Experimental on ultrasound enhancement of para-xylene crystallization characteristics and regulation mechanism

doi:10.16085/j.issn.1000-6613.2022-1899

Abstract

Abstract:

Para-xylene(PX) is one of the most crucial aromatic raw materials in petrochemical industry. It is urgent to develop a more low-cost and efficient PX production process due to the growing demand for PX. This paper introduced ultrasound into the PX crystallization process and analyzed the data of supersolubility, metastable zone width and induction period of PX under different working conditions. Based on the classical nucleation theory and the cluster coalescence model, the PX crystallization characteristics and the mechanism of ultrasound enhancement were investigated. The results showed that ultrasound reduced the metastable zone width and induction period of PX crystallization process, speeded up the crystal nucleation rate and prevented the explosion nucleation. When the supersaturation was below 1.055, the PX nucleation mechanism was heterogeneous nucleation, and when it was above 1.055, the PX nucleation mechanism was homogeneous nucleation. The crystal growth mechanism was continuous growth. In addition to lowering the critical nucleation radius and critical nucleation free energy of PX, ultrasound also reduced the surface entropy factor and interface tension that correlated to the two nucleation mechanisms and raised the system’s diffusion coefficient. When the ultrasonic power changed from 0 to 88W, the crystal nucleation rate constant increased by 22.4 times and the diffusion coefficient by 11.86 times, respectively. This study might enable future PX crystallization process improvements.

Key words: para-xylene, crystallization, classical nucleation theory, thermodynamics, dynamics, ultrasound enhancement

摘要：

对二甲苯（PX）是石油化工中最重要的芳烃原料之一。随着对PX的需求日益增长，迫切需要开发一种成本更低、效率更高的对二甲苯生产工艺。本文将超声引入到PX结晶过程，分析了不同工况下PX的超溶解度、介稳区宽度和诱导期等数据。基于经典成核理论，探究了PX的结晶特性和超声强化PX的作用机制。结果如下：超声减小了PX结晶过程的介稳区宽度和诱导期，加快了晶体成核速率，并避免了爆发成核。当过饱和度低于1.055时，PX成核机制为非均相成核；当过饱和度高于1.055时，PX为均相成核。晶体生长机制为连续生长。超声降低了PX的临界成核半径和临界成核自由能，也降低了两种成核机制对应的界面张力和表面熵因子，同时提高了体系的扩散系数。当超声功率从0变化到88W时，晶体成核速率常数增大了22.4倍，扩散系数增大了11.86倍。所得结论可为PX结晶工艺的改进提供参考。

关键词: 对二甲苯, 结晶, 经典成核理论, 热力学, 动力学, 超声强化

CLC Number:

TQ021.4

DONG Jiayu, WANG Simin. Experimental on ultrasound enhancement of para-xylene crystallization characteristics and regulation mechanism[J]. Chemical Industry and Engineering Progress, 2023, 42(9): 4504-4513.

董佳宇, 王斯民. 超声强化对二甲苯结晶特性及调控机理实验[J]. 化工进展, 2023, 42(9): 4504-4513.

Figures/Tables 15

References 36

1	Quanming LYU, DONG Jian, HE Renchu, et al. Modeling of the Co-Mn-Br catalyzed liquid phase oxidation of p-xylene to terephthalic acid and m-xylene to isophthalic acid[J]. Chemical Engineering Science, 2021, 232: 116340.
2	FARUQUE HASAN M M, FIRST Eric L, FLOUDAS Christodoulos A. Discovery of novel zeolites and multi-zeolite processes for p-xylene separation using simulated moving bed (SMB) chromatography[J]. Chemical Engineering Science, 2017, 159: 3-17.
3	安超. 全球对二甲苯供需分析与预测[J]. 世界石油工业, 2021, 28(3): 37-43.
	AN Chao. Analysis and forecast of global p-xylene supply and demand[J]. World Petroleum Industry, 2021, 28(3): 37-43.
4	SHI Qian, GONÇALVES Jonathan C, FERREIRA Alexandre F P, et al. A review of advances in production and separation of xylene isomers[J]. Chemical Engineering and Processing-Process Intensification, 2021, 169: 108603.
5	SHIAU Lie-Ding. Purification of m-xylene from the mixed xylenes by stripping crystallization[J]. Separation and Purification Technology, 2021, 255: 117688.
6	李贵贤, 张军强, 杨勇, 等. 基于PX选择性强化的短流程甲苯甲醇甲基化PX生产新工艺[J]. 化工进展, 2022, 41(6): 2939-2947.
	LI Guixian, ZHANG Junqiang, YANG Yong, et al. A novel PX production shortcut through PX selectivity intensification in toluene and methanol methylation[J]. Chemical Industry and Engineering Progress, 2022, 41(6): 2939-2947.
7	冯培曦, 周震寰, 康承琳, 等. SKI-210催化二甲苯异构化反应的动力学研究[J]. 石油炼制与化工, 2022, 53(3): 73-78.
	FENG Peixi, ZHOU Zhenhuan, KANG Chenglin, et al. Kinetics of xylene isomerization catalyzed by SKI-210 catalyst[J]. Petroleum Processing and Petrochemicals, 2022, 53(3): 73-78.
8	沈澍, 李士雨. 熔融结晶法分离提纯对二甲苯[J]. 化工进展, 2017, 36(5): 1605-1611.
	SHEN Shu, LI Shiyu. Purification of p-xylene by melt crystallization[J]. Chemical Industry and Engineering Progress, 2017, 36(5): 1605-1611.
9	景博, 常泽伟, 贾晟哲, 等. 熔融结晶的过程强化[J]. 化工学报, 2021, 72(8): 3907-3918.
	JING Bo, CHANG Zewei, JIA Shengzhe, et al. Process intensification of melt crystallization[J]. CIESC Journal, 2021, 72(8): 3907-3918.
10	DURĎÁKOVÁ Tereza Markéta, Štěpán HOVORKA, Zdeněk HRDLIČKA, et al. Comparison of pervaporation and perstraction for the separation of p‑xylene/m‑xylene mixtures using PDMS and CTA membranes[J]. Separation and Purification Technology, 2021, 274: 118986.
11	KAUR BHANGU Sukhvir, ASHOKKUMAR Muthupandian, LEE Judy. Ultrasound assisted crystallization of paracetamol: Crystal size distribution and polymorph control[J]. Crystal Growth & Design, 2016, 16(4): 1934-1941.
12	SABNIS Sarvesh S, GOGATE Parag R. Ultrasound assisted size reduction of DADPS based on recrystallization[J]. Ultrasonics Sonochemistry, 2019, 54: 198-209.
13	SÁNCHEZ-GARCÍA Yanira I, ASHOKKUMAR Muthupandian, MASON Timothy J, et al. Influence of ultrasound frequency and power on lactose nucleation[J]. Journal of Food Engineering, 2019, 249: 34-39.
14	VISHWAKARMA Rakhi S, GOGATE Parag R. Intensified oxalic acid crystallization using ultrasonic reactors: Understanding effect of operating parameters and type of ultrasonic reactor[J]. Ultrasonics Sonochemistry, 2017, 39: 111-119.
15	DEVOS Cedric, VAN GERVEN Tom, KUHN Simon. Nucleation kinetics for primary, secondary and ultrasound-induced paracetamol crystallization[J]. CrystEngComm, 2021, 23(30): 5164-5175.
16	MAO Yafei, LI Fei, WANG Ting, et al. Enhancement of lysozyme crystallization under ultrasound field[J]. Ultrasonics Sonochemistry, 2020, 63: 104975.
17	FERREIRA Joana, OPSTEYN Jeroen, ROCHA Fernando, et al. Ultrasonic protein crystallization: Promoting nucleation in microdroplets through pulsed sonication[J]. Chemical Engineering Research and Design, 2020, 162: 249-257.
18	殷海青, 马祎明, 万旭兴, 等. 碳酸锂气液固三相反应结晶过程研究[J]. 化工学报, 2022, 73(3): 1207-1220.
	YIN Haiqing, MA Yiming, WAN Xuxing, et al. Research of lithium carbonate three-phase reactive crystallization process[J]. CIESC Journal, 2022, 73(3): 1207-1220.
19	RAMIREZ MENDOZA H, JORDENS J, VALDEZ LANCINHA PEREIRA M, et al. Effects of ultrasonic irradiation on crystallization kinetics, morphological and structural properties of zeolite FAU[J]. Ultrasonics Sonochemistry, 2020, 64: 105010.
20	陈亮, 田飞豹, 辛秀兰, 等. 核黄素超声结晶工艺优化[J]. 化工进展, 2021, 40(2): 1018-1024.
	CHEN Liang, TIAN Feibao, XIN Xiulan, et al. Optimization of ultrasonic crystallization process of riboflavin[J]. Chemical Industry and Engineering Progress, 2021, 40(2): 1018-1024.
21	ZENG Guisheng, LI Hui, LUO Shenglian, et al. Effects of ultrasonic radiation on induction period and nucleation kinetics of sodium sulfate[J]. Korean Journal of Chemical Engineering, 2014, 31(5): 807-811.
22	KASHCHIEV D, VAN ROSMALEN G M. Review: Nucleation in solutions revisited[J]. Crystal Research and Technology, 2003, 38(78): 555-574.
23	YANG Huaiyu, Michael SVÄRD, ZEGLINSKI Jacek, et al. Influence of solvent and solid-state structure on nucleation of parabens[J]. Crystal Growth & Design, 2014, 14(8): 3890-3902.
24	PANTARAKS Pareena, FLOOD Adrian E. Effect of growth rate history on current crystal growth: A second look at surface effects on crystal growth rates[J]. Crystal Growth & Design, 2005, 5(1): 365-371.
25	张旭. 吡喹酮结晶过程研究[D]. 天津: 天津大学, 2020.
	ZHANG Xu. Study on crystallization process of praziquantel[D]. Tianjin: Tianjin University, 2020.
26	张振亚. Cu-Ni体系相界面实验研究[D]. 东营: 中国石油大学(华东), 2006.
	ZHANG Zhenya. Experimental study on phase interface of Cu-Ni system[D]. Dongying: China University of Petroleum(East China), 2006.
27	MERAMANN A. Crystallization technology handbook[M]. 2nd ed. New York: Marcel Dekker, 2001.
28	JAKOB A, JOH R, ROSE C, et al. Solid-liquid equilibria in binary mixtures of organic compounds[J]. Fluid Phase Equilibria, 1995, 113(1/2): 117-126.
29	FANG Chen, TANG Weiwei, WU Songgu, et al. Ultrasound-assisted intensified crystallization of L-glutamic acid: Crystal nucleation and polymorph transformation[J]. Ultrasonics Sonochemistry, 2020, 68: 105227.
30	赵丹洋. 吡氟草胺结晶成核和生长研究[D]. 哈尔滨: 哈尔滨工业大学, 2019.
	ZHAO Danyang. Crystal nucleation and growth of diflufenican[D]. Harbin: Harbin Institute of Technology, 2019.
31	陈霞. 超声波对硫酸钠溶液结晶影响的研究[D]. 天津: 天津大学, 2008.
	CHEN Xia. Investigation on the crystallization of Na₂SO₄ under ultrasound[D]. Tianjin: Tianjin University, 2008.
32	王美凤. 高压和低温下氢键有机晶体的结构相变研究[D]. 秦皇岛: 燕山大学, 2019.
	WANG Meifeng. Study on structural phase transition of hydrogen-bonded organic crystals at high pressure and low temperature[D]. Qinhuangdao: Yanshan University, 2019.
33	KULDIPKUMAR Anuj, KWON Glen S, ZHANG Geoff G Z. Determining the growth mechanism of tolazamide by induction time measurement[J]. Crystal Growth & Design, 2007, 7(2): 234-242.
34	FLINT Edward B, SUSLICK Kenneth S. The temperature of cavitation[J]. Science, 1991, 253(5026): 1397-1399.
35	ZEIGER Brad W, SUSLICK Kenneth S. Sonofragmentation of molecular crystals[J]. Journal of the American Chemical Society, 2011, 133(37): 14530-14533.
36	KASHCHIEV Dimo, BORISSOVA Antonia, HAMMOND Robert B, et al. Effect of cooling rate on the critical undercooling for crystallization[J]. Journal of Crystal Growth, 2010, 312(5): 698-704.

表面熵因子f	生长机理	表面特性
f＜3	连续型生长	表面粗糙
3＜f＜5	二维扩散型生长	表面较光滑
f＞5	螺旋位错型生长	表面光滑

表面熵因子f	生长机理	表面特性
f＜3	连续型生长	表面粗糙
3＜f＜5	二维扩散型生长	表面较光滑
f＞5	螺旋位错型生长	表面光滑

过饱和度	超声功率
过饱和度	0	44W	66W	88W
1.04	560	456	446	437
1.05	291	237	232	227
1.06	171	139	136	133
1.07	109	89	87	85
1.08	74	60	59	58

过饱和度	超声功率
过饱和度	0	44W	66W	88W
1.04	560	456	446	437
1.05	291	237	232	227
1.06	171	139	136	133
1.07	109	89	87	85
1.08	74	60	59	58

功率/W	均相成核界面张力/mJ·m^-2	异相成核界面张力/mJ·m^-2
0	1.032	0.517
44	0.964	0.511
66	0.957	0.507
88	0.950	0.481