Numerical analysis of collision characteristics between charged drop and neutral droplet under uniform electric field

Li, Jiawei; Li, Chuan; Wang, Pengyu; He, Fuyou; Xiao, Menghan; Zhang, Ming; Yang, Yong; Yu, Kun; Pan, Yuan

doi:10.1088/1361-6463/ac16fb

Cited by 3 publications

(2 citation statements)

References 28 publications

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“…As a type of particle, the charging of fog droplets also follows these mechanisms. The dominant charging mechanism depends on the particle size [25,26]. For particles larger than 0.5 µm, the main charging mechanism is field charging; for particles smaller than 0.2 µm, the main charging mechanism is diffusion charging [10].…”

Section: Analysis Of Fog Droplet Behaviormentioning

confidence: 99%

Deconstructing plasma fog collection technology: an experimental study on factors impacting collection efficiency

Li,

Xiao

et al. 2023

J. Phys. D: Appl. Phys.

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Water scarcity is a global challenge that hinders human development. In recent years, electrostatic fog collection technology has emerged as a promising technology to alleviate this issue. Although electrostatic fog collectors based on a variety of electrode structures have been developed previously, there has been less research into other factors affecting the efficiency of electrostatic fog collection (e.g. electrical factors, environmental factors, etc), which has delayed the commercial application of the technology. In this paper, we experimentally investigate the effects of power supply polarity, voltage, airflow direction, airflow velocity, fog concentration and temperature on collection efficiency using a typical wire-mesh electrode fog collector as an example. The results show that both electrical and environmental factors influence the collection efficiency by changing the charge and the electric field force of the droplets. Negative polarity corona and high voltage are more favorable for fog collection. High velocity airflow and high fog concentration increase the amount of water collected due to the ability to bring more droplets into the electric field. However, the collection efficiency is reduced by the weakening of the corona discharge. High temperature accelerates the evaporation of fog droplets, which is not favorable for fog collection. In conclusion, this work will not only contribute to revealing the underlying mechanisms of the electrostatic fog collection but also will guide the development of highly efficient fog collectors.

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Section: Analysis Of Fog Droplet Behaviormentioning

confidence: 99%

Deconstructing plasma fog collection technology: an experimental study on factors impacting collection efficiency

Li,

Xiao

et al. 2023

J. Phys. D: Appl. Phys.

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“…It excels by introducing an electrostatic force, which overcomes the air drag force and minimizes aerodynamic limitations in inertial collisions. In addition to the above two forces, an extended mechanical model including gravity and an applied electric field force has been studied in detail [30]. The results show that the collision rate increases with the applied electric field, but the collision probability decreases first and then increases.…”

Section: Introductionmentioning

confidence: 99%

Numerical simulation of the enhancing effect of micro–nano protrusions on electrostatic fog harvesting

Zhang

Xiao

et al. 2023

J. Phys. D: Appl. Phys.

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Fog harvesting is one potential approach to provide supplementary water resources in arid areas. Considerable researches have been devoted to electrostatic fog harvesting technology, but there are still some problems such as high voltage, complex structure and expensive cost. Decorating micro-nano protrusions on the electrode is an effective method to lower operating voltage, improve fog harvesting efficiency, and the enhancement effect of protrusions has already been experimentally demonstrated. However, the enhancement mechanism on the microscopic level is less reported. This manuscript tries to explain why the micro-nano protrusions can enhance the discharge and fog harvesting by numerical simulation. Three key processes of corona discharge, fog droplet migration, and fog harvesting efficiency are discussed in detail, especially the influence of droplet size, tip radius of protrusion, protrusion-protrusion angle and so on. The numerical simulation results show that the inception voltage of barbed electrode decreases from 7 kV to 3 kV (decrease in 57%), and current increases significantly (e.g. 68% at 15 kV). At 15 kV, the fog harvesting efficiency of barbed electrode is higher (29.8%) than that of smooth wire (25.7%), even with less effective collection area. The collection efficiency increases with the droplet size and exists an optimized ratio (~1‰) of protrusion tip radius and wire radius to gain high collection efficiency. This research results are beneficial for understanding the microscopic mechanism of protrusions enhancing electrostatic fog harvesting and providing guidance for further fog harvesting equipment improvement.

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Efficient Corona Discharge Fog Collector: Multiple Mesh Electrodes with Electric Field Enhances Fog Harvesting

et al. 2022

Plasma Chem Plasma Process

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Numerical analysis of collision characteristics between charged drop and neutral droplet under uniform electric field

Cited by 3 publications

References 28 publications

Deconstructing plasma fog collection technology: an experimental study on factors impacting collection efficiency

Deconstructing plasma fog collection technology: an experimental study on factors impacting collection efficiency

Numerical simulation of the enhancing effect of micro–nano protrusions on electrostatic fog harvesting

Efficient Corona Discharge Fog Collector: Multiple Mesh Electrodes with Electric Field Enhances Fog Harvesting

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