Study on Preparation of Acetaldoxime by Oxime Exchange

doi:10.3969/j.issn.1006-396X.2021.06.002

Abstract

Abstract:

Oxime exchange is a novel process preparing acetaldehyde oxime, but some disadvantages in the reaction process also exist, such as easily oxidized acetaldoxime by air, many azeotropes in the reaction solution, and hardly separated and purified acetaldoxime.The oxidation of acetaldehyde oxime and volatilization of acetaldehyde and butanone oxime were avoided using 0.2 MPa nitrogen as protective gas during the reaction process. The selectivity of acetaldehyde oxime is 96.12%. Moreover, an effective purification process of the product was developed. Firstly, the basic process of separation of reaction liquid by vacuum distillation was simulated by Aspen plus. The influences of pressure, plate number, reflux ratio and feed position on the separation process were investigated. According to the operating parameters of simulation, the optimum separation and purification process in actual reaction were determined. In this condition, the purity of the resulting acetaldoxime is 95.33% with the yield of 94.31%. This work could provide guidance for the industrialization of acetaldehyde oxime by oxime exchange method.

Key words: Acetaldehyde oxime, Oxime exchange method, Nitrogen, Aspen Plus simulation, Vacuum distillation

摘要：

肟交换法是一种制备乙醛肟的新兴工艺，但反应过程存在乙醛肟易被空气氧化等问题，且反应液中存在多组共沸物，分离提纯得到高纯度的乙醛肟较为困难。以丁酮肟为原料，通过向反应器内充入0.2 MPa的氮气，有效避免了乙醛肟氧化与原料乙醛、丁酮肟的挥发，乙醛肟反应选择性达96.12%。开发了产物的提纯工艺，通过Aspen Plus模拟,初步确定减压精馏分离反应液的基本流程，考察了压力、塔板数、回流比、进料位置等操作参数对分离过程的影响。在此基础上，依据模拟确定的操作参数进行实验，确定最优分离提纯工艺，得到纯度为95.33%的乙醛肟产品，收率可达94.31%。本研究可为肟交换法制备乙醛肟的工业化提供一定的指导。

关键词: 乙醛肟, 肟交换法, 氮气, Aspen Plus模拟, 减压精馏

CLC Number:

TQ224.1

Ziliang Liu, Yuying Han, Shuang Wang, Chuanxing Wang. Study on Preparation of Acetaldoxime by Oxime Exchange[J]. Journal of Petrochemical Universities, 2021, 34(6): 7-15.

刘梓良, 韩宇莹, 王双, 王传兴. 肟交换法制备乙醛肟工艺的研究[J]. 石油化工高等学校学报, 2021, 34(6): 7-15.

Figures/Tables 22

Table 1 The properties and mass fraction of each component in reaction solution

组分	质量分数/%	沸点/℃	备注
乙醛	15.84	20.8
丁酮	25.81	79.6	丁酮与水共沸，沸点73.41 ℃
水	35.59	100.0
乙醛肟	21.34	114.5	乙醛肟与水共沸，沸点95.50 ℃
丁酮肟	0.84	152.0	丁酮肟与水共沸，沸点97.92 ℃
其他	0.58	-	主要为乙腈

Fig.1 The T?xy phase diagram of acetaldoxime / water system

Fig.2 The T?xy phase diagram of butanone / water system

Fig.3 Aspen Plus simulation process

Table 2 The effect of inert gas on reaction

序号	乙醛肟选择性/%	丁酮肟转化率/%	备注
1	95.45	98.43	空气，常压
2	95.91	98.42	充氮气，常压
3	96.12	98.77	充氮气，0.2 MPa
4	96.13	98.77	充氮气，0.3 MPa

Table 3 The composition of each stream and mass fraction of each component before optimization

流股	w（乙醛）	w（丁酮)	w(水)	w(乙醛肟)	w(丁酮肟)	w(其他)
S1	98.701	0.899	0.393	0	0	0.007
S2	0.002	30.792	40.807	27.078	0.703	0.618
S3	0.006	88.181	9.804	0.327	0.005	1.677
S4	0	0	56.534	42.238	1.228	0
S5	0	0	74.625	24.110	1.265	0
S6	0	0	20.494	78.922	0.584	0
S7	0	0	25.262	74.734	0.004	0
S8	0	0	0.005	89.211	10.784	0

Fig.4 The effect of tray number on yield and mass fraction of acetaldehyde

Fig.5 The effect of feed position on the product and energy consumption of Tower 1

Fig.6 The effect of reflux ratio on yield and mass fraction of acetaldehyde

Fig.7 The effect of tray number on yield and mass fraction of butanone

Fig.8 The effect of feed position on yield and mass fraction of butanone

Fig.9 The effect of reflux ratio on yield and mass fraction of butanone

Fig.10 The effect of pressure on yield and mass fraction of butanone

Fig.11 The effect of plate number on acetaldoxime mass fraction

Fig.12 The effect of feed position on mass fraction of acetaldehyde oxime

Fig.13 The effect of reflux ratio on mass fraction of acetaldehyde oxime

Fig.14 The effect of pressure on cetaldoxime mass fraction

Fig.15 The effect of tray number on yield and mass fraction of acetaldoxime

Fig.16 The effect of feed position on yield and mass fraction of acetaldoxime

Fig.17 The effect of reflux ratio on yield and mass fraction of acetaldehyde oxime

Table 4 The composition of each stream and mass fraction of each component after optimization

流股	w（乙醛）	w（丁酮）	w（水）	w（乙醛肟）	w（丁酮肟）	w（其他）
S1	98.701	0.901	0.392	-	-	0.006
S2	0.002	30.794	40.801	27.088	0.708	0.611
S3	0.007	91.432	7.131	0.062	-	1.368
S4	-	-	57.631	41.264	1.103	0.002
S5	-	0.001	89.782	10.135	0.080	0.003
S6	-	-	3.627	93.619	2.754	-
S7		-	3.818	96.112	0.070	-
S8	-	-	0.005	53.154	46.841	-

Fig.18 The comparison results of gas chromatograms of acetaldehyde oxime products

References 16

1	杨自力，徐健，罗先福，等. 灭多威肟的合成研究［J］. 精细化工中间体， 2020， 50（3）： 26⁃29.
	Yang Z L， Xu J， Luo X F， et al. Synthesis of methomyloxime［J］. Fine Chemical Intermediates， 2020， 50（3）： 26⁃29.
2	黄静，鲍涵，徐铭，等. 2⁃（3，3⁃二甲基双环［2.2.1］庚⁃2⁃亚基）乙醛肟的合成［J］. 化学研究与应用， 2018， 30（11）： 1886⁃1891.
	Huang J， Bao H， Xu M， et al. Synthesis of 2⁃（3，3⁃dimethylbicyclo［2.2.1］heptan⁃2⁃ylidene） acetaldehyde oxime［J］. Chemical Research and Application， 2018， 30（11）： 1886⁃1891.
3	吴永璐. 乙醛肟合成方法的改进［J］. 化学与黏合， 2005 （1）： 61⁃62.
	Wu Y L. Improve on the synthesis method of acetaldoxime［J］. Chemical and Adhesion， 2005 （1）： 61⁃62.
4	Liu W. Synthesis of acetaldehyde oxime［J］. Journal of Qingdao Institute of Chemical Technology，1996，32（6）：473⁃475.
5	Ding J H， Xu L， Yu Y J， et al. Clean synthesis of acetaldehyde oxime through ammoximation on titanosilicate catalysts［J］. Catalysis Science & Technology， 2013， 3（10）： 2587⁃2595.
6	Li X， Yan W J， Zhang R， et al. Direct synthesis of nitrones via transition⁃metal⁃free ring⁃opening of N⁃tosylaziridines with the nitrogen atom of various （E）⁃aldoximes and （E）⁃ketoximes［J］. Synthesis，2019，23（4）：1423⁃1430.
7	Hideaki T， Hiro K， Shoichiro Y. Synthesis and properties of cobalt（II）， nickel（II）， and copper（II） coMPlexes with acetaldehyde oxime and benzaldehyde oxime［J］. Bulletin of the Chemical Society of Japan，1977，21（15）：452⁃456.
8	Raissi H， Yoosefian M， Mollania F. Hydrogen bond studies in substituted imino⁃acetaldehyde oxime［J］. Computational and Theoretical Chemistry， 2012， 996（9）： 68⁃75.
9	张敏生.乙醛肟合成新工艺的研究［D］. 北京：北京化工大学， 2016.
10	刘明，娄风雷，王琴，等. TS⁃1催化丙酮氨氧化合成丙酮肟工艺研究［J］. 化学推进剂与高分子材料， 2011， 9（2）： 67⁃69.
	Liu M， Lou F L， Wang Q， et al. Study on synthetic process of acetone oxime catalytic ammoxidation by TS⁃1［J］. Chemical Propellants & Polymeric Materials， 2011， 9（2）： 67⁃69.
11	卢福军. 肟的合成及其水解制备盐酸羟胺的新工艺研究［D］.青岛：青岛科技大学， 2016.
12	Jin H ， Meng C ， He G ， et al. Green synthesis of acetaldehyde oxime using ammonia oxidation in the TS⁃1/H₂O₂ system［J］. Reaction Kinetics， Mechanisms and Catalysis， 2018，4（17）：125⁃129.
13	张景玉，任立国. 环己酮1，2⁃丙二醇缩酮的催化合成［J］. 辽宁石油化工大学学报， 2009， 29（2）： 8⁃10.
	Zhang J Y， Ren L G. Catalytic synthesis of cyclohexanone 1，2⁃propanediol ketal［J］. Journal of Liaoning University of Petrochemical Technology， 2009， 29（2）： 8⁃10.
14	许越，张勇，周德瑞，等. 除氧剂乙醛肟的合成及除氧反应动力学研究［J］. 哈尔滨工业大学学报， 2001，37（2）：248⁃251.
	Xu Y， Zhang Y， Zhou D R， et al. Synthesis and reaction kinetics of acetaldoxime as water deoxidiser［J］. Journal of Harbin Institute of Technology，2001，37（2）：248⁃251.
15	张志德，陈玉琴，邹志琛.气相萃取法制备无水乙醛肟［J］.化学世界，2000，43（11）：582⁃583.
	Zhang Z D， Chen Y Q， Zou Z C. Preparation of anhydrous acetaldehyde oxime by gas phase extraction［J］. Chemical World， 2000，43（11）： 582⁃583.
16	赵治雨，仇汝臣. 减压精馏分离DEHCH和DOP模拟研究［J］. 山东化工， 2016， 45（2）： 106⁃107.
	Zhao Z Y， Qiu R C. Simulation study of separating DEHCH and DOP with vacuum distillation［J］. Shandong Chemical Industry， 2016， 45（2）： 106⁃107.

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[2]	Han Ma, Duosen Yan, Yaqi Zhu, Xiaodan Zhu, Shanshan Li. Effect of HRT on Nitrogen Removal Performance and EPS in Combined Packed SBBR [J]. Journal of Petrochemical Universities, 2023, 36(2): 27-33.
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[4]	Yin Taiheng,Zhao Ji,Tang Yongliang,et al. Experiment Study on NitrogenInjection for Controlling Bottom Water Coning [J]. Journal of Petrochemical Universities, 2017, 30(3): 50-55.
[5]	Wang Chunzhi,Li Zhaomin,Li Songyan,Li Binfei,Zhang Chao,Wang Fei. Enhancing Super Extra Heavy Oil Recovery by Using High Temperature Resistant Enhanced Foam System [J]. Journal of Petrochemical Universities, 2016, 29(1): 14-20.
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[8]	TIAN Dan,HUO Wenzhou,LYU Qinglin,et al. Purifying Technology of Succinic Acid from Product of Maleic Anhydride Hydrogenation [J]. Journal of Petrochemical Universities, 2013, 26(5): 10-14.
[9]	YANG Jihe, FU Liang. The Comparative Study on the FCC Reaction of Components Rich  in Saturated Hydrocarbons Under Different Processes [J]. Journal of Petrochemical Universities, 2013, 26(3): 18-22.
[10]	DU Mingjun,TANG Hongmei,XIONG Xinqiang,et al. Process Calculation for Nitrogen Through Ball Pigging of the Pier Offloading Pipelines [J]. Journal of Petrochemical Universities, 2013, 26(2): 71-73.
[11]	FAN Kaifeng, WANG Weiqiang， MA Yue，et al. The Numerical Simulation on Mixture Gas of Nitrogen Replacement in Natural Gas Pipeline [J]. Journal of Petrochemical Universities, 2013, 26(1): 63-67.
[12]	WEN Ping，LI Chuan, LI Shu-feng，DENG Wen-an. Research on Nitrogen Distribution in Products of Slurry-Bed Hydrocracking of Cracked Residues Recycle [J]. Journal of Petrochemical Universities, 2012, 25(3): 31-34.
[13]	LIN Sai-yan,LIU Dan,WANG Hong,et al. Removing Basic Nitrogen Compounds From Coker  Diesel by Extraction With Acidic Ionic Liquid [J]. Journal of Petrochemical Universities, 2012, 25(1): 8-12.
[14]	LI Dong-sheng,ZHANG Jian-shu,LI Xiao-ou,ZHAI Yu-chun. Complex Denitrification in Lubricant by Joining Furfural and Additives [J]. Journal of Petrochemical Universities, 2011, 24(3): 43-46.
[15]	ZHAO Bo,LI Dong-sheng,DAI Yue-ling,et al. Pretreatment of Coking Gas Oil in Dagang Tianjin [J]. Journal of Petrochemical Universities, 2011, 24(2): 69-72.