The Modeling and Magnetic Simulation of Resistance High-Voltage Divider Based on AutoCAD and Maxwell

Song, Jian Kang; Lv, Dan; Zhang, Huang Hui

doi:10.4028/www.scientific.net/amm.307.231

Cited by 2 publications

(3 citation statements)

References 2 publications

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“…The stray or parasitic capacitance to ground is closely related to the electric field distribution around the divider [25]. It can be calculated by using computer programs based on the charge distribution of the conductors [20], such as those based on FEA [12,23]. FEA models were developed using the Comsol Multiphysics ® software package by conducting a frequency domain study at 50 Hz.…”

Section: Fea Simulations To Determine the Effects Of Stray Capacitancementioning

confidence: 99%

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Analysis and Mitigation of Stray Capacitance Effects in Resistive High-Voltage Dividers

2019

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This work analyzes the effects of the parasitic or stray distributed capacitance to ground in high-voltage environments and assesses the effectiveness of different corrective actions to minimize such effects. To this end, the stray capacitance of a 130 kV RMS high-voltage resistive divider is studied because it can severely influence the behavior of such devices when operating under alternating current or transient conditions. The stray capacitance is calculated by means of three-dimensional finite element analysis (FEA) simulations. Different laboratory experiments under direct current (DC) and alternating current (AC) supply are conducted to corroborate the theoretical findings, and different possibilities to mitigate stray capacitance effects are analyzed and discussed. The effects of the capacitance are important in applications, such as large electrical machines including transformers, motors, and generators or in high-voltage applications involving voltage dividers, conductors or insulator strings, among others. The paper also proves the usefulness of FEA simulations in predicting the stray capacitance, since they can deal with a wide range of configurations and allow determining the effectiveness of different corrective configurations.

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Section: Fea Simulations To Determine the Effects Of Stray Capacitancementioning

confidence: 99%

“…Internal and external stray capacitances affect the transient response of high-voltage devices, including transformers [11] or voltage dividers [12], among others. However, measurement of the stray capacitance is usually difficult due to the small signal to be measured and the low immunity to noise [13].…”

Section: Introductionmentioning

confidence: 99%

Analysis and Mitigation of Stray Capacitance Effects in Resistive High-Voltage Dividers

2019

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“…The stray capacitance to ground is directly related to the distribution of the electric field around high-voltage electrodes [22]. It is a recognized fact that the effects of stray capacitance can be determined by means of FEM-based approaches [12,23].…”

Section: The Fem Approach To Analyze the Stray Capacitancementioning

confidence: 99%

Analysis of Capacitance to Ground Formulas for Different High-Voltage Electrodes

Riba

Capelli²

2018

Energies

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Stray capacitance can seriously affect the behavior of high-voltage devices, including voltage dividers, insulator strings, modular power supplies, or measuring instruments, among others. Therefore its effects must be considered when designing high-voltage projects and tests. Due to the difficulty in measuring the effects of stray capacitance, there is a lack of available experimental data. Therefore, for engineers and researchers there is a need to revise and update the available information, as well as to have useful and reliable data to estimate the stray capacitance in the initial designs. Although there are some analytical formulas to calculate the capacitance of some simple geometries, they have a limited scope. However, since such formulas can deal with different geometries and operating conditions, it is necessary to assess their consistency and applicability. This work calculates the stray capacitance to ground for geometries commonly found in high-voltage laboratories and facilities, including wires or rods of different lengths, spheres and circular rings, the latter ones being commonly applied as corona protections. This is carried out by comparing the results provided by the available analytical formulas with those obtained from finite element method (FEM) simulation, since field simulation methods allow solving such problem. The results of this work prove the suitability and flexibility of the FEM approach, because FEM models can deal with wider range of electrodes, configurations and operating conditions. power supplies composed of several modules in series, since in [9] it is proved that the stray capacitance to ground has a significant impact on the individual voltage of each module. In other high-voltage applications, including high-voltage transformers [10] or high-voltage motors, parasitic capacitances have a key role to predict the frequency behavior of such machines.Accurate methods to calculate the capacitance are based on the calculation of the electrostatic field generated by the system of charged objects under consideration [3]. The capacitance of basic isolated geometries, such as very long horizontal cylindrical conductors, coaxial cylindrical conductors, concentric spheres, or spheres well above ground, can be easily deduced theoretically. However, such formulas have very restricted practical use. The calculation of the capacitance of conductive objects which are close to ground leads to challenging mathematical problems, even for simple geometries. Therefore, analytical solutions for capacitance only exist for a limited number of electrode geometries and configurations, which have almost no practical applications [11], and often only contemplate the stray capacitance to ground, thus disregarding the effects of nearby grounded electrodes, structures or walls [3].As a consequence, computational methods are increasingly being applied to solve such problem, although most of the published works deal with very particular problems, such as insulator strings [4,5,7], transformer windings [10]...

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The Modeling and Magnetic Simulation of Resistance High-Voltage Divider Based on AutoCAD and Maxwell

Cited by 2 publications

References 2 publications

Analysis and Mitigation of Stray Capacitance Effects in Resistive High-Voltage Dividers

Analysis and Mitigation of Stray Capacitance Effects in Resistive High-Voltage Dividers

Analysis of Capacitance to Ground Formulas for Different High-Voltage Electrodes

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