Journal of South China University of Technology(Natural Science) >

2025 , Vol. 53 >Issue 11: 150 - 156

DOI: https://doi.org/10.12141/j.issn.1000-565X.240368

Chemistry & Chemical Engineering

Experimental Investigation into Suspension Crystallization Refining of Coal-to-Ethylene Glycol

  • XUE Yuyuan ,
  • ZHAO Miao ,
  • ZHAO Zhitong ,
  • YUAN Dongyong ,
  • LI Gang
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  • College of Chemistry and Chemical Engineering,Taiyuan University of Technology,Taiyuan 030024,Shanxi,China
薛雨源(1992—),男,博士,副教授,主要从事低值植物资源利用和结晶分离研究。E-mail: xueyuyuan@tyut.edu.cn

Received date: 2024-07-16

  Online published: 2025-01-15

Supported by

the Natural Science Foundation of Shanxi Province for Young Scholars(20210302124465)

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Abstract

Suspension crystallization coupled with centrifugal separation can be used to refine polyester-grade coal-to-ethylene glycol. Compared with the traditional distillation purification, suspension crystallization has the advantages of low energy consumption, no need for solvents and environmental friendliness. It is particularly effective in reducing energy consumption and emissions when purifying the narrow-boiling, azeotropic and heat-sensitive systems formed by impurities and ethylene glycol during the coal-to-ethylene glycol production process. To optimize the operation process of suspension crystallization for coal-to-ethylene glycol and provide a reference for the deve-lopment of coupled centrifugal separation technology, this paper investigated the effects of seed dosage, filter cake thickness, stirring intensity, programmed cooling and mother liquid circulation operation process on the purification efficiency. The results show that seed dosage affects crystal size distribution, and that increasing the dosage may improve the product purity, with the effective distribution coefficient decreasing by 15.8%. Reducing the filter cake thickness allows for more sufficient contact between crystals and sweating gas, thus enhancing the sweating effect and resulting in a maximum reduction of 56.8% in the effective distribution coefficient. Stirring intensity directly affects mass and heat transfer. Higher stirring intensity leads to higher product purity but lower yield, with maximum decreases in the effective distribution coefficient and the yield of 39.4% and 30.8%, respectively. Programmed cooling directly affects crystallization time. A slower cooling rate prolongs the crystallization time but reduces product purity. Mother liquid recycling increases the water content in the system, reduces the degree of supercooling, and thereby improves product purity. Compared with fresh mother liquid, the mother liquid cycled for 7 times leads to an effective distribution coefficient decrease by 72.0%.

Key words: coal-to-ethylene glycol; suspension crystallization; process optimization; experimental investigation

Cite this article

XUE Yuyuan , ZHAO Miao , ZHAO Zhitong , YUAN Dongyong , LI Gang . Experimental Investigation into Suspension Crystallization Refining of Coal-to-Ethylene Glycol[J]. Journal of South China University of Technology(Natural Science), 2025 , 53(11) : 150 -156 . DOI: 10.12141/j.issn.1000-565X.240368

References

[1] 李学强,郑化安,张生军,等 .国内煤制乙二醇现状及发展建议[J].洁净煤技术201420(6):92-96.
  LI Xueqiang, ZHENG Huaan, ZHANG Shengjun,et al .Development suggestions for coal to ethylene glycol in domestic[J].Clean Coal Technology201420(6):92-96.
[2] 靳丽丽 .乙二醇合成工艺研究进展[J].煤炭与化工201841(2):35-37.
  JIN Lili .Progress on synthetic technologies of ethylene glycol[J].Coal and Chemical Industry201841(2):35-37.
[3] 杨庆,许思敏,张大伟,等 .石油与煤路线制乙二醇过程的技术经济分析[J].化工学报202071(5):2164-2172.
  YANG Qing, XU Simin, ZHANG Dawei,et al .Techno-economic analysis of oil and coal to ethylene glycol processes[J].CIESC Journal202071(5):2164-2172.
[4] 艾硕,郑明远,庞纪峰,等 .新型乙二醇合成工艺的产品精制与节能技术[J].化工进展201736(7):2344-2352.
  AI Suo, ZHENG Mingyuan, PANG Jifeng,et al .Energy-saving technologies for purification of crude ethy-lene glycol synthesized via novel pathways[J].Chemical Industry and Engineering Progress201736(7):2344-2352.
[5] 刘兴伟 .乙二醇与1,2-丁二醇的分离方法研究进展[J].现代化工201636(9):16-19,21.
  LIU Xing-wei .Advances in methods for separation of ethylene glycol and 1,2-butanediol[J].Modern Chemical Industry201636(9):16-19,21.
[6] 肖北辰 .共沸精馏分离乙二醇-1,2-丁二醇的研究[D].天津:天津大学,2019
[7] LI H, ZHAO Z, QIN J,et al .Reversible reaction-assisted intensification process for separating the azeotropic mixture of ethanediol and 1,2-butanediol: vapor-liquid equilibrium and economic evaluation[J].Industrial & Engineering Chemistry Research201857(14):5083-5092.
[8] 王铁锋 .熔融结晶法提纯煤制乙二醇的研究[D].太原:太原理工大学,2021
[9] WANG T, LI X, DONG J .Ethylene glycol purification by melt crystallization:removal of short-chain glycol impurities[J].Industrial & Engineering Chemistry Research202059(18):8805-8812.
[10] ULRICH J, NORDHOFF S .Fluidverfahrenstechnik[M].[S.1.]:Wiley,2006
[11] ZHANG Y, LI G, XUE Y,et al .Solid-liquid equilibria,density,viscosity,metastable zone width, and thermal conductivity of a binary system of ethylene glycol and 1,2-butanediol from a coal-to-ethylene glycol process[J].Journal of Chemical & Engineering Data202368(12):2989-2999.
[12] EISENBART F J, ULRICH J .Solvent-aided layer crystallization-case study glycerol-water[J].Chemical Engineering Science2015133:24-29.
[13] 张妍 .煤制乙二醇熔融结晶过程研究[D].太原:太原理工大学,2023
[14] XUE Y, LI G, ZHANG Y,et al .Refining technology for polyester-grade coal to ethylene glycol based on melt crystallization and its benefit analysis[J].Chemical Engineering Science2024297:120251/1-11.
[15] 齐亚兵,贾宏磊 .熔融结晶技术分离纯化有机化合物的研究进展[J].化工进展202342(1):373-385.
  QI Yabing, JIA Honglei .Progress on separation and purification for organic compounds by melt crystallization[J].Chemical Industry and Engineering Progress202342(1):373-385.
[16] CHOI W S, KIM K-J .Separation of acetic acid from acetic acid-water mixture by crystallization[J].Separation Science and Technology201348(7):1056-1061.
[17] TAI C Y, SHIH C-Y, JUANG W-S .Suspension crystallization of p-dichlorobenzene from the melt[J].Journal of Crystal Growth1996166(1/2/3/4):1040-1045.
[18] 白云鹤 .对二甲苯熔融结晶过程研究[D].天津:天津大学,2019
[19] YIN Y, YANG Y H, DE LOURDES MENDOZA M,et al .Progressive freezing and suspension crystallization methods for tetrahydrofuran recovery from Grignard reagent wastewater[J].Journal of Cleaner Production2017144:180-186.
[20] 景博,常泽伟,贾晟哲,等 .熔融结晶的过程强化[J].化工学报202172(8):3907-3918.
  JING Bo, CHANG Zewei, JIA Chengzhe,et al .Process intensification of melt crystallization[J].CIESC Journal202172(8):3907-3918.
[21] HASS H B, PATTERSON J A .Purification of glycerol by crystallization[J].Industrial & Engineering Che-mistry194133(5):615-616.
[22] NAGY B, SZILáGYI B, DOMOKOS A,et al .Mo-deling of pharmaceutical filtration and continuous integrated crystallization-filtration processes[J].Chemical Engineering Journal2021413:127566/1-15.
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