芳烃类氢载体催化转化制氢的研究

doi:10.3969/j.issn.0253-2417.2023.02.009

摘要/Abstract

摘要：

以分子筛为载体, 采用不同辅助方法浸渍法制备镍基负载型分子筛催化剂, 并在固定床反应器中研究了镍基分子筛催化剂对生物质焦油芳烃类氢载体——甲苯的催化热解制氢性能, 考察了不同分子筛、辅助方法及工艺条件的影响, 对催化剂的使用寿命进行了研究；并采用XRD、SEM、BET等方法对催化剂进行表征分析。研究结果表明：以HZSM-5(硅铝比25)分子筛为载体, 采用超声波辅助浸渍法, 且当超声波处理时间为20 min, 超声波功率为80 W, Ni负载量(以分子筛质量计)为8%时制备出的Ni/HZSM-5分子筛催化剂的催化活性最强, 在700 ℃下催化甲苯40 min的氢气产率可以达到76.6 mL/g, 甲烷产率为27.6 mL/g, 总气体产率为108.9 mL/g, 甲苯转化率为76.8%, 积炭量为238.2 mg/g, 催化剂比表面积为241.8 m²/g, 总孔容为0.19 cm³/g, 平均孔径为3.16 nm；Ni的负载不会对HZSM-5的晶体结构造成明显影响, 但Ni组分的加入起到了很好的催化效果, Ni/HZSM-5催化剂稳定性得到了提升, 使用寿命得到了延长, 对甲苯的催化制氢性能优于四氢萘、苯酚和乙酸。

关键词: 镍基催化剂, 催化热解, 芳烃, 制氢

Abstract:

Nickel-based supported molecular sieve catalysts were prepared by excessive impregnation with different auxiliary methods using molecular sieve as the carrier. The catalytic pyrolysis performance of the nickel-based molecular sieve catalysts on the hydrogen carrier of biomass tar aromatic hydrocarbon-toluene to produce hydrogen was studied in a fixed-bed reactor. The effects of different molecular sieves, auxiliary methods and process conditions were investigated, and the service life of the catalyst was studied. The catalysts were characterized by XRD, SEM and BET. The results showed that the Ni/HZSM-5 molecular sieve catalyst using HZSM-5(the ratio of silicon to aluminum was 25) zeolite as the carrier had the highest catalytic activity, through the ultrasonic-assisted impregnation method, and the ultrasonic time was 20 min, the ultrasonic power was 80 W, and the Ni loading was 8%. At 700℃ and 40 min, the yields of H₂ and CH₄ were 76.6 mL/g and 27.6 mL/g, respectirely, and the total gas yield reached 108.9 mL/g. The toluene conversion rate was 76.8%, and the carbon deposition was 238.2 mg/g. The specificsurface area, the total pore volume and the average pore size of the catalyst were 241.8 m²/g, 0.19 cm³/g and 3.16 nm, respectively. The Ni loading did not affect the crystal structure of HZSM-5 obviously, while it exhibited an excellent catalytic activity. The stability of Ni/HZSM-5 catalyst was improved, and the service life was also extended. The catalytic hydrogen production performance of toluene was better than that of tetralin, phenol and acetic acid.

Key words: nickel-based catalyst, catalytic pyrolysis, aromatics, hydrogen production

中图分类号:

TQ35
TK6

陈文轩, 李学琴, 刘鹏, 雷廷宙, 李艳玲, 吴幼青. 芳烃类氢载体催化转化制氢的研究[J]. 林产化学与工业, 2023, 43(2): 63-72.

Wenxuan CHEN, Xueqin LI, Peng LIU, Tingzhou LEI, Yanling LI, Youqing WU. Catalytic Conversion of Aromatic Hydrocarbon-based Hydrogen Carriers to Produce Hydrogen[J]. Chemistry and Industry of Forest Products, 2023, 43(2): 63-72.

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分子筛¹⁾ molecular sieves	氢气产率/(mL·g^-1) H₂ yield	甲烷产率/(mL·g^-1) CH₄ yield	总气体产率/(mL·g^-1) total gas yield	甲苯转化率/% toluene conversion rate	积炭量/(mg·g^-1) carbon deposition
HZSM-5(25)	31.3	14.3	47.5	47.4	126.2
HZSM-5(50)	26.1	11.0	40.2	44.4	164.0
USY	32.0	15.4	49.4	41.4	253.9

辅助方法 auxiliary methods	氢气产率 /(mL·g^-1) H₂ yield	甲烷产率 /(mL·g^-1) CH₄ yield	总气体产率 /(mL·g^-1) total gas of yield	甲苯转化率/% toluene conversion rate	积炭量/(mg·g^-1) carbon deposition
传统浸渍traditional impregnation	60.6	18.9	83.4	70.3	392.2
离子交换ion exchange	59.1	17.9	80.0	78.6	317.9
超声波辅助ultrasonic assisted	65.7	22.1	94.9	79.7	311.7
旋转蒸发rotary evaporation	62.8	19.5	86.3	75.4	331.8

超声波功率/W ultrasonic power	氢气产率/(mL·g^-1) H₂ yield	甲烷产率/(mL·g^-1) CH₄ yield	总气体产率/(mL·g^-1) total gas yield	甲苯转化率/% toluene conversion rate	积炭量/(mg·g^-1) carbon deposition
60	54.1	18.9	76.9	74.3	336.1
70	60.1	18.9	82.0	76.6	312.7
80	65.7	22.1	91.9	75.7	290.9
90	54.8	19.5	78.3	75.4	322.3

超声波时间/min ultrasonic time	氢气产率/(mL·g^-1) H₂ yield	甲烷产率/(mL·g^-1) CH₄ yield	总气体产率/(mL·g^-1) total gas yield	甲苯转化率/% toluene conversion rate	积炭量/(mg·g^-1) carbon deposition
20	70.2	24.8	99.2	75.9	259.8
40	66.9	23.6	94.4	74.4	272.3
60	64.5	21.1	90.0	74.5	284.2
90	64.7	22.4	91.1	73.8	292.4
120	63.6	20.8	89.0	75.1	288.5

镍负载量/% Ni loading	氢气产率/(mL·g^-1) H₂ yield	甲烷产率/(mL·g^-1) CH₄ yield	总气体产率/(mL·g^-1) total gas yield	甲苯转化率/% toluene conversion rate	积炭量/(mg·g^-1) carbon deposition
6	60.1	20.4	84.5	74.3	315.9
7	62.5	19.4	87.9	75.4	303.6
8	66.4	23.4	95.8	76.4	260.7
9	64.0	24.0	92.0	74.4	268.6
10	65.7	22.5	91.2	74.0	272.5