Synthesis and Analysis of Arc Furnace Electrical Mode Control System on the Basis of Three-Dimensional Phase Currents Vector Distribution

Lozynskyy, Orest; Lozynskyi, A. O.; Paranchuk, Yaroslav; Paranchuk, Roman

doi:10.20998/2074-272x.2019.4.04

Cited by 4 publications

(2 citation statements)

References 9 publications

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“…The operational asymmetry is reduced by the use of the electrode position control system [20,21] and additional devices aimed at improving the energy quality [22][23][24][25]. It should also be mentioned that the arc furnaces is the source of fast voltage fluctuations [26][27][28][29][30][31].…”

Section: Introductionmentioning

confidence: 99%

Electric Arc Furnaces as a Cause of Current and Voltage Asymmetry

Olczykowski

2021

Energies

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In the case of three-phase arc furnaces, two types of asymmetry can be distinguished: constructional and operational. The structural asymmetry is related to the construction of high-current circuits supplying the arc furnace. The knowledge of the parameters of the high-current circuit allows to determine the operating characteristics of the arc device. The author proposed a method for calculating the real values of the resistance and reactance of the high-current circuit. For this purpose, tests were made to short-circuit the electrodes with the charge. During the short-circuit, with the use of a power quality analyzer, measurements of electrical indicators were carried out, which allow to determine the parameters of the high-current circuit. A new method for determining voltage operational unbalance is also presented in this paper. The theoretical considerations presented in the article were verified in industrial conditions.

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Section: Introductionmentioning

confidence: 99%

Electric Arc Furnaces as a Cause of Current and Voltage Asymmetry

Olczykowski

2021

Energies

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“…Circuit models are based on the theory of circuits and are based on the EM substitution circuits utilization. The interdependence between electric, magnetic, and design parameters of the EM is carried out between the inductive and active parameters of the EM substitution circuits [6]. Such models are described either by a system of algebraic equations or by a system of nonlinear differential equations of the first order.…”

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confidence: 99%

Development of methods for adapting the parameters of spatial end winding sections in 2D circuit-field models of induction-synchronous electric machines

Kotsur

2024

Electrical Engineering & Electromechanics

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Introduction. Recently, the theory of a special class of cascade slow-speed non-contact induction-synchronous electrical machines (ISEM) has been developed. This allowed to obtain a combination of positive properties from conventional induction and synchronous electric machines. Problem. The lack of circuit and field models of ISEM imposes restrictions on further research of electromagnetic, mechanical and energy processes, in transient and quasi-steady modes of its operation. Goal. Development of 3D and adapted 2D circuit-field models of ISEM, decomposition methods, and dynamic synthesis with adaptation of electromagnetic parameter coupling conditions at the boundaries of calculated subdomains of ISEM. Methodology. Spatial elements of ISEM design are represented by separate spatial calculation subareas. The conditions of compliance with electromagnetic processes, which are formed by a complete calculation area and separate spatial calculation subareas of ISEM, are accepted. The influence of end effects and the parameters of the frontal parts of ISEM windings are determined by the inequality of the magnetic field energy of separate calculation subareas. These parameters, including end effects, are displayed as circuit elements in the 2D circuit-field model. Results. The obtained combination of 3D area decomposition methods and dynamic synthesis with adaptation of electromagnetic parameters coupling conditions at the boundaries of its calculated ISEM’s subdomains. The proposed technique for determining the resistance and inductive resistances of the frontal parts of the ISEM windings, taking into account edge effects. The accuracy and effectiveness of the proposed methods is confirmed by the results of an experimental study. Originality. An adapted dynamic 2D circuit-field model of transient processes of ISEM has been developed, which allows taking into account parameters of the frontal parts of its windings. Practical value. The proposed methods can be used for various types of electrical machines. References 27, tables 3, figures 12.

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