竹材微正压热解自活化制备高吸附性能活性炭的机制研究

doi:10.3969/j.issn.0253-2417.2019.05.003

林产化学与工业 ›› 2019, Vol. 39 ›› Issue (5): 19-25.doi: 10.3969/j.issn.0253-2417.2019.05.003

竹材微正压热解自活化制备高吸附性能活性炭的机制研究

孙昊^1,2,3, 孙康^1,2,3, 蒋剑春^1,2, 许伟^1,2, 张燕萍^1,2

1. 中国林业科学研究院林产化学工业研究所;生物质化学利用国家工程实验室;国家林业和草原局林产化学工程重点实验室;江苏省生物质能源与材料重点实验室, 江苏南京 210042;
2. 南京林业大学江苏省林业资源高效加工利用协同创新中心, 江苏南京 210037;
3. 中国林业科学研究院林业新技术研究所, 北京 100091

收稿日期:2019-04-26 出版日期:2019-10-25 发布日期:2019-11-01
通讯作者: 蒋剑春,研究员,博士生导师,主要从事生物质能源和炭材料的研究开发工作;E-mail:bio-energy@163.com E-mail:bio-energy@163.com
作者简介:孙昊(1989-),男,江苏盐城人,助理研究员,博士,主要从事木质纤维基炭材料的研究工作
基金资助:
江苏省生物质能源与材料重点实验室基本科研业务费项目（JSBEM-S-201910）

Self-activation Mechanism for Preparation of Bamboo Derived High Performance Activated Carbon Under Micro-posotive Pressure

SUN Hao^1,2,3, SUN Kang^1,2,3, JIANG Jianchun^1,2, XU Wei^1,2, ZHANG Yanping^1,2

1. Institute of Chemical Industry of Forest Products, CAF;National Engineering Lab. for Biomass Chemical Utilization;Key Lab. of Chemical Engineering of Forest Products, National Forestry and Grassland Administration;Key Lab. of Biomass Energy and Material, Jiangsu Province, Nanjing 210042, China;
2. Jiangsu Co-Innovation Center of Efficient Processing and Utilization of Forest Resources, Nanjing Forestry University, Nanjing 210037, China;
3. Research Institute of Forestry New Technology, CAF, Beijing 100091, China

Received:2019-04-26 Online:2019-10-25 Published:2019-11-01

摘要/Abstract

摘要： 以竹材加工剩余物为原料，在不添加活化剂的条件下，开展了微正压热解自活化制备活性炭的研究，通过热重-质谱分析、热解炭化和热解自活化对比，以及热解自活化尾气监测，探究热解过程中活性炭孔隙结构的形成机制。研究结果发现：热解过程产生的水蒸气和二氧化碳可以与固相炭发生气化成孔反应，制得高吸附性能的竹材活性炭；热解气体、均匀活化、气-炭可逆反应平衡状态、活化剂的扩散速率及气-炭反应速率是竹材活性炭孔隙结构和吸附性能的主要影响机制；控制热解自活化压力为0.12 MPa，在900℃（升温速率15℃/min）热解6 h，制得活性炭得率为15.22%，BET比表面积（S_BET）1 108 m²/g，微孔容积（V_mic）为0.407 cm³/g，介孔容积（V_mes）为0.085 cm³/g，碘和亚甲基蓝的吸附值分别为1 438和300 mg/g，同时副产高H₂、CO含量和高CO/CO₂比例的费托合成原料气。

关键词: 竹活性炭, 自活化, 微正压, 调控机制

Abstract: The preparation of activated carbon was carried out using bamboo as material via pyrolysis self-activation under micro-positive pressure without activating agent. The pore formation mechanism of activated carbon was investigated based on its structural characterization and adsorption properties. The results showed that the generated CO₂ and H₂O could react with solid carbon to prepare activated carbon with high adsorption performance during the pyrolysis process. The main influences on pore structure and adsorption properties of bamboo activated carbon were the pyrolysis gas, humogeneous activation, equilibrium state of gas-carbon reversible reaction, diffusion rate of activator and gas-carbon reaction rate. The activated carbon was prepared under the pyrolysis self-activation of bamboo 0.12 MPa at 900℃ (15℃/min heating rate) for 6 h. The yield of the product was 15.22% with the BET specific surface area(S_BET), micropore volume(V_mic), mesopore volume(V_mes), iodine value and methylene blue (MB) value of activated carbon were 1 108 m²/g, 0.407 cm³/g, 0.085 cm³/g, 1 438 mg/g and 300 mg/g, respectively. Moreover, the gas by-product of self-activation contained high concentration of H₂ and CO and exhibited a high ratio of CO to CO₂, which could be raw materials for Fischer-Tropsch reaction.

Key words: bamboo derived activated carbon, self-activation, micro-positive pressure, regulation mechanism

中图分类号:

TQ35

孙昊, 孙康, 蒋剑春, 许伟, 张燕萍. 竹材微正压热解自活化制备高吸附性能活性炭的机制研究[J]. 林产化学与工业, 2019, 39(5): 19-25.

SUN Hao, SUN Kang, JIANG Jianchun, XU Wei, ZHANG Yanping. Self-activation Mechanism for Preparation of Bamboo Derived High Performance Activated Carbon Under Micro-posotive Pressure[J]. Chemistry and Industry of Forest Products, 2019, 39(5): 19-25.

参考文献

[1] ZHANG Y J, XING Z J, DUAN Z K, et al.Effects of steam activation on the pore structure and surface chemistry of activated carbon derived from bamboo waste[J]. Applied Surface Science, 2014, 315:279-286.
[2] ZHU Y W, GAO J H, SUN Y F, et al.Preparation of activated carbons for SO₂ adsorption by CO₂ and steam activation[J]. Journal of the Taiwan Institute of Chemical Engineers, 2012, 43(1):112-119.
[3] ZHU G Z, DENG X L, HOU M, et al.Comparative study on characterization and adsorption properties of activated carbons by phosphoric acid activation from corncob and its acid and alkaline hydrolysis residues[J]. Fuel Processing Technology, 2016, 144:255-261.
[4] HASAN S, FUAT G.High surface area mesoporous activated carbon from tomato processing solid waste by zinc chloride activation:Process optimization, characterization and dyes adsorption[J]. Journal of Cleaner Production, 2016, 113:995-1004.
[5] LIU D C, ZHANG W L, LIN H B, et al.A green technology for the preparation of high capacitance rice husk-based activated carbon[J]. Journal of Cleaner Production, 2015, 112(1):1190-1198.
[6] SUN K, LENG C Y, JIANG J C, et al.Microporous activated carbons from coconut shells produced by self-activation using the pyrolysis gases produced from them, that have an excellent electric double layer performance[J]. New Carbon Materials, 2017, 32(5):451-459.
[7] SUN K, JIANG J C, LU X C, et al.Preparation of high microporosity activated carbon by autogenic pressure under high temperature[J].Chemistry and Industry of Forest Products, 2015, 35(4):53-58. 孙康, 蒋剑春, 卢辛成, 等.高温自生压活化制备高微孔率活性炭研究[J].林产化学与工业, 2015, 35(4):53-58.
[8] JIANG J C.Manufacturing and Application Technology of Activated Carbon[M]. Beijing:Chemical Industry Press, 2017:45. 蒋剑春.活性炭制造与应用技术[M].北京:化学工业出版社, 2017:45.
[9] BOMMIER C, XU R, WANG W, et al.Self-activation of cellulose:A new preparation methodology for activated carbon electrodes in electrochemical capacitors[J]. Nano Energy, 2015, 13:709-717.
[10] CHENG Q P, TIAN Y, LYU S S, et al.Confined small-sized cobalt catalysts stimulate carbon-chain growthreversely by modifying ASF law of Fischer-Tropsch synthesis[J]. Nature Communications, 2018, 9(1):1-9.
[11] SI C D, GUO Q J.Progress research on activation mechanism and regeneration of activated carbon[J]. China Powder Science and Technology, 2008, 14(5):48-52. 司崇殿, 郭庆杰.活性炭活化机理与再生研究进展[J].中国粉体技术, 2008, 14(5):48-52.
[12] HIDEKI T, ABE I.Application Technology of Activated Carbon:Its Maintenance Management and Existing Problems for Reference[M]. GAO S Y, tran.Nanjing:Southeast University Press, 2002:35. 立本英机, 安部郁夫.活性炭的应用技术:其维持管理及存在问题[M].高尚愚, 译.南京:东南大学出版社, 2002:35.

竹材微正压热解自活化制备高吸附性能活性炭的机制研究

Self-activation Mechanism for Preparation of Bamboo Derived High Performance Activated Carbon Under Micro-posotive Pressure

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