水/二氧化碳气氛下酒糟催化气化反应特性的研究
收稿日期: 2022-04-28
网络出版日期: 2023-02-16
基金资助
国家重点研发计划项目(2018YFC1903500);贵州省科技计划项目(黔科合平台人才[2019]5410)
Study on catalytic gasification reaction of distillers′grains under H2O/CO2 atmosphere
Received date: 2022-04-28
Online published: 2023-02-16
在固定床气化装置中,以赤泥为催化剂、水/二氧化碳为气化剂对酒糟进行气化实验。研究了赤泥添加量、气化温度和V(水)/V(二氧化碳)对酒糟气化活性的影响,并对水/二氧化碳共气化协同机理进行了探讨。结果表明:当赤泥添加量为20%(质量分数)时气化活性最佳;升高气化温度有利于提高气化反应活性;随着V(水)/V(二氧化碳)的增大,合成气产量、n(氢气)/n(一氧化碳)均增加,分别达到270.7 mmol/g和6.67;在水/二氧化碳混合气氛下共气化反应产生了明显的协同效应,协同因子在60%水-40%二氧化碳(体积分数)时达到峰值。拉曼光谱、扫描电子显微镜及比表面积分析表明:水/二氧化碳混合气氛下酒糟焦无定形碳和非晶碳结构的破坏程度比在纯水或二氧化碳中更严重,验证了二氧化碳和水在酒糟气化中存在协同效应;二氧化碳更容易在酒糟焦表面发生气化反应,形成大量微孔使其比表面积增加;水炭渗透力较强有利于形成中孔;在水/二氧化碳混合气氛下,二氧化碳与水产生的交互作用促进了孔结构的发育,使酒糟焦的微孔发展为中孔和大孔并促使气化反应向酒糟颗粒内部发展,这是协同效应产生的主要原因。
李松鸿 , 周松华 , 赵爱明 , 董文燕 , 姜春燕 , 曹阳 , 敖先权 . 水/二氧化碳气氛下酒糟催化气化反应特性的研究[J]. 无机盐工业, 2023 , 55(2) : 132 -140 . DOI: 10.19964/j.issn.1006-4990.2022-0243
The gasification experiments on distillers′ grain was conducted in a fixed-bed gasification plant with red mud as the catalyst and H2O/CO2 as the gasification agent.The effects of red mud addition,gasification temperature and H2O/CO2 ratio on the gasification characteristics of the distillers′ grain were investigated and the synergistic mechanism of H2O/CO2 co-gasification was discussed.The results showed that the gasification activity was best when red mud addition was 20%(mass fraction).The increased gasification temperature was beneficial to the gasification reaction activity.When V(H2O)/V(CO2) was increased,the syngas yield and n(H2)/n(CO) was also increased,up to 270.7 mmol/g and 6.67.The co-gasification under H2O/CO2 mixed atmosphere produced significant synergistic effect,and the synergistic factor was peaked at 60% H2O-40% CO2(volume fraction).Raman,SEM and BET analysis showed that the amorphous carbon and amorphous carbon structure of the distillers′ grain coke in the H2O/CO2 mixed atmosphere was more severely damaged than that in pure H2O or CO2,which verified that CO2 and H2O existed the synergistic effect of in the distillers′ grain gasification.CO2 was more prone to gasification on the surface of distiller′s grains coke,forming a large number of micropores to increase the specific surface area.Carbon with H2O had stronger permeability to facilitate the formation of mesopores.In H2O/CO2 mixed atmosphere,the interaction between CO2 and H2O made the micropores of distiller′s grains coke to develop into mesopores and macropores and promoted the gasification reaction to the interior of distillers′ grains granule,which triggered the synergistic effect.
Key words: distillers′grains; synergistic effect; H2O/CO2; catalytic gasification; red mud
| 1 | 中华人民共和国国家统计局.中国统计年鉴[M].北京:中国统计出版社,2020. |
| 1 | National Bureau of Statistics of the People's Republic of China.China Statistical Yearbook[M].Beijing:China Statistics Press,2020. |
| 2 | 王兆夺,祝超伟,于东生.全球气候变化背景下对“温室效应”的思考[J].辽宁师范大学学报:自然科学版,2017,40(3):407-414. |
| 2 | WANG Zhaoduo, ZHU Chaowei, YU Dongsheng.On“Greenhouse Effect”under the background of global climate change[J].Journal of Liaoning Normal University:Natural Science Edition,2017,40(3):407-414. |
| 3 | IRFAN M, ELAVARASAN R M, AHMAD M,et al.Prioritizing and overcoming biomass energy barriers:Application of AHP and G-TOPSIS approaches[J].Technological Forecasting and Social Change,2022,177.Doi:10.1016/j.techfore.2022.121524 . |
| 4 | 聂永增.对于酒糟综合利用现状及创新应用的思考[J].轻工科技,2021,37(9):11-12. |
| 4 | NIE Yongzeng.Thoughts on the comprehensive utilization of distiller's grains and its innovative application[J].Light Industry Science and Technology,2021,37(9):11-12. |
| 5 | 张德成,敖先权,陈前林,等.酒糟与煤焦在CO2气氛下的共气化活性[J].过程工程学报,2016,16(4):629-633. |
| 5 | ZHANG Decheng, AO Xianquan, CHEN Qianlin,et al.Co-gasification characteristics of distillery residue with coal char in CO2 atmosphere[J].The Chinese Journal of Process Engineering,2016,16(4):629-633. |
| 6 | WANG Jiaxing, ZHANG Shuping, XU Dan,et al.Catalytic activity evaluation and deactivation progress of red mud/carbonaceous catalyst for efficient biomass gasification tar cracking[J].Fuel,2022,323.Doi:10.1016/j.fuel.2022.124278 . |
| 7 | LV Jiwei, AO Aianquan, LI Qian,et al.Steam co-gasification of different ratios of spirit-based distillers′grains and anthracite coal to produce hydrogen-rich gas[J].Bioresource Technology,2019,283:59-66. |
| 8 | ZHAO Aiming, LV Jiwei, CHEN Qianlin,et al.Spirit-based distillers’grains and red mud synergistically catalyse the steam gasification of anthracite to produce hydrogen-rich synthesis gas[J].International Journal of Hydrogen Energy,2021,46(1):314-323. |
| 9 | PHOUNGLAMCHEIK A, BACKEBO M, ROBINSON R,et al.The significance of intraparticle and interparticle diffusion during CO2 gasification of biomass char in a packed bed[J].Fuel,2022,3.Doi:1010.1016/j.fuel.2021.122302 . |
| 10 | CAI Jianjun, ZHANG Wenheng, LUO Ming,et al.Evaluation of the CO2 gasification of residual char under a regeneration atmosphere via calcium-based chemical looping gasification[J].Chemical Engineering and Processing-Process Intensification,2021,168.Doi:10.1016/j.cep.2021.108564 . |
| 11 | NILSSON S, GOMEZ-BAREA A, OLLEROll P.Gasification of char from dried sewage sludge in fluidized bed:Reaction rate in mixtures of CO2 and H2O[J].Fuel,2013,105:764-768. |
| 12 | CHANG Guozhang, YAN Ximin, QI Pengyu,et al.Characteristics of reactivity and structures of palm kernel shell(PKS) biochar during CO2/H2O mixture gasification[J].Chinese Journal of Chemical Engineering,2018,26(10):2153-2161. |
| 13 | 关昱,张彦迪,刘银河.CO2/H2O气氛下红沙泉煤中碱(土)金属的分布及其气化反应特性[J].燃料化学学报,2022,50(6):674-682. |
| 13 | GUAN Yu, ZHANG Yandi, LIU Yinhe.Distribution of alkaline(earth) metals and gasification reaction characteristics of HSQ coal under CO2/H2O atmosphere[J].Journal of Fuel Chemistry and Technology,2022,50(6):674-682. |
| 14 | HOWANIEC N.Temperature induced development of porous structure of bituminous coal chars at high pressure[J].Journal of Sustainable Mining,2016,15(3):120-124. |
| 15 | GLENK G, REICHELSTEIN S.Economics of converting renewable power to hydrogen[J].Nature Energy,2019,4(3):216-222. |
| 16 | GUIZANI C, ESCUDERO-SANZ F J, SALVADOR S.The gasification reactivity of high-heating-rate chars in single and mixed atmospheres of H2O and CO2 [J].Fuel,2013,108:812-823. |
| 17 | MASSOUDI-FARID M, HWANG J.Competition between H2O and CO2 for active sites during co-gasification of bituminous coal and pineapple sawdust in an atmosphere containing H2O,CO2,H2,and CO[J].Fuel,2017,207:198-203. |
| 18 | ROBERTS D G, HARRIS D J.Char gasification kinetics in mixtures of CO2 and H2O:The role of partial pressure in determining the extent of competitive inhibition[J].Energy & Fuels,2014,28(12):7643-7648. |
| 19 | UMEMOTO S, KAJITANI S, HARA S.Modeling of coal char gasification in coexistence of CO2 and H2O considering sharing of active sites[J].Fuel,2013,103:14-21. |
| 20 | BAI Yonghui, LV Peng, YANG Xuhao,et al.Gasification of coal char in H2O/CO2 atmospheres:Evolution of surface morphology and pore structure[J].Fuel,2018,218:236-246. |
| 21 | GAO Meiqi, LV Peng, YANG Zhirong,et al.Effects of Ca/Na compounds on coal gasification reactivity and char characteristics in H2O/CO2 mixtures[J].Fuel,2017,206:107-116. |
| 22 | LIU Rui, ZHANG Yan, ZHENG Ling,et al.Some new insights into the synergy occurring during char gasification in CO2/H2O mixtures[J].Fuel,2020,268.Doi:10.1016/j.fuel.2020.117307 . |
| 23 | GIL M V, RIAZA J, áLVAREZ L,et al.Biomass devolatilization at high temperature under N2 and CO2:Char morphology and reactivity[J].Energy,2015,91:655-662. |
| 24 | WEI Juntao, GUO Qinghua, HE Qing,et al.Co-gasification of bituminous coal and hydrochar derived from municipal solid waste:Reactivity and synergy[J].Bioresource Technology,2017,239:482-489. |
| 25 | KORUS A, RAVENNI G, LOSKA K,et al.The importance of inherent inorganics and the surface area of wood char for its gasification reactivity and catalytic activity towards toluene conversi- on[J].Renewable Energy,2021,173:479-497. |
| 26 | MASSOUDI FARID M, JEONG H J, HWANG J.Kinetic study on coal-biomass mixed char co-gasification with H2O in the presence of H2 [J].Fuel,2016,181:1066-1073. |
| 27 | PARTHASARATHY P, K.S NARAYANAN.Hydrogen production from steam gasification of biomass:Influence of process parameters on hydrogen yield-A review[J].Renewable Energy,2014,66:570-579. |
| 28 | ELLIS N, MASNADI M S, ROBERTS D G.Mineral matter interactions during co-pyrolysis of coal and biomass and their impact on intrinsic char co-gasification reactivity[J].Chemical Engineering Journal,2015,279:402-408. |
| 29 | XU Deliang, YANG Liu, DING Kuan,et al.Mini-review on char catalysts for tar reforming during biomass gasification:The importance of char structure[J].Energy & Fuels,2020,34(2):1219-1229. |
| 30 | JAYARAMAN K, GOKALP I, JEYAKUMAR S.Estimation of synergetic effects of CO2 in high ash coal-char steam gasificati-on[J].Applied Thermal Engineering,2017,110:991-998. |
| 31 | 黄艳琴,苏德仁,阴秀丽,等.木粉焦CO2和H2O气化过程孔结构及反应性的变化[J].燃料化学学报,2011,39(6):432- 437. |
| 31 | HUANG Yanqin, SU Deren, YIN Xiuli,et al.Changes of pore structure and reactivity during CO2 and H2O gasification of fir char[J].Journal of Fuel Chemistry and Technology,2011,39(6):432-437. |
| 32 | SHENG Changdong.Char structure characterised by Raman spectroscopy and its correlations with combustion reactivity[J].Fuel,2007,86(15):2316-2324. |
| 33 | LI Xiao, CHANG Guozhang, YANG Laishun,et al.Enhancement of coke gasification by lignite and a low-cost Fe/red mud catalyst to produce syngas[J].Journal of the Energy Institute,2021,98:116-123. |
| 34 | FENG Dongdong, ZHAO Yijun, ZHANG Yu,et al.Catalytic mechanism of ion-exchanging alkali and alkaline earth metallic species on biochar reactivity during CO2/H2O gasification[J].Fuel,2018,212:523-532. |
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