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浙江大学学报(工学版)
Journal of ZheJiang University (Engineering Science)  2020, Vol. 54 Issue (12): 2336-2343    DOI: 10.3785/j.issn.1008-973X.2020.12.008
    
Effect of gas composition on discharge characteristics of electrostatic precipitator
Hao-lin WANG(),Zhong-yang LUO*(),Ming-chun HE,Dan SHEN
College of Energy Engineering, Zhejiang University, Hangzhou 310027, China
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Abstract  

The volt ampere characteristics of electrostatic precipitator under different gas composition were studied by experiments and numerical simulation, and a corona discharge model of simulated flue gas was established by COMSOL software in order to analyze the influence mechanism of concentration changes of O2, H2O and CO2 in flue gas on the negative corona discharge characteristics. Results show that when the CO2 concentration increases and the O2 concentration decreases, the corona onset voltage increases, the current is negatively correlated with the CO2 concentration at low voltage, and positively at high voltage. When the relative humidity increases, the corona onset voltage decreases. The current is positively correlated with the relative humidity at low voltage and negatively at high voltage. With the increasing of CO2 concentration and the decreasing of O2 concentration, the number of electrons increases. When the relative humidity increases, the number of anion clusters increases and the mobility of ions decreases. The increasing of CO2 concentration and relative humidity contributes to the increasing of space charge density, which is conducive to enhancing the diffusion charge and the removal of fine particles.

Key wordselectrostatic precipitator      ion products      current      space charge density      particle charging     
Received: 07 November 2019      Published: 31 December 2020
CLC:  TK 284  
  X 513  
Corresponding Authors: Zhong-yang LUO     E-mail: 21727098@zju.edu.cn;zyluo@zju.edu.cn
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Hao-lin WANG
Zhong-yang LUO
Ming-chun HE
Dan SHEN
Cite this article:

Hao-lin WANG,Zhong-yang LUO,Ming-chun HE,Dan SHEN. Effect of gas composition on discharge characteristics of electrostatic precipitator. Journal of ZheJiang University (Engineering Science), 2020, 54(12): 2336-2343.

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http://www.zjujournals.com/eng/10.3785/j.issn.1008-973X.2020.12.008     OR     http://www.zjujournals.com/eng/Y2020/V54/I12/2336


烟气成分对静电除尘器放电特性的影响

为了研究烟气中O2、H2O、CO2体积分数变化对负电晕放电特性的影响机理,采用实验和数值模拟方法分析静电除尘器在不同气体成分下的伏安特性,应用COMSOL软件建立模拟烟气的电晕放电模型. 研究结果表明:当CO2体积分数增大,O2体积分数降低时,起晕电压增大,电流在低电压时与CO2体积分数负相关,在高电压时正相关;当相对湿度增大时,起晕电压降低,电流在低电压时与相对湿度正相关,在高电压时负相关;当CO2体积分数增大,O2体积分数降低时,电子数量增大;当相对湿度增大时,空间中的负离子团数量增大,离子迁移率降低. CO2体积分数和相对湿度增大,空间电荷密度增大,有利于增大扩散荷电量,从而提高细微颗粒物的脱除效率.


关键词: 静电除尘器,  离子产物,  电流,  空间电荷密度,  颗粒荷电 
Fig.1 Experimental system diagram for volt ampere characteristics of simulated flue gas
Fig.2 Model of wire-plate electrostatic precipitator
Fig.3 Volt ampere characteristic curves under different CO2-O2 volume fractions
Fig.4 Net ionization coefficient-reduced electric intensity curves under different CO2-O2 volume fractions
Fig.5 Volt ampere characteristic curves under different relative humidities
Fig.6 Net ionization coefficient-reduced electric intensity curves under different relative humidities
Fig.7 Potential distribution graph of negative corona discharge
Fig.8 Space charge density distribution graph of negative corona discharge
Fig.9 Effect of CO2-O2 volume fraction on electron density on Y-axis of model
Fig.10 Effect of O2/CO2 volume fraction on number density of CO3 and CO4 on Y-axis of model
Fig.11 Effect of O2/CO2 volume fraction on number density of CO3(H2O) and CO4(H2O) on Y-axis of model
Fig.12 Effect of relative humidity on number density of hydrated ions on Y-axis of model
Fig.13 Effect of different gas composition on space charge density on Y-axis of model
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