Your search keyword '"Particle"' showing total 8 results

1. Effective Use of External Electric Field for Charging and Levitation of Particles Under UV Irradiation.

Author

Shoyama, Mizuki, Sugaya, Taiki, and Matsusaka, Shuji

Subjects

*ELECTRIC fields, *LEVITATION, *PARTICLE motion, *CHARGE transfer, *ELECTRIC lighting, *IRRADIATION, *ELECTRIC charge

Abstract

Electrostatic forces can be used to control the motion of charged particles. In this article, particle charging and motion in an electric field under ultraviolet (UV) irradiation were investigated. When the particle layers deposited on an insulating substrate were irradiated with UV light in a downward electric field, photoelectrons were emitted, and positive charges moved to the bottom of the particle layers. Subsequently, by reversing the direction of the electric field, the positive charges in the bottom moved upward; thus, the particles in the top layer were positively charged and levitated by Coulomb forces. The flux of the levitated particles increased with an increase in the strength of the electric field (downward and upward). As the upward electric field strength increased, the number of agglomerated particles in the levitation increased; however, the particle charge decreased. As the thickness of the particle layers increased, the time delay for particle levitation increased; however, the flux of the levitated particles decreased. The ratio of agglomerated particles to the total levitated particles increased. These results can be explained by the mechanisms of charge transfer and particle levitation. [ABSTRACT FROM AUTHOR]

Published

2022

2. Charging and Levitation of Particles Using UV Irradiation and Electric Field.

Author

Shoyama, Mizuki, Yoshioka, Hironobu, and Matsusaka, Shuji

Subjects

*ELECTRIC fields, *LEVITATION, *ELECTROSTATIC precipitation, *EQUATIONS of motion, *PARTICLE motion, *GLASS beads

Abstract

The charging and levitation of particles using UV irradiation in an upward electric field were investigated. Glass beads with a mass median diameter of 61 μm were used for the experiments. The particle layers formed on a glass plate were irradiated by UV light with wavelengths ranging from 240 to 400 nm. The particles in the top layer were positively charged by photoemission and levitated by the electrostatic forces. The fluxes and motions of the levitated particles were analyzed by digital processing of the images obtained with a high-speed camera. The charge of each levitated particle was determined by fitting the results calculated using the equation of motion to the experimentally obtained particle motion. The charge of the particles beginning to be levitated was determined by the force balance and thus was not affected by the UV irradiance. The positive charge of the levitated particles could be increased by continuous photoemission from the particles and decreased by the capture of photoelectrons emitted by other particles. Approximately 40% of the levitated particles descended because of the negative charge clouds formed by the photoemission from the particle layers and the levitated particles. Furthermore, in a second set of experiments, an upward electric field was applied after UV irradiation. In these experiments, the particles in the top layer were levitated after applying the electric field. These particles could be gain more excess charges than the particles for which the levitation was governed by the force balance. [ABSTRACT FROM AUTHOR]

Published

2022

3. Numerical Analysis and Experiments on the Electromechanical Behavior of Wired-Shape Conducting Particles.

Author

Techaumnat, Boonchai, Huynh, Viet Q., and Hidaka, Kunihiko

Subjects

*NUMERICAL analysis, *ELECTROMECHANICAL devices, *BOUNDARY element methods, *PARAMETER estimation, *ELECTRIC fields, *PROBABILITY theory

Abstract

This paper presents the numerical analysis and experiments on the electromechanical behavior of conducting wired-shape particles. We investigate the effects of particle ending profiles and orientation on the initial motion. The boundary element method is used to analyze the electric field, forces, and torques on the particles. The calculated liftoff electric field is smaller than the estimated value based on a model of infinitely long cylinder, and slightly decreases for a particle with a sharp end when the sharp tip is separated from the electrode. The measured liftoff electric field agrees with the tendency obtained from the numerical analysis. Particles mostly began the motion at either end. When the sharp tip was separated from the electrode, the initial motion almost exclusively took place at the sharp end. On the other hand, the probability was slightly higher for the motion at the rounded end when the sharp tip was close to the electrode. The numerical calculation clarifies that the electrostatic and gravitational torques contribute to such liftoff behavior. [ABSTRACT FROM AUTHOR]

Published

2018

4. Experimental study on the movement of non-spherical particles in nonuniform electric field.

Author

Sangsri, Tatchawin and Techaumnat, Boonchai

Subjects

*PARTICULATE matter, *ELECTRIC field lines, *ELECTRIC field strength, *ELECTROMAGNETIC fields

Abstract

The deactivation of free particles is an important issue for improving the insulating capability and reliability of high-voltage systems. In this work, we carry out experiments to investigate the electromechanical behavior of the non-spherical conducting particles for different particle orientations on either bare or coated electrode. Spheroidal and wire-shaped particles are used for the experiments. The particle motion is observed for two principal orientations with respect to the applied electric field in air. The results show that on a bare electrode, both kinds of particles exhibit the liftoff motion when the particle axis is aligned with electric field gradient. The field nonuniformity enhances the upward rotation of the particle tip subjected to the higher electric field. When the particle axis is parallel with a constant field line, the wire-shaped particle is more readily to make a rolling motion to the region of stronger electric field in comparison with the spheroidal particle, which shows higher occurrence rate of liftoff. The motion onset electric field decreases with increasing field nonuniformity. On the insulated electrode, the wire-shaped particle shows exclusively the rolling motion, whereas the spheroidal particle may make a rolling motion or rotate horizontally so as to align its axis with electric field gradient. [ABSTRACT FROM PUBLISHER]

Published

2017

5. Influence of forest fire particles on the breakdown characteristics of air gap.

Author

Li, Peng, Huang, Daochun, Ruan, Jiangjun, Wei, Han, Qin, Zhihang, Long, Mingyang, Pu, Ziheng, and Wu, Tian

Subjects

*FOREST fires, *PARTICLE size distribution, *ELECTRIC breakdown, *AIR gap (Engineering), *ELECTRIC lines, *ELECTRIC insulators & insulation

Abstract

The frequent forest fires become a serious threat to the performance of transmission lines' external insulation. Gap breakdown in forest fire relates to many factors, such as flame temperature, conductivity and particles. Large quantities of smoke (carbon black) and flying ash are produced during the combustion of vegetation, causing the dielectric strength of gap to decrease drastically. In order to analyze the influence of forest fire particles on the breakdown characteristics of air gap, the experimental setup consisting of a conductor-plane was built to simulate the effect of forest fire particles. At the same time, a theoretical model was developed to analyze the influence mechanism of multiple particles on the discharge characteristics of gap. Experimental results show that, a chain of carbon particles has been formed between flame and conductor by the action of electric field. The gap's insulation strength decreases significantly, which is about 40% of that in the pure air under AC voltage. The particles movement and the breakdown characteristics of air gap have an evident effect of polarity characteristic under DC voltage and the breakdown voltage is reduced to about 29% of that in the air gap under negative DC voltage. The simulation results show that, the electric field distribution between conductor and plane become uneven, and the distortion degree of the elongated particle to the background electric field is not related to the distance between particles with high-voltage electrode. According to the electric field diagram, it is obvious that the particles make the background electric field distortion, and the maximum field strength increased by about 100%. More close to the conductor, the greater electric field strength is at the both ends of particles. [ABSTRACT FROM AUTHOR]

Published

2016

6. Phenomena and Mechanism of Electric Charges on Spacers in Gas Insulated Switchgears.

Author

Okabe, Shigemitsu

Subjects

*ELECTRIC discharges, *ELECTROSTATICS, *ELECTRIC action of points, *ELECTRIC fields, *ELECTRIC utilities, *ELECTRIC power, *INDUSTRIAL engineering, *POWER resources

Abstract

The phenomenon of accumulated charges on solid insulator surfaces is one of the critical parameters to consider at the insulation design stage, for ac electric power equipment as well as for dc equipment, so it is important to investigate the characteristics and predominant factors underlying various charging mechanisms. Several researches related to this theme have been reported, but independently, and cross-sectional comparison and evaluation from a unified viewpoint are meaningful. In this paper, the resistance of solid insulator is first discussed, showing that the resistances found by diverse measurements are in a fairly good agreement under similar conditions of the temperature and electric field. Next, three kinds of electric charging mechanisms, i.e. volume conduction, surface conduction and electric field emission are characterized in terms of the time constant, applied voltage and charge distribution. Then, eight cases of recent measurements on the charging time are investigated and their charging mechanisms are classified. Electric field emissions are likely to occur with model spacers made in routine GIS manufacturing process at the electric field level used. Further, three examples in cases with metallic particles are introduced, of simulating charge from edge on the tank, spacer surface charging phenomena, and influence of charge on spacer surface flashover. It is expected that this paper will be helpful for understanding charging phenomena e.g. on insulation spacers in gas insulated switchgears. [ABSTRACT FROM AUTHOR]

Published

2007

7. Induction Charging of Granular Materials in an Electric Field.

Author

Yishui Wu, Castle, G. S. Peter, and Inculet, Ion I.

Subjects

*ELECTRIC fields, *ELECTROMAGNETIC fields, *GRANULAR materials, *BULK solids, *COMPACTING, *FIELD theory (Physics)

Abstract

It is well known that particles can be freely levitated in an electric field due to the charge induced on the particles by the external field. The charge depends upon the electric field strength and particle properties. This paper studies some of these factors to investigate the fundamentals of induction charging for granular materials. An experimental apparatus was set up to collect the levitated particles in a filter contained in a Faraday pail and the charge-to-mass (Q/M) ratio was obtained based on the charge and mass measurements for the samples in the filter. Furthermore, the particle size distribution was measured and analyzed by laser diffraction and microscopy and the surface mean diameter (Ds) and volume mean diameter (Dv) were obtained. In these experiments irregular shaped Al2 O3 particles and spherical glass beads with a size range of 42-390 μm were used and tested at different electric field strengths. By combining the results of Q/M, Ds and Dv, the charge per particle was calculated and the results compared with theoretical values. It was confirmed that the particle charge is dependent upon the electric field strength and the particle properties of size, shape, density, resistivity, and adhesive force. [ABSTRACT FROM AUTHOR]

Published

2005

8. On the lumped lorentz force approximation for modeling the motion of free metallic particles.

Author

Marchant, R.J., Jiang, Q., and Coombs, T.A.

Subjects

*ELECTRIC discharges, *ELECTRIC charge, *ELECTROSTATICS, *MATHEMATICAL models, *SURFACES (Technology), *NANOPARTICLES, *FINITE element method, *APPROXIMATION theory

Abstract

The force acting upon a free metallic particle in an alternating electric field will determine its motion and ultimately allow for the estimation of the risk imposed due to dielectric failure of the high voltage equipment. Existing models approximate the force with Lorentz' law and consider the charge resting upon the surface as being lumped into a point charge at the center of the particle during its motion. The model proposed in this paper demonstrates a time stepped electrostatic Finite Element Method to calculate these forces, therefore taking into account the charge distribution upon the surface of the particle. The use of this model is seen to have a significant effect upon the motion of the particle under certain conditions. [ABSTRACT FROM AUTHOR]

Published

2010