Solids flux of pulverized coal of high-pressure and dense-phase pneumatic conveying and ANN simulation

doi:10.3969/j.issn.0438-1157.2013.05.015

CIESC Journal ›› 2013, Vol. 64 ›› Issue (5): 1607-1613.DOI: 10.3969/j.issn.0438-1157.2013.05.015

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Solids flux of pulverized coal of high-pressure and dense-phase pneumatic conveying and ANN simulation

LU Peng^1,2, HAN Dong¹, PU Wenhao¹, YUE Chen¹, CHEN Xiaoping², ZHAO Changsui²

1. School of Energy and Power Engineering, Nanjing University of Aeronautics and Astronautics, Nanjing 210016, Jiangsu, China;
2. School of Energy and Environment, Southeast University, Nanjing 210096, Jiangsu, China

Received:2012-08-26 Revised:2012-11-21 Online:2013-05-05 Published:2013-05-05
Supported by:
supported by the National Basic Research Program of China(2010CB227002),the Youth’s Science & Technology Innovation Foundation of Nanjing University of Aeronautics and Astronautics(3082012NS2012084)and the Teacher’s Research Start-up Foundation of Nanjing University of Aeronautics and Astronautics(1002-56YAH11030).

高压密相气力输送煤粉输送速率通量及神经网络模拟

鹿鹏^1,2, 韩东¹, 蒲文灏¹, 岳晨¹, 陈晓平², 赵长遂²

1. 南京航空航天大学能源与动力学院, 江苏南京 210016;
2. 东南大学能源与环境学院, 江苏南京 210096

通讯作者: 鹿鹏
作者简介:鹿鹏(1981-),男,博士,讲师。
基金资助:
国家重点基础研究发展计划项目(2010CB227002);江苏高校优势学科建设项目;南京航空航天大学青年科技创新基金项目(3082012NS2012084);南京航空航天大学引进人才启动项目(1002-56YAH11030)。

Abstract

Abstract: By changing operating conditions, such as conveying pressure P₁, total differential pressure ΔP_T and fluidizing gas flow rate Q_f, and by changing properties of pulverized coal, such as particle size d_p, moisture content W and coal category, experimental investigations on solids flux ψ of pulverized coal were conducted on a pilot scale experimental setup of high-pressure and dense-phase pneumatic conveying. Considering the complexity of high-pressure and dense-phase solids-gas flow, artificial neural network(ANN)was introduced based on sufficient experiments.Original BP neural network and two kinds of improved algorithm were used and their simulation and prediction results were compared.The results showed that ψ increased with P₁ and ΔP_T, and it increased firstly and then decreased with Q_f.ψ reduced with the increase of d_p and W, and it was also affected by coal category.The two kinds of improved algorithm in BP neural network could successfully simulate and predict ψ of pulverized coal, however, convergence speed and prediction accuracy could not be satisfied simultaneously.The work in this paper can guide the control, operation, simulation and prediction of key characteristic parameters for high-pressure and dense-phase pneumatic conveying system.

Key words: high-pressure, pneumatic conveying, solid flux, neural network

摘要： 在高压密相气力输送中试试验台上,研究了输送压力P₁、总差压ΔP_T和流化风量Q_f等操作条件,以及煤粉平均粒径d_p、含水率W和煤粉种类等物性参数对煤粉输送速率通量ψ的影响规律。鉴于高压密相气固两相流的复杂性,在充分试验的基础上,先后采用原始BP神经网络和两种改进算法,对ψ进行模拟和预测,并比较各算法的优劣。研究结果表明:ψ随着P₁和ΔP_T的增大而增大,随着Q_f的增大而先增大后减小;ψ随着d_p和W的增大而减小,也受煤粉种类的影响;两种改进算法的BP网络可以对研究对象进行较好的模拟和预测,但收敛速度和预测精度不可兼得。试验结果将对高压密相气力输送系统的操作运行以及关键特征参数的模拟预测起到一定的指导作用。

关键词: 高压, 气力输送, 输送速率通量, 神经网络

CLC Number:

TQ536

LU Peng, HAN Dong, PU Wenhao, YUE Chen, CHEN Xiaoping, ZHAO Changsui. Solids flux of pulverized coal of high-pressure and dense-phase pneumatic conveying and ANN simulation[J]. CIESC Journal, 2013, 64(5): 1607-1613.

鹿鹏, 韩东, 蒲文灏, 岳晨, 陈晓平, 赵长遂. 高压密相气力输送煤粉输送速率通量及神经网络模拟[J]. 化工学报, 2013, 64(5): 1607-1613.

References 21

[1]	Xu Yue(徐越), Wu Yining(吴一宁), Wei Shirang(危师让).Simulation and analysis on gasification technology of a two-stage dry feed entrained flow bed[J].Proceedings of the Chinese Society of Electrical Engineering(中国电机工程学报), 2003, 23(10):186-190
[2]	Molerus O.Overview:pneumatic transport of solids[J].Powder Technology, 1996, 88(3):309-321
[3]	Molerus O, Heucke U.Pneumatic transport of coarse grained particles in horizontal pipes[J].Powder Technology, 1999, 102(2):135-150
[4]	Li Hui, Tomita Yuji.Particle velocity and concentration characteristics in a horizontal dilute swirling flow pneumatic conveying[J].Powder Technology, 2000, 107(1/2):144-152
[5]	Wypych Peter W, Yi Jianglin.Minimum transport boundary for horizontal dense-phase pneumatic conveying of granular materials[J].Powder Technology, 2003, 129(1/2/3):111-121
[6]	Sanchez L, Vasquez N A, Klinzing G E, Dhodapkar S.Evaluation of models and correlations for pressure drop estimation in dense phase pneumatic conveying and an experimental analysis[J].Powder Technology, 2005, 153(3):142-147
[7]	Gong Xin(龚欣), Guo Xiaolei(郭晓镭), Dai Zhenghua(代正华), Feng Jinhua(封金花), Chen Jinfeng(陈金峰), Zheng Yaohui(郑耀辉), Chen Feng(陈锋), Xiong Lang(熊浪), Yu Zunhong(于遵宏).High solids loading pneumatic conveying of pulverized coal[J].Journal of Chemical Industry and Engineering(China)(化工学报), 2006, 57(3):640-644
[8]	Shen Xianglin(沈湘林), Xiong Yuanquan(熊源泉).Experimental study on dense-phase pneumatic conveying of pulverized coal at high pressures[J].Proceedings of the Chinese Society of Electrical Engineering(中国电机工程学报), 2005, 25(24):103-107
[9]	Liu Bin(刘彬), He Chunhui(贺春辉), Yan Jinpei(颜金培), Wang Jianhao(王建豪), Ni Hongliang(倪红亮), Shen Xianglin(沈湘林).Experimental study on dense phase pneumatic conveying of pulverized coal at high pressure using carbon dioxide as carrier[J].Proceedings of the Chinese Society of Electrical Engineering(中国电机工程学报), 2010, 30(11):21-26
[10]	Liang C, Zhao C S, Chen X P, Pu W H, Lu P, Fan C L.Flow characteristics and Shannon entropy analysis of dense-phase pneumatic conveying of pulverized coal with variable moisture content at high pressure[J].Chemical Engineering & Technology, 2007, 30(7):926-931
[11]	Chen Xiaoping, Fan Chunlei, Liang Cai, Pu Wenhao, Lu Peng, Zhao Changsui.Investigation on characteristics of pulverized coal dense-phase pneumatic conveying under high pressure[J].Korean Journal of Chemical Engineering, 2007, 24(3):499-502
[12]	Xiong Yanjun(熊焱军), Guo Xiaolei(郭晓镭), Gong Xin(龚欣), Huang Wanjie(黄万杰), Zhao Jinchao(赵锦超), Lu Haifeng(陆海峰).Blockage critical state of pulverized coal dense-phase pneumatic conveying in horizontal pipe[J].CIESC Journal(化工学报), 2009, 60(6):1421-1426
[13]	Ma Sheng(马胜), Guo Xiaolei(郭晓镭), Gong Xin(龚欣), Huang Wanjie(黄万杰), Lu Haifeng(陆海峰), Liu Kai(刘剀).Flow regime of pulverized coal in dense-phase pneumatic conveying system[J].CIESC Journal(化工学报), 2010, 61(6):1415-1422
[14]	Dong Weibin(董卫宾), Guo Xiaolei(郭晓镭), Gong Xin(龚欣), Yong Xiaojing(雍晓静), Wu Yue(吴跃), Luo Chuntao(罗春桃).Characteristic of top discharge blow tank conveying system and comparison with bottom discharge blow tank conveying system[J].CIESC Journal(化工学报), 2011, 62(7):1989-1997
[15]	Xu Guiling(徐贵玲), Chen Xiaoping(陈晓平), Liang Cai(梁财), Zhao Changsui(赵长遂), Xu Pan(许盼), Bu Changsheng(卜昌盛), Zhang Tienan(张铁男).Top discharge blow tank pneumatic conveying characteristics of pulverized coal[J].CIESC Journal(化工学报), 2012, 63(6):1709-1716
[16]	Duan Yubo(段玉波), Liu Jicheng(刘继承), Wang Qiong(王琼).Application of RBF neural network to ultrasonic holdup measurement for water-oil two-phase flow[J].Information and Control(信息与控制), 2005, 34(4):1709-1716
[17]	Wu Xinjie(吴新杰), Wang Shi(王师).The method for measuring solid velocity based on linear neural networks[J].Chinese Journal of Scientific Instrument(仪器仪表学报), 2000, 21(4):343-345
[18]	Zhou Yunlong(周云龙), Sun Bin(孙斌), Lu Jun(陆军).Application of improved BP neural network in identification of air-water two-phase flow patterns[J].Journal of Chemical Industry and Engineering(China)(化工学报), 2005, 56(1):110-115
[19]	Wang F J, Zhu J X, Beeckmans J M.Pressure gradient and particle adhesion in the pneumatic transport of cohesive fine powders[J].International Journal of Multiphase Flow, 2000, 26(2):245-265
[20]	Feisi Technology Product R&D Center(飞思科技产品研发中心).Theory of Neural Network and MATLAB7 Realization(神经网络理论与MATLAB7实现)[M].Beijing:Electronic Industry Press, 2005:44
[21]	Hagan T, Demuth H, Beale M.Neural Network Design(神经网络设计)[M].Beijing:Mechanical Engineering Press, 2002:232-244

Solids flux of pulverized coal of high-pressure and dense-phase pneumatic conveying and ANN simulation

高压密相气力输送煤粉输送速率通量及神经网络模拟

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