Technical-economic evaluation for different separation strategies of xylene isomers

doi:10.16085/j.issn.1000-6613.2025-0154

Abstract

Abstract:

Xylene isomer are crucial chemical intermediates, but traditional production methods and yield increasing strategies result in significant differences in isomer content. The content of para-xylene (PX) can be changed from the thermodynamic equilibrium (about 23.8%) to more than 90%, which poses a great challenge for low-carbon and efficient separation strategies. Addressing variations in isomer content from different process sources, this paper focuses on the separation efficiency, energy consumption, and techno-economic feasibility of three separation strategies such as simulated moving bed (SMB) adsorption, cryogenic crystallization and reactive distillation. As the PX content in xylene isomers increases to over 90% from thermodynamic equilibrium compositions, the energy consumption, equipment costs, and utility requirements of the SMB adsorption process significantly increase, leading to decreased economic viability. Conversely, reactive distillation and cryogenic crystallization processes exhibit opposite trends. SMB adsorption demonstrates significant techno-economic feasibility when PX content is low, whereas reactive distillation achieves higher separation efficiency at higher PX contents. Cryogenic crystallization shows lower energy consumption and superior techno-economic performance when PX content ranges among 45.49%—72.57%.

Key words: xylene isomer, simulated moving bed adsorption, cryogenic crystallization, reactive distillation, technical-economic evaluation

摘要：

二甲苯异构体是重要的化工中间体产品，但传统生产方法和增产技术获得的异构体含量差异较大，对二甲苯（PX）的含量可由热力学平衡组成（约23.8%）上升至90%以上，对低碳高效的分离策略提出了巨大挑战。针对不同工艺来源二甲苯异构体含量差异，重点探究模拟移动床吸附、深冷结晶、反应精馏3种分离策略的分离效率、能耗和技术经济性，对3种分离策略的关键因素进行灵敏度分析。结果表明，当异构体中PX含量由热力学平衡组成增加至90%以上时，模拟移动床分离效率先降低后增加，过程能耗、设备成本和公用工程都在显著增加，经济性逐渐变差；而反应精馏和结晶分离的分离效率逐渐升高，能耗降低、经济性增加。当二甲苯异构体中PX含量较低时，模拟移动床具有显著的技术经济性；PX含量较高时，反应精馏分离效率较高；当PX含量位于45.49%~72.57%时，结晶分离工艺具有较低的能耗和较优的技术经济性。

关键词: 二甲苯异构体, 模拟移动床吸附, 深冷结晶, 反应精馏, 技术经济评价

CLC Number:

TQ028.2

YANG Yong, ZHANG Zhao, WANG Dongliang, ZHOU Huairong, ZHAO Zihao, LI Yukun. Technical-economic evaluation for different separation strategies of xylene isomers[J]. Chemical Industry and Engineering Progress, 2025, 44(8): 4732-4740.

杨勇, 张钊, 王东亮, 周怀荣, 赵子豪, 李煜坤. 二甲苯异构体不同分离策略的技术经济评价[J]. 化工进展, 2025, 44(8): 4732-4740.

Figures/Tables 13

References 37

[4]	MINCEVA Mirjana, GOMES Pedro Sá, MESHKO Vera, et al. Simulated moving bed reactor for isomerization and separation of p-xylene[J]. Chemical Engineering Journal, 2008, 140(1/2/3): 305-323.
[5]	GONÇALVES Jonathan C, FARIA Rui P V, FERREIRA Alexandre F P, et al. Optimization of a simulated moving bed unit within an existing and revamped aromatics complex with crystallization and toluene methylation units[J]. Industrial & Engineering Chemistry Research, 2020, 59(25): 11570-11581.
[6]	刘莹, 郑芳, 杨启炜, 等. 二甲苯异构体吸附分离研究进展[J]. 化工学报, 2024, 75(4): 1081-1095.
	LIU Ying, ZHENG Fang, YANG Qiwei, et al. Recent progress in adsorption and separation of xylene isomers[J]. CIESC Journal, 2024, 75(4): 1081-1095.
[7]	ASHRAF Muhammad Tahir, CHEBBI Rachid, DARWISH Naif A. Process of p-xylene production by highly selective methylation of toluene[J]. Industrial & Engineering Chemistry Research, 2013, 52(38): 13730-13737.
[8]	SAITO Shozaburo, MICHISHITA Tsuguo, MAEDA Siro. Separation of meta- and para-xylene mixture by distillation accompanied by chemical reactions[J]. Journal of Chemical Engineering of Japan, 1971, 4(1): 37-43.
[9]	张方坤, 王云龙, 徐啟蕾, 等. 一种萃取精馏分离邻/间/对二甲苯混合物的方法: CN117285405A[P]. 2023-12-26.
	ZHANG Fangkun, Wang Yunlong, Xu Qilei, et al. A method for separating o/m/p-xylene mixture by extractive distillation: CN117285405A[P] 2023-12-26.
[10]	赵同复, 李斌, 王振龙, 等. BaX分子筛的阳离子分布及其吸附分离对二甲苯的机理[J]. 催化学报, 2005, 26(8): 655-659.
	ZHAO Tongfu, LI Bin, WANG Zhenlong, et al. Distribution of cation in BaX zeolite and mechanism of adsorption and separation for paraxylene[J]. Chinese Journal of Catalysis, 2005, 26(8): 655-659.
[11]	RASOULI Milad, YAGHOBI Nakisa, MOVASSAGHI GILANI Seyedeh Zahra, et al. Influence of monovalent alkaline metal cations on binder-free nano-zeolite X in para-xylene separation[J]. Chinese Journal of Chemical Engineering, 2015, 23(1): 64-70.
[12]	CHEN Weiye, YAO Tuo, LIU Jian, et al. Modeling and validation of multi-objective optimization for mixed xylene hybrid distillation/crystallization process[J]. Separation and Purification Technology, 2025, 354: 128778.
[13]	杨勇, 张钊, 王东亮, 等. 基于CO₂加氢耦合甲苯甲基化选择催化的PX生产工艺对比[J]. 清华大学学报(自然科学版), 2024, 64(3): 538-544.
	YANG Yong, ZHANG Zhao, WANG Dongliang, et al. Production technology of p-xylene production by toluene methylation with selective carbon dioxide hydrogenation[J]. Journal of Tsinghua University (Science and Technology), 2024, 64(3): 538-544.
[14]	夏敦焰, 彭莉, 吴政奇, 等. MFI型分子筛膜的两段变温合成及对二甲苯异构体的分离性能[J]. 高等学校化学学报, 2020, 41(12): 2813-2821.
	XIA Dunyan, PENG Li, WU Zhengqi, et al. Two-stage varying-temperature synthesis of MFI zeolite membrane and their separation performance for xylene isomers[J]. Chemical Journal of Chinese Universities, 2020, 41(12): 2813-2821.
[15]	ZHOU Jian, LIU Zhicheng, WANG Yangdong, et al. Shape selective catalysis in methylation of toluene: Development, challenges and perspectives[J]. Frontiers of Chemical Science and Engineering, 2018, 12(1): 103-112.
[16]	SHARMA Poonam, SEBASTIAN Joby, GHOSH Sreetama, et al. Recent advances in hydrogenation of CO₂ into hydrocarbons via methanol intermediate over heterogeneous catalysts[J]. Catalysis Science & Technology, 2021, 11(5): 1665-1697.
[17]	CHAKINALA Nandana, CHAKINALA Anand G. Process design strategies to produce p-xylene via toluene methylation: A review[J]. Industrial & Engineering Chemistry Research, 2021, 60(15): 5331-5351.
[18]	LIU Jing, YANG Yu, WEI Shunan, et al. Intensified p-xylene production process through toluene and methanol alkylation[J]. Industrial & Engineering Chemistry Research, 2018, 57(38): 12829-12841.
[19]	WANG Dongliang, ZHANG Junqiang, YANG Yong, et al. Process simulation for enhanced p-xylene production via aromatics complex integrated toluene methylation with low-cost methanol feedstock[J]. Chemical Engineering Research and Design, 2023, 191: 184-195.
[20]	SHANG Xin, ZHUO Hongying, HAN Qiao, et al. Xylene synthesis through tandem CO₂ hydrogenation and toluene methylation over a composite ZnZrO zeolite catalyst[J]. Angewandte Chemie International Edition, 2023, 62(37): e202309377.
[21]	ZUO Jiachang, CHEN Weikun, LIU Jia, et al. Selective methylation of toluene using CO₂ and H₂ to para-xylene[J]. Science Advances, 2020, 6(34): eaba5433.
[22]	MIAO Dengyun, PAN Xiulian, JIAO Feng, et al. Selective synthesis of para-xylene and light olefins from CO₂/H₂ in the presence of toluene[J]. Catalysis Science & Technology, 2021, 11(13): 4521-4528.
[1]	BUSCA Guido. Production of gasolines and monocyclic aromatic hydrocarbons: From fossil raw materials to green processes[J]. Energies, 2021, 14(13): 4061.
[2]	PENG Bo, WANG Shaoyan. Separation of p-xylene and m-xylene by simulated moving bed chromatography with MIL-53(Fe) as stationary phase[J]. Journal of Chromatography A, 2022, 1673: 463091.
[3]	GONÇALVES Jonathan C, RODRIGUES Alírio E. Simulated moving bed reactor for p-xylene production: Adsorbent and catalyst homogeneous mixture[J]. Chemical Engineering Journal, 2014, 258: 194-202.
[23]	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.
[24]	ZHANG Peipei, TAN Li, YANG Guohui, et al. One-pass selective conversion of syngas to para-xylene[J]. Chemical Science, 2017, 8(12): 7941-7946.
[25]	HAN Xiaoqin, ZUO Jiachang, WEN Danlu, et al. Toluene methylation with syngas to para-xylene by bifunctional ZnZrO _x -HZSM-5 catalysts[J]. Chinese Journal of Catalysis, 2022, 43(4): 1156-1164.
[26]	TIAN Haifeng, HE Huanhuan, JIAO Jiapeng, et al. Tandem catalysts composed of different morphology HZSM-5 and metal oxides for CO₂ hydrogenation to aromatics[J]. Fuel, 2022, 314: 123119.
[27]	LI Wen, WANG Kuncan, HUANG Junjie, et al. M _x O _y -ZrO₂ (M=Zn, Co, Cu) solid solutions derived from schiff base-bridged UiO-66 composites as high-performance catalysts for CO₂ hydrogenation[J]. ACS Applied Materials & Interfaces, 2019, 11(36): 33263-33272.
[28]	XIAO Zhikai, HUANG Hai, CAO Chenxi, et al. Designing a bifunctional ZrCuO _x /HZSM-5 catalyst for selective methylation of toluene with carbon dioxide to para-xylene[J]. Fuel, 2022, 319: 123848.
[29]	NI Youming, CHEN Zhiyang, FU Yi, et al. Selective conversion of CO₂ and H₂into aromatics[J]. Nature Communications, 2018, 9(1): 3457.
[30]	Mahdi ABDI-KHANGHAH, ALRASHED Abdullah A A A, HAMOULE Touba,et al. Toluene methylation to para-xylene[J]. Journal of Thermal Analysis and Calorimetry, 2018, 135(3): 1723-1732.
[31]	杨明磊, 魏民, 胡蓉, 等. 二甲苯模拟移动床分离过程建模与仿真[J]. 化工学报, 2013, 64(12): 4335-4341.
	YANG Minglei, WEI Min, HU Rong, et al. Modeling of simulated moving bed for xylene separation[J]. CIESC Journal, 2013, 64(12): 4335-4341.
[32]	张东辉, 沈圆辉, 吴丽梅, 等. 对二甲苯模拟移动床分离过程的模拟与优化[J]. 天津大学学报(自然科学与工程技术版), 2016, 49(3): 279-286.
	ZHANG Donghui, SHEN Yuanhui, WU Limei, et al. Simulation and optimization of simulated moving bed for the separation of p-xylene[J]. Journal of Tianjin University (Science and Technology), 2016, 49(3): 279-286.
[33]	WANKAT P C. Simulated moving bed cascades for ternary separations[J]. Industrial & Engineering Chemistry Research, 2001, 40(26): 6185-6193.
[34]	JIN Weihua, WANKAT Phillip C. Hybrid simulated moving bed processes for the purification of p‍‐‍xylene[J]. Separation Science and Technology, 2007, 42(4): 669-700.
[35]	Cristofer BRAVO-BRAVO, SEGOVIA-HERNÁNDEZ Juan Gabriel, Salvador HERNÁNDEZ, et al. Hybrid distillation/melt crystallization process using thermally coupled arrangements: Optimization with evolutive algorithms[J]. Chemical Engineering and Processing: Process Intensification, 2013, 67: 25-38.
[36]	KONG Lingxun, WU Yaqing, MARAVELIAS Christos T. Simultaneous utility and heat exchanger area targeting for integrated process synthesis and heat integration[J]. Industrial & Engineering Chemistry Research, 2017, 56(41): 11847-11859.
[37]	IBRAHIM Dauda, JOBSON Megan, Gonzalo GUILLÉN-GOSÁLBEZ. Optimization-based design of crude oil distillation units using rigorous simulation models[J]. Industrial & Engineering Chemistry Research, 2017, 56(23): 6728-6740.

类别	对二甲苯	间二甲苯	邻二甲苯	催化剂	参考文献
A	23.89	53.26	22.84		[3,23-24]
B	33.00	48.00	19.00	ZnZrO _x /4Z5	[25]
C	48.00	26.85	25.15	ZnZrO _x /2Z5	[24-26]
D	70.81	20.10	9.06	ZnZrO _x /2Z5	[5,22,25,27]
E	81.79	12.26	5.95	ZrCuO_0.1-Z5_0.5(25)-Si(2)	[28-29]
F	92.09	3.98	3.93	ZSM-5	[18-19,30]

类别	对二甲苯	间二甲苯	邻二甲苯	催化剂	参考文献
A	23.89	53.26	22.84		[3,23-24]
B	33.00	48.00	19.00	ZnZrO _x /4Z5	[25]
C	48.00	26.85	25.15	ZnZrO _x /2Z5	[24-26]
D	70.81	20.10	9.06	ZnZrO _x /2Z5	[5,22,25,27]
E	81.79	12.26	5.95	ZrCuO_0.1-Z5_0.5(25)-Si(2)	[28-29]
F	92.09	3.98	3.93	ZSM-5	[18-19,30]

SMB结构参数	吸附操作条件	吸附模型参数
SMB结构参数	吸附操作条件	吸附剂参数	吸附平衡常数	最大吸附量
H_SMB=122.7cm	t=70s	ρ=876kg/m³	K_PX=1.0750	q_m_PX=0.168kg/kg
D_SMB=600cm	T=177℃	ε=0.39	K_OX=0.2850	q_m_OX=0.168kg/kg
床层数分配7-9-5-3	p=0.88MPa	d_p=0.56mm	K_MX=0.2645	q_m_MX=0.168kg/kg
床层数分配7-9-5-3		Pe=2000	K_PDEB=1.3125	q_m_PDEB=0.138kg/kg
		K_L=9min^-1

SMB结构参数	吸附操作条件	吸附模型参数
SMB结构参数	吸附操作条件	吸附剂参数	吸附平衡常数	最大吸附量
H_SMB=122.7cm	t=70s	ρ=876kg/m³	K_PX=1.0750	q_m_PX=0.168kg/kg
D_SMB=600cm	T=177℃	ε=0.39	K_OX=0.2850	q_m_OX=0.168kg/kg
床层数分配7-9-5-3	p=0.88MPa	d_p=0.56mm	K_MX=0.2645	q_m_MX=0.168kg/kg
床层数分配7-9-5-3		Pe=2000	K_PDEB=1.3125	q_m_PDEB=0.138kg/kg
		K_L=9min^-1

流股	模拟移动床					反应精馏					结晶
	PDEB	S101	PX	MX	OX	DTBB，TBB	S202	PX	OX	TBMX	S301	PX	MX	OX
	物流量/kmol·h^-1	PX质量分数/%	PX收率/%	物流量/kmol·h^-1	物流量/kmol·h^-1	物流量/kmol·h^-1	PX质量分数/%	PX收率/%	物流量/kmol·h^-1	物流量/kmol·h^-1	PX质量分数/%	PX收率/%	物流量 /kmol·h^-1	物流量 /kmol·h^-1
A	156.64	96.44	98.38	52.19	22.38	79.89	45.34	94.94	22.38	50.60	10.67	89.33	52.25	22.41
B	167.80	95.36	97.42	47.04	18.62	72.00	50.08	95.32	18.70	46.08	8.68	91.32	47.14	18.66
C	194.43	93.88	96.87	26.31	24.65	40.28	71.15	96.77	24.75	26.04	6.22	93.78	26.39	24.72
D	235.55	92.43	96.27	19.70	8.88	30.15	77.90	97.43	8.93	19.70	3.14	96.86	19.80	8.92
E	274.96	95.69	95.16	12.01	5.83	18.39	85.44	97.94	5.89	12.14	2.57	97.43	12.09	5.87
F	310.32	98.26	94.22	3.90	3.85	5.97	94.46	98.38	3.92	3.94	0.09	99.91	3.93	3.88