic removal of volatile organic compounds by sawtooth plate [J]. Chemical Industry and Engineering Progress, 2023, 42(S1): 84-93.
[12]	CHEN Lin, XU Peiyuan, ZHANG Xiaohui, CHEN Jie, XU Zhenjun, CHEN Jiaxiang, MI Xiaoguang, FENG Yongchang, MEI Deqing. Investigation on the LNG mixed refrigerant flow and heat transfer characteristics in coil-wounded heat exchanger (CWHE) system [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4496-4503.
[13]	ZHANG Fan, TAO Shaohui, CHEN Yushi, XIANG Shuguang. Initializing distillation column simulation based on the improved constant heat transport model [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4550-4558.
[14]	WANG Weitao, BAO Tingyu, JIANG Xulu, HE Zhenhong, WANG Kuan, YANG Yang, LIU Zhaotie. Oxidation of benzene to phenol over aldehyde-ketone resin based metal-free catalyst [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4706-4715.
[15]	GE Yafen, SUN Yu, XIAO Peng, LIU Qi, LIU Bo, SUN Chengying, GONG Yanjun. Research progress of zeolite for VOCs removal [J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4716-4730.