Please use the following text to cite this item or export to a predefined format:
Zmeko, Filip; Müllerová, Eva and Martínek, Petr, 2026, Fast Calculation of the Corona Discharge Ignition Voltage Using the Nelder–Mead Optimization, DSpace at University of West Bohemia, http://hdl.handle.net/20.500.14592/109
dc.contributor.authorZmeko, Filip
dc.contributor.authorMüllerová, Eva
dc.contributor.authorMartínek, Petr
dc.date.accessioned2026-07-08T10:19:55Z
dc.date.available2026-07-08T10:19:55Z
dc.date.issued2026
dc.descriptionAccurate prediction of corona discharge ignition voltages Ui is essential for the design and reliability assessment of high-voltage (HV) systems. This article presents a combined experimental and numerical study focused on the evaluation of Ui for various electrode geometries, gap distances, and pressures in ambient or synthetic air. Based on a new analysis of experimental data, two numerical optimization models were developed and implemented in COMSOL Multiphysics to determine ignition voltages with minimal computational cost. Both models are founded on two physically motivated assumptions: a constant critical electron avalanche intensity at corona onset and symmetry of the ignition electric field profile under low field homogeneity conditions with respect to varying gap distances. The first method is based on integration of the effective ionization coefficient along the discharge path, while the second relies on the local electric field at the electrode tip. In both cases, the Nelder–Mead optimization algorithm is employed to identify the critical voltage corresponding to corona inception. The proposed methods were validated against experimental data over a wide range of pressures, electrode configurations, and field homogeneity conditions. The predicted ignition voltages show good agreement with measurements, with a typical deviation of approximately 5% and a maximum error below 10% in a limited number of cases. While the integration-based optimization provides higher robustness and reduced dependence on empirical input, the field-based optimization offers simplicity and rapid implementation. The presented approaches enable efficient parametric studies and provide practical tools for HV insulation analysis, the design of corona-resistant components, and the definition of boundary conditions (BCs) in more advanced discharge simulations.
dc.description.sponsorshipČeský inkubátor technologií pro energetické sítě EH23_020/0008490
dc.identifier.urihttp://hdl.handle.net/20.500.14592/109
dc.language.isoen
dc.publisherZápadočeská univerzita v Plzni
dc.rightsCreative Commons - Attribution-NonCommercial-NoDerivatives 4.0 International (CC BY-NC-ND 4.0)
dc.rights.labelPUB
dc.rights.urihttp://creativecommons.org/licenses/by-nc-nd/4.0/
dc.subjectCOMSOL multifyzika
dc.subjectzapálení koronového výboje
dc.subjectnehomogenní elektrostatické pole
dc.subjectintegrace ionizačního koeficientu
dc.subjectNelder-Meadův optimalizační algoritmus
dc.subjecttlaková nádoba
dc.titleFast Calculation of the Corona Discharge Ignition Voltage Using the Nelder–Mead Optimization
dc.typedataset
local.files.count1
local.files.size16976
local.has.filesyes
local.identifier.publicationshttp://hdl.handle.net/11025/64528
local.subject.translatedCOMSOL multiphysics
local.subject.translatedcorona discharge ignition
local.subject.translatedinhomogeneous electrostatic field
local.subject.translatedionization coefficient integration
local.subject.translatedNelder–Mead optimization algorithm
local.subject.translatedpressure vessel
 Files in this item
Name
Dataset.zip
Size
16.58 KB
Format
application/zip
Description
zip
MD5
dca33714d90df550c98ed805d4943437
Preview
  File Preview