高压电耦合荷电液滴控制细颗粒物实验平台设计OA
Design of an experimental platform for controlling fine particulate matter using high-voltage electrically charged liquid droplets
我国细颗粒物浓度平均水平远超世界卫生组织推荐标准,大幅削弱了生态环境改善带来的保护效益.传统颗粒超低排放在颗粒控制方法协同、多变量参数耦合等方面研究不足,与实际烟气控制目标存在一定差距.文章以高效低耗控制细颗粒为导向,基于电流体动力学、气溶胶力学、通风控制等理论设计并搭建了多参数耦合实验平台,以开展运行控制参数、气流特性参数和电动力雾化参数耦合捕集颗粒研究,揭示多相混合流动模式下颗粒控制特征与脱除规律,为细颗粒物增效捕集设计和优化提供实践经验和技术方法参考,对于发展和完善气溶胶协同控制具有重要意义.
[Objective]The average concentration of fine particulate matter(PM2.5)in China significantly exceeds the World Health Organization-recommended standards,thereby undermining the environmental benefits achieved through ecological improvements.Traditional ultra-low-emission particle control strategies lack systematic investigation of method synergy and multi-parameter coupling,resulting in a gap between current practices and actual flue gas control objectives.To meet the stringent requirements for ultra-low emission of fine particulate matter,the wet electrostatic precipitator,as a preferred option for construction and retrofitting,offers notable advantages.However,it often faces challenges,including high water consumption,secondary emission pollution,and elevated operating costs.[Methods]Previous studies have demonstrated that electrohydrodynamic atomization has considerable potential for enhancing fine particle removal.This technique promotes collision,interception,and coalescence of particulate matter at reduced water consumption,thereby improving water-based removal efficiency for fine particles.Guided by the principles of efficient and low-consumption fine particle control,this study integrates electrohydrodynamics,aerosol mechanics,and ventilation control theories.By analyzing electrostatic precipitation devices reported in recent years and referencing single-parameter models,engineering prototypes,and relevant parameters,an experimental platform was designed and constructed.The platform employs high-voltage electro-coupled charged liquid droplets generated via electrokinetic atomization in combination with an electrostatic field to control fine particles;it consists of a pollutant generation system,a high-voltage power supply system,a multi-parameter coupled dust removal system,and a measurement and analysis system.Key parameters,including corona electrode configuration,dust collection electrode design,electrokinetic atomization settings,and rapping ash cleaning mechanisms,are continuously adjustable,enabling multidimensional collaborative coupling control to optimize fine particle removal performance.[Results]Using this experimental platform,the effects of key parameters,including electric field strength,residence time,and flue gas concentration,on the motion characteristics,spatial distribution,and removal efficiency of fine particles were systematically investigated.The dynamic evolution mechanism of particle capture under coupled operational control parameters,airflow characteristics,and electrokinetic atomization was elucidated.These findings provide a theoretical basis and technical support for optimizing efficient fine particle capture and offer important implications for advancing collaborative aerosol control strategies.[Conclusions]The results demonstrate that fine particle control using high-voltage electro-coupled charged liquid droplets integrates the advantages of electrohydrodynamic atomization and electrostatic fields,effectively promoting coalescence and agglomeration of fine particles into larger ones.Under the synergistic action of the electrostatic field,charged liquid droplets enhance particle capture efficiency across all size ranges,significantly reducing fractional penetration compared with a dry electrostatic precipitator.Further increases in electric field strength amplify the effectiveness of charged liquid droplets in particle removal.Moreover,under long-term operation,the dust removal device maintains clean plate surfaces and consistently high particle capture efficiency.
滕辰姊;张芸;任思达
北京市科学技术研究院,北京 100089农业农村部规划设计研究院,北京 100125首钢集团有限公司技术研究院,北京 100043
资源环境
多变量参数耦合控制方法协同电流体动力雾化颗粒捕集特征
multivariable parameter couplingcontrol method synergyelectrohydrodynamic atomizationparticle capture characteristics
《实验技术与管理》 2026 (2)
17-25,9
国家自然科学基金项目(52204200)农业农村部规划设计研究院自主研发项目(QX202418)首钢重大团队项目(K202200153H)
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