Structural optimization of baffle internals for fast particle pyrolysis in a downer reactor using the discrete element method

导出

摘要 The structural optimization of baffle internals for fast pyrolysis of coal with particulate mixing and heat transfer in a downer reactor using the discrete element method(DEM)has been investigated in this research.The pyrolysis terminal temperature at the exit of the downer reactor is not only decided by the volume-feeding-rate ratio of the coal to the sand,but also is affected by the inner structural design of the baffle internals in the downer reactor.As presented in the previous publication of the author,the inhibition from the baffle internals in a downer reactor can improve the particulate-mixing degree and heat carrier,and increase the mean residence time of the coal and heat-carrier particles in the downer reactor.The structure of the baffle internals in the downer reactor mentioned in this research can be optimized by the independently developed 3D soft-sphere model of the DEM programme of a 40-mm baffle length,a 30°baffle-slope angle and at least four baffles designed in the downer reactor,which is beneficial for the process design of coal pyrolysis with a heat carrier in the downer reactor.

作者 Bing Liu

机构地区 National Institute of Clean-and-Low-Carbon Energy

出处《Clean Energy》 EI 2021年第2期167-179,共13页 清洁能源（英文）

关键词 structural optimization baffle internals downer reactor DEM coal pyrolysis

分类号 O35 [理学—流体力学]

引文网络
相关文献

参考文献2

1Bing Liu.Algorithm design and the development of a discrete element method for simulating particulate flow and heat transfer[J].Clean Energy,2021,5(2):141-166. 被引量：1
2刘安源,刘石.流化床内颗粒碰撞传热的理论研究[J].中国电机工程学报,2003,23(3):161-165. 被引量：28

二级参考文献12

1[2]Yagi S, Kunii D. Studies on effective thermal conductivities in packed beds [J]. AIChE Journal, 1957, 3(3):373-381. 被引量：1
2[3]Wen C Y, Chang T M. Particle to particle heat transfer in air fluidized beds [A]. Proceedings of International Symposium on Fluidization, edited by drinken-burg[C] A A H, Eindhoven, Part 2, 1967,491-506. 被引量：1
3[4]Sun J, Chen M M. A theoretical analysis of heat transfer due to particle impact [J]. Int. J. Heat Mass Transfer, 1988, 31(5):969-975. 被引量：1
4[5]Delvosalle C, Vanderschuren J. Gas to particle and particle to particle heat transfer in fluidized beds of large particles [J]. Chemical Engineering Science, 1985, 40(4):769-779. 被引量：1
5[6]Rong D. DEM simulation of hydrodynamics, heat transfer and combustion in fluidized beds [D]. Tokyo University of Agriculture and Technology, Japan, 2000. 被引量：1
6[7]Cundall P A, Strack O D L. A discrete numerical model for granular assemblies [J]. Geotechnique, 1979, 29(1):47-65. 被引量：1
7[8]Tsuji Y, Kawaguchi T, Tanaka T. Discrete particle simulation of two-dimensional fluidized bed [J]. Powder Technology, 1993, 77(1):79-87. 被引量：1
8[9]Ranz W E, Marshall W R. Evaporation from drops [J]. Chemical Engineering Progress, 1952, 48(3):141-146. 被引量：1
9[10]Syamlal M, Gidaspow D. Hydrodynamics of fluidization: prediction of wall tobed heat transfer coefficients [J]. AIChE Journal, 1985, 31(1):127-135. 被引量：1
10[11]Ozkaynak T, Chen J C. Emulsion phase residence time and its use in heat transfer models in fluidized bed [J]. AIChE Journal, 1980, 26(4):544. 被引量：1

共引文献27

1周浩生,陆继东.流化床内煤粒燃烧过程的数值模拟[J].中国电机工程学报,2004,24(12):212-217. 被引量：11
2刘安源,刘石,马玉峰,宗承云.流化床锅炉热烟气点火过程的离散颗粒模拟[J].中国电机工程学报,2005,25(3):120-124. 被引量：11
3刘阳,陆慧林,黄本诚.重力条件对稠密气固两相流动特性影响的数值模拟[J].中国电机工程学报,2005,25(20):83-88. 被引量：1
4刘安源,刘石,马玉峰,宗承云.流化床表面传热系数的直接数值模拟[J].燃烧科学与技术,2005,11(6):515-519. 被引量：4
5武锦涛,陈纪忠,阳永荣.移动床中颗粒接触传热的数学模型[J].化工学报,2006,57(4):719-725. 被引量：23
6田凤国,章明川,齐永锋,顾明言,张健,范浩杰.流化床轴径向混合特性的数值研究[J].中国电机工程学报,2006,26(21):119-124. 被引量：12
7刘安源,刘石.流化床内单个颗粒传热特性的模拟[J].工程热物理学报,2006,27(5):835-837. 被引量：1
8常剑,高金森,徐春明.气固两相流中颗粒间碰撞传热进展[J].计算机与应用化学,2007,24(4):425-428. 被引量：3
9李志合,崔喜彬,柏雪源,易维明,李永军.固体热载体与生物质颗粒之间的传热研究[J].农业机械学报,2010,41(S1):128-132. 被引量：4
10李志合,易维明,刘焕卫.陶瓷球固体热载体与粉状生物质的热平衡分析[J].农业机械学报,2009,40(7):103-106. 被引量：3

1Juanbo Liu,Xinhua Liu,Zhixin Zhang,Hui Zhao,Wei Ge.Modeling the axial hydrodynamics of gas-solid counter-current downers[J].Particuology,2020,18(3):135-143. 被引量：8
2Xueer Pan,Wenhao Lian,Jingxuan Yang,Junli Wang,Zhonglin Zhang,Xiaogang Hao,Abuliti Abudula,Guoqing Guan.Downer reactor simulation and its application on coal pyrolysis:A review[J].Carbon Resources Conversion,2022,5(1):35-51. 被引量：6
3Qiang Zheng,Jingxuan Yang,Wenhao Lian,Baoping Zhang,Xueer Pan,Zhonglin Zhang,Xiaogang Hao,Guoqing Guan.Multi-fluid Eulerian simulation of binary particles mixing and gas–solids contacting in high solids-flux downer reactor equipped with a lateral particle feeding nozzle[J].Chinese Journal of Chemical Engineering,2021,34(7):152-162. 被引量：5
4王晓芳,顾雅娟,吴勇斌.三大船型应用甲醇燃料满足EEDI3阶段可行性分析[J].机电技术,2022(3):77-81. 被引量：2
5宋焕富,郑宏鼎.体外冲击波联合系统康复训练对胫骨平台骨折患者术后功能康复的影响[J].反射疗法与康复医学,2021(7):113-115.
6Yanan Qian,Jin-Hui Zhan,Wei Xu,Zhennan Han,Xiaoxing Liu,Guangwen Xu.ReaxFF molecular dynamic simulation of primary and secondary reactions involving in sub-bituminous coal pyrolysis for tar production[J].Carbon Resources Conversion,2021,4(1):230-238. 被引量：5
7Zhaohui Chen,Deliang Wang,Hang Yang,Yusheng Zhang,Yunjia Li,Changming Li,Jian Yu,Shiqiu Gao.Novel application of red mud as disposal catalyst for pyrolysis and gasification of coal[J].Carbon Resources Conversion,2021,4(1):10-18. 被引量：3
8Bing Liu.Algorithm design and the development of a discrete element method for simulating particulate flow and heat transfer[J].Clean Energy,2021,5(2):141-166. 被引量：1
9E.Amani,A.Daneshgar,A.Hemmatzade.A novel combined baffle-cavity micro-combustor configuration for Micro-Thermo-Photo-Voltaic applications[J].Chinese Journal of Chemical Engineering,2020,28(2):403-413.
10Lijuan Zhang,Cheolyong Choi,Hiroshi Machida,Zhibao Huo,Koyo Norinaga.Catalytic hydrotreatment of alkaline lignin and its consequent influences on fast pyrolysis[J].Carbon Resources Conversion,2021,4(1):219-229.

Clean Energy

2021年第2期

浏览历史

内容加载中请稍等...

Structural optimization of baffle internals for fast particle pyrolysis in a downer reactor using the discrete element method

参考文献2

二级参考文献12

共引文献27

相关作者

相关机构

相关主题

浏览历史