液化残渣基CO2吸附剂的制备与性能优化

doi:10.16085/j.issn.1000-6613.2023-0090

化工进展 ›› 2023, Vol. 42 ›› Issue (12): 6620-6630.DOI: 10.16085/j.issn.1000-6613.2023-0090

• 资源与环境化工 • 上一篇

液化残渣基CO₂吸附剂的制备与性能优化

崔倩¹(), 王岸楠¹, 陈再明², 孙峤昳¹, 王保登¹, 王永胜³, 孙楠楠⁴, 胡剑², 李井峰⁵, 熊日华¹()

^1.国家能源集团北京低碳清洁能源研究院，北京 102209
^2.国能浙江宁海发电有限公司，浙江宁波 315612
^3.中国神华煤制油化工有限公司鄂尔多斯煤制油分公司，内蒙古鄂尔多斯 017209
^4.中国科学院上海高等研究院低碳转化科学与工程重点实验室，上海 201210
^5.国家能源投资集团有限责任公司，北京 100011

收稿日期:2023-01-19 修回日期:2023-03-20 出版日期:2023-12-25 发布日期:2024-01-08
通讯作者: 熊日华
作者简介:崔倩（1991—），女，硕士，工程师，研究方向为CCUS、新能源。E-mail：qian.cui.c@chnenergy.com.cn。

Preparation and performance optimization of liquefied residue-based CO₂ adsorbents

CUI Qian¹(), WANG Annan¹, CHEN Zaiming², SUN Qiaoyi¹, WANG Baodeng¹, WANG Yongsheng³, SUN Nannan⁴, HU Jian², LI Jingfeng⁵, XIONG Rihua¹()

^1.National Institute of Clean and Low Carbon Energy, Beijing 102209, China
^2.Guoneng Zhejiang Ninghai Power Generation Co. , Ltd. , Ningbo 315612, Zhejiang, China
^3.Ordos Coal-to-Oil Sub-Company, China Shenhua Coal-to-Oil Chemical Co. , Ltd. , Ordos 017209, Inner Mongolia, China
^4.CAS Key Lab of Low-Carbon Conversion Science and Engineering, Shanghai Advanced Research Institute, Chinese Academy of Sciences, Shanghai 201210, China
^5.CHN Energy Investment Group Co. , Ltd. , Beijing 100011, China

Received:2023-01-19 Revised:2023-03-20 Online:2023-12-25 Published:2024-01-08
Contact: XIONG Rihua

摘要/Abstract

摘要：

以煤液化残渣（CLR）为原料制备CO₂吸附剂，在实现碳减排的同时，可有效提高煤直接液化工艺的经济性和环保价值。本文采用神华煤直接液化残渣为碳源，通过预氧化、炭化活化等工艺，制备出了吸附性能较优的CO₂吸附剂。利用热重分析仪（TGA）、低温氮吸附仪（BET）、扫描电镜（SEM）以及透射电子显微镜（TEM）等分析手段对吸附材料的微观形貌、孔径结构以及吸附性能进行了表征测试。结果显示，低灰分液化残渣所制备的吸附材料具有更高的比表面积和更多的微孔结构，更有利于CO₂的吸附。以低灰分液化残渣为原料，在较优活化条件下（活化剂/原料质量比为1∶1、升温速率5℃/min、活化时间1h）制备的CO₂吸附剂表现出良好的吸附性能，在40℃、15%（体积分数）CO₂模拟烟气条件下的CO₂吸附容量为4.47%（质量分数），在0℃、1bar（1bar=10⁵Pa）条件下的CO₂吸附容量可高达27.70%（质量分数），低温吸附性能优异，吸附速率快且具有良好的循环稳定性。

关键词: 煤液化残渣, 二氧化碳, 二氧化碳捕集, 吸附剂, 低温吸附

Abstract:

Using coal liquefaction residue (CLR) as the raw material to prepare CO₂adsorbents can effectively improve the economic and environmental value of direct coal liquefaction process while achieving carbon emission reduction, which is of great significance. The direct liquefaction residue of Shenhua coal was used as carbon source, and the CO₂adsorbents with better adsorption performance were prepared through the process of pre-oxidation and carbonization activation. The microstructure, pore size structure and adsorption properties of the adsorbents were characterized and tested by thermogravimetric analyzer (TGA), low temperature nitrogen adsorption instrument (BET), scanning electron microscope (SEM) and transmission electron microscope (TEM). The results showed that the adsorbents prepared from low ash liquefied residue had higher specific surface area and more microporous structure, which were more conducive to the adsorption of CO₂. The CO₂adsorbent prepared from low ash liquefied residue under optimal activation conditions (mass ratio of activator/raw material was 1∶1, heating rate was 5℃/min, activation time was 1h) showed good adsorption performance. The CO₂ adsorption capacity at 40℃ and 15%CO₂ simulated flue gas was 4.47%. At 0℃ and 1bar, the CO₂adsorption capacity could be up to 27.70%, the low temperature adsorption performance was excellent, the adsorption rate was fast, and it had good cycle stability.

Key words: coal liquefaction residual, carbon dioxide, CO₂ capture, adsorbents, low temperature adsorption

中图分类号:

TQ028

崔倩, 王岸楠, 陈再明, 孙峤昳, 王保登, 王永胜, 孙楠楠, 胡剑, 李井峰, 熊日华. 液化残渣基CO₂吸附剂的制备与性能优化[J]. 化工进展, 2023, 42(12): 6620-6630.

CUI Qian, WANG Annan, CHEN Zaiming, SUN Qiaoyi, WANG Baodeng, WANG Yongsheng, SUN Nannan, HU Jian, LI Jingfeng, XIONG Rihua. Preparation and performance optimization of liquefied residue-based CO₂ adsorbents[J]. Chemical Industry and Engineering Progress, 2023, 42(12): 6620-6630.

图/表 19

参考文献 32

1	蔡博峰, 李琦, 张贤, 等. 中国二氧化碳捕集、利用与封存 (CCUS) 年度报告: 中国 CCUS 路径研究[R]. 生态环境部环境规划院, 中国科学院武汉岩土力学研究所, 中国 21 世纪议程管理中心, 2021.
	CAI Bofeng, LI Qi, ZHANG Xian, et al. China carbon dioxide capture, utilization and storage (CCUS) annual report: China CCUS pathway study[R]. Institute of Environmental Planning, Ministry of Ecology and Environment, Wuhan Institute of Rock and Soil Mechanics, Chinese Academy of Sciences, China Management Center for Agenda 21, 2021.
2	宋亚楠. CCUS技术的减排作用与应用前景[J]. 金融纵横, 2021(9): 35-43.
	SONG Yanan. Emission reduction effects and application prospects of CCUS[J]. Financial Perspectives Journal, 2021(9): 35-43.
3	李禾. 任重道远 CCUS技术体系尚待完善[N]. 科技日报, 2022-09-27(5).
	LI He. The CCUS technology system still needs to be improved[N]. Science and Technology Daily, 2022-09-27(5).
4	何亮, 王延斌, 张景阳. 厚积薄发 CCUS重点工程加速推进[N]. 科技日报, 2022-09-27(5).
	HE Liang, WANG Yanbing, ZHANG Jingyang. Accelerate the progress of CCUS key projects through thick accumulation and thin development[N]. Science and Technology Daily, 2022-09-27(5).
5	何亮. 变害为宝 CCUS助力“双碳”目标实现[N]. 科技日报, 2022-09-27(5).
	HE Liang. Turning harm into treasure CCUS helps achieve the “double carbon” goal[N]. Science and Technology Daily, 2022-09-27(5).
6	WANG Baodeng, CUI Qian, ZHANG Guoping, et al. Post-combustion slipstream CO₂-capture test facility at Jiangyou Power Plant, Sichuan, China: Facility design and validation using 30% wt monoethanolamine (MEA) testing[J]. Clean Energy, 2020, 4(2): 107-119.
7	CUI Qian, WANG Baodeng, ZHAO Xinglei, et al. Post-combustion slipstream CO₂-capture test facility at Jiangyou Power Plant, Sichuan, China: Performance of a membrane separation module under dynamic power-plant operations[J]. Clean Energy, 2021, 5(4): 742-755.
8	CAO Shicheng, ZHAO Hongyu, HU Deng, et al. Preparation of potassium intercalated carbons by in situ activation and speciation for CO₂ capture from flue gas[J]. Journal of CO₂ Utilization, 2020, 35: 59-66.
9	WANG Baodeng, ZHANG Zhongzheng, ZHU Chenming, et al. Enhancing low pressure CO₂ adsorption of solvent-free derived mesoporous carbon by highly dispersed potassium species[J]. RSC Advances, 2016, 6(40): 33580-33588.
10	BALSAMO M, BUDINOVA T, ERTO A, et al. CO₂ adsorption onto synthetic activated carbon: Kinetic, thermodynamic and regeneration studies[J]. Separation and Purification Technology, 2013, 116: 214-221.
11	刘之琳. 氨基功能化MCM-41材料制备及其二氧化碳吸附性能研究[D]. 北京: 华北电力大学(北京), 2016.
	LIU Zhilin. Preparation and CO₂ adsorption performance of amine-functionalized MCM-41[D]. Beijing: North China Electric Power University(Beijing), 2016.
12	SJOSTROM Sharon, SENIOR Constance. Pilot testing of CO₂ capture from a coal-fired power plant—Part 2: Results from 1-MWe pilot tests[J]. Clean Energy, 2020, 4(1): 12-25.
13	何利梅, 姜伟丽, 李继聪, 等. CO₂吸附材料的研究进展[J]. 石油化工, 2022, 51(1): 83-91.
	HE Limei, JIANG Weili, LI Jicong, et al. Research progress in the adsorption materials of CO₂ [J]. Petrochemical Technology, 2022, 51(1): 83-91.
14	MESFER Mohammed K AL. Synthesis and characterization of high-performance activated carbon from walnut shell biomass for CO₂ capture[J]. Environmental Science and Pollution Research, 2020, 27(13): 15020-15028.
15	ZENG Ganning, LOU Sa, YING Huijuan, et al. Preparation of microporous carbon from Sargassum horneri by hydrothermal carbonization and KOH activation for CO₂ capture[J]. Journal of Chemistry, 2018, 2018: 1-11.
16	KHUONG Duy Anh, NGUYEN Hong Nam, TSUBOTA Toshiki. Activated carbon produced from bamboo and solid residue by CO₂ activation utilized as CO₂ adsorbents[J]. Biomass and Bioenergy, 2021, 148: 106039.
17	张建波. 煤直接液化残渣基炭材料的制备及应用[D]. 大连: 大连理工大学, 2013.
	ZHANG Jianbo. Preparation and applications of carbon materials from direct coal liquefaction residue[D]. Dalian: Dalian University of Technology, 2013.
18	段林娥. 液化残渣在CO₂气氛下热转化特性热重研究[D]. 西安: 西北大学, 2015.
	DUAN Lin'e. Thermogravimetric study on thermal conversion characteristics of liquefied residue in CO₂ atmosphere.[D]. Xi'an: Northwest University, 2015.
19	舒成, 李克健, 章序文, 等. 原料预处理对氢氧化钾活化法制备活性炭的影响[J]. 炭素技术, 2014, 33(2): 5-8.
	SHU Cheng, LI Kejian, ZHANG Xuwen, et al. Effects of raw material pretreatment on activated carbons prepared with KOH activation[J]. Carbon Techniques, 2014, 33(2): 5-8.
20	辛凡文, 李克健, 舒歌平, 等. 预氧化对煤液化沥青制备超级活性炭的影响研究[J]. 煤炭工程, 2017, 49(8): 141-144.
	XIN Fanwen, LI Kejian, SHU Geping, et al. Influence of pre-oxidation to super activated carbon prepared from coal liquefaction asphaltene[J]. Coal Engineering, 2017, 49(8): 141-144.
21	罗化峰, 乔元栋, 李通达, 等. 煤液化残渣基炭材料吸附瓦斯实验研究[J]. 煤炭技术, 2020, 39(1): 89-92.
	LUO Huafeng, QIAO Yuandong, LI Tongda, et al. Experimental study on adsorption of gas by coal liquefaction residue based carbon material[J]. Coal Technology, 2020, 39(1): 89-92.
22	徐春霞. 煤直接液化残渣半焦CO₂气化特性及动力学研究[J]. 煤炭加工与综合利用, 2021(7): 62-67.
	XU Chunxia. Study on characteristics anddynamics of direct liquefaction residue semi-coke gasification with CO₂ [J]. Coal Processing & Comprehensive Utilization, 2021(7): 62-67.
23	李肖, 李昱琳, 田晓冬, 等. 煤液化残渣的性质及应用现状[J]. 化学研究, 2020, 31(1): 9-16, 95.
	LI Xiao, LI Yulin, TIAN Xiaodong, et al. Properties and application of coal liquefaction residues[J]. Chemical Research, 2020, 31(1): 9-16, 95.
24	LEE Seul-Yi, PARK Soo-Jin. Determination of the optimal pore size for improved CO₂ adsorption in activated carbon fibers[J]. Journal of Colloid and Interface Science, 2013, 389(1): 230-235.
25	JANG Eunji, CHOI Seung Wan, HONG Seok-Min, et al. Development of a cost-effective CO₂ adsorbent from petroleum coke via KOH activation[J]. Applied Surface Science, 2018, 429: 62-71.
26	KIM Min-Jeong, CHOI Seung Wan, KIM Hyunwook, et al. Simple synthesis of spent coffee ground-based microporous carbons using K₂CO₃ as an activation agent and their application to CO₂ capture[J]. Chemical Engineering Journal, 2020, 397: 125404.
27	SEVILLA Marta, FUERTES Antonio B. Sustainable porous carbons with a superior performance for CO₂ capture[J]. Energy & Environmental Science, 2011, 4(5): 1765-1771.
28	WANG Jiacheng, HEERWIG Andreas, LOHE Martin R, et al. Fungi-based porous carbons for CO₂ adsorption and separation[J]. Journal of Materials Chemistry, 2012, 22(28): 13911-13913.
29	WANG Lijie, SUN Fei, HAO Fei, et al. A green trace K₂CO₃ induced catalytic activation strategy for developing coal-converted activated carbon as advanced candidate for CO₂ adsorption and supercapacitors[J]. Chemical Engineering Journal, 2020, 383: 123205.
30	LIU Shenfang, MA Rui, HU Xin, et al. CO₂ adsorption on hazelnut-shell-derived nitrogen-doped porous carbons synthesized by single-step sodium amide activation[J]. Industrial & Engineering Chemistry Research, 2020, 59(15): 7046-7053.
31	张双全, 马蓉, 朱文魁, 等. 用于吸附分离CO₂的活性炭研究[J]. 中国矿业大学学报, 2004, 33(6): 683-686.
	ZHANG Shuangquan, MA Rong, ZHU Wenkui, et al. Research on activated carbon for separating CO₂ by adsorption[J]. Journal of China University of Mining & Technology, 2004, 33(6): 683-686.
32	PLAZA M G, GONZÁLEZ A S, PEVIDA C, et al. Valorisation of spent coffee grounds as CO₂ adsorbents for postcombustion capture applications[J]. Applied Energy, 2012, 99: 272-279.

样品	工业分析				元素分析
样品	M_ad	A_d	V_d	FC_d	C	H	N	S
CLR	0.31	26.28	33.56	40.17	67.60	4.26	0.53	4.99
DCLR	0.26	0.35	51.91	47.75	91.20	6.41	1.14	0.21

样品	工业分析				元素分析
样品	M_ad	A_d	V_d	FC_d	C	H	N	S
CLR	0.31	26.28	33.56	40.17	67.60	4.26	0.53	4.99
DCLR	0.26	0.35	51.91	47.75	91.20	6.41	1.14	0.21

样品	成分
样品	Fe₂O₃	CaO	SO₃	SiO₂	Al₂O₃	TiO₂	MgO	Na₂O	其他
CLR	53.48	12.39	12.19	11.79	5.77	1.16	1.05	1.02	1.15
DCLR	45.88	11.92	22.33	7.13	4.70	1.08	1.57	3.99	1.40

样品	成分
样品	Fe₂O₃	CaO	SO₃	SiO₂	Al₂O₃	TiO₂	MgO	Na₂O	其他
CLR	53.48	12.39	12.19	11.79	5.77	1.16	1.05	1.02	1.15
DCLR	45.88	11.92	22.33	7.13	4.70	1.08	1.57	3.99	1.40

样品	S_BET/m²·g^-1	S_mic /m²·g^-1	V_tol /cm³·g^-1	V_mic /cm³·g^-1	D_a/nm
CLR-1-10C-0.5h	1308	1103	0.61	0.46	4.73
CLR-1-10C-1h	1259	1121	0.59	0.47	2.98
CLR-1-10C-1.5h	1251	1038	0.57	0.43	4.65
CLR-1-10C-2h	1328	996	0.78	0.39	4.84

液化残渣基CO₂吸附剂的制备与性能优化

Preparation and performance optimization of liquefied residue-based CO₂ adsorbents

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参考文献 32

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样品	S_BET/m²·g^-1	S_mic/m²·g^-1	V_tol/cm³·g^-1	V_mic/cm³·g^-1	D_a/nm
CLR-1-3C-1h	1311	1244	0.60	0.53	1.83
CLR-1-5C-1h	1389	1221	0.63	0.52	2.22
CLR-1-10C-1h	1259	1121	0.59	0.47	2.98

样品	S_BET/m²·g^-1	S_mic/m²·g^-1	V_tol/cm³·g^-1	V_mic/cm³·g^-1	D_a/nm
CLR-0-5C-1h	49	36	0.03	0.01	3.98
CLR-0.5-5C-1h	708	630	0.37	0.24	2.10
CLR-1-5C-1h	1389	1221	0.63	0.52	2.22
CLR-2-5C-1h	1528	1103	0.95	0.50	2.87

样品	灰分	Fe₂O₃	CaO	SO₃	SiO₂	Al₂O₃	TiO₂	MgO	Na₂O	K₂O	其他
CLR-1-10C-0.5h	2.54	36.37	1.31	0.63	50.14	3.62	2.44	0.47	2.81	2.00	0.21
DCLR-1-10C-0.5h	1.21	23.83	0.80	0.70	63.49	2.87	0.42	0.25	3.11	4.24	0.29

项目	前体	活化剂	吸附温度/℃	吸附压力/bar	CO₂吸附量/%
DCLR-1-5C-1h	液化残渣	KOH	40	0.15	4.47
DCLR-1-5C-1h	液化残渣	KOH	0	1	27.70
文献[27]	淀粉/纤维素/木屑	KOH	0	1	25.52
文献[28]	莴笋叶	KOH	0	1	26.40
文献[29]	亚烟煤	K₂CO₃+ CO₂	0	1	19.18
文献[30]	榛子壳	NaNH₂	0	1	26.00
文献[31]	无烟煤	H₂O	0	1	12.89
文献[32]	咖啡渣	CO₂	0	1	14.08
市售活性炭1	煤质	—	40	0.15	2.57
市售活性炭2	椰壳	—	40	0.15	3.48
市售活性炭3	椰壳	—	40	0.15	2.91

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