LONGITUDINAL IMPEDANCE OF A SINGLE-CIRCUIT POWER TRANSMISSION LINE WITH TWO LIGHTNING PROTECTION CABLES IN THE PROBLEM OF REMOTE FAULT LOCATION-Reference-Cited by-同舟云学术

LONGITUDINAL IMPEDANCE OF A SINGLE-CIRCUIT POWER TRANSMISSION LINE WITH TWO LIGHTNING PROTECTION CABLES IN THE PROBLEM OF REMOTE FAULT LOCATION

Published:2021 Issue:4 Volume:21 Page:40-47
ISSN:1990-8512
Container-title:Bulletin of the South Ural State University series "Power Engineering"
language:
Short-container-title:PE

Author:

Panova E.A.,

Abstract

One of the most important tasks in remote fault location in a 110 kV+ network is modeling the power lines taking into account the electromagnetic and electrostatic interaction of their conductive elements. A common approach is to use the mathematical models recommended by the guidelines for calculating short-circuit currents for relay protection. However, these models of power transmission lines take into account the geometric mean distance between the wires and the lightning protection cables, which means they average the values of the mutual induction impedances. In cases where wires and cables are located asymmetrically relative to each other, this leads to an overestimation of the zero-sequence impedance of power lines and, as a consequence, to an underestimation of the single-phase short-circuit current. This situation can affect the results of remote fault location. To eliminate this drawback, the article proposes a combined equivalent circuit for a single-circuit power transmission line with two lightning protection cables, based on a combination of methods of phase coordinates and symmetric components. The given equivalent circuit of power transmission lines allows calcula¬ting the mode parameters using the method of symmetric components and, at the same time, simulating those of interest for calculating power lines using phase coordinates.

Publisher

FSAEIHE South Ural State University (National Research University)

Subject

General Medicine

Reference20 articles.

1. 1. Rukovodyashchie ukazaniya po releynoy zashchite. Vyp. 11. Raschet tokov korotkogo zamykaniya dlya releynoy zashchity i sistemnoy avtomatiki v setyakh 110-750 kV [Relay protection guidelines. Issue 11. Calculation of short-circuit currents for relay protection and system automation in 110-750 kV networks]. Moscow, Energiya Publ., 1979. 152 p.

2. 2. Dikhno A.O., Makasheva S.I. [Modeling of Electromagnetic Processes in Parallel Power Transmission Lines]. Nauchno-tekhnicheskoe i ekonomicheskoe sotrudnichestvo stran ATR v XXI veke [Scientific, technical and economic cooperation of the Asia-Pacific countries in the XXI century], 2019, vol. 2, pp. 227-231. (in Russ.)

3. 3. Kabanov V.O. [Simulation of a High Voltage Power Line to Determine the Limit of the Transmitted Power]. Energiya-2021: Tezisy dokladov Shestnadtsatoy vserossiyskoy (vos'moy mezhdunarodnoy) nauchno-tekhnicheskoy konferentsii studentov, aspirantov i molodykh uchenykh: v 7 t. [Energy-2021: Abstracts of the Sixteenth All-Russian (Eighth International) Scientific and Technical Conference of Students, Postgraduates and Young Scientists], 2021, Ivanovo, vol. 3, pp. 17. (in Russ.)

4. 4. Rubanov N.V. [Simulation of Electric Transmission Lines of Extra High Voltage Class in MATLAB Software Complex]. Colloquium-journal, 2019, no. 24-2 (48), pp. 109-111. (in Russ.)

5. 5. Bykovskaya L.V., Bykovskiy V.V. [Mathematical Modeling of Air Lines Operation Modes with Distributed Parameters]. Gornoe oborudovanie i elektromekhanika [Mining equipment and electromechanics], 2018, no. 5 (139), pp. 11-16. (in Russ.) DOI: 10.26730/1816-4528-2018-5-11-15