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Consideration of Active Resistances Temperature Dependency of Power Transformers when Calculating Power Losses in Grids | IEEE Conference Publication | IEEE Xplore
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Consideration of Active Resistances Temperature Dependency of Power Transformers when Calculating Power Losses in Grids

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A.O. Shepelev; E.V. Petrova; O.A. Sidorov
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Abstract:

An analytical method for calculating power losses is developed taking into account the temperature dependence of the active resistances in power transformers. The propose...Show More

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Abstract:

An analytical method for calculating power losses is developed taking into account the temperature dependence of the active resistances in power transformers. The proposed mathematical model is based on the transformation of the nonlinear function of the power loss versus linear dependence. This transformation is based on the integral least-squares method. For the power transformer TMN 6300/35, the power losses are calculated taking into account the temperature dependence of the load losses. The results of comparison of power losses in transformers with power losses in power transmission lines show the need to take into account the temperature dependence of the resistance in transformers.
Published in: 2018 International Conference on Industrial Engineering, Applications and Manufacturing (ICIEAM)
Date of Conference: 15-18 May 2018
Date Added to IEEE Xplore: 06 June 2019
ISBN Information:
DOI: 10.1109/ICIEAM.2018.8728811
Conference Location: Moscow, Russia
References is not available for this document.
Contents

I. Introduction

Increasing the accuracy of calculations of losses of electric energy requires taking into account the temperature dependence of the active resistance of power transmission lines. At the article [1] the thermal calculation of an isolated wire is given in the steady state regime. The authors in [2] presented a mathematical model of a 4-wire system in insulated wires, which allows to determine the temperature of wires taking into account the mutual influence of the wire of each phase. The described thermal model of the stationary regime of an insulated wire in [3] allows to calculate the temperature of both insulated and bare conductors. At [4], individual aspects of the effect of insulation on thermal processes in the wires of overhead transmission lines were investigated. The simplified model proposed by the authors of [5] for calculating the temperature of power transmission lines in non-stationary modes allows one to determine the temperature by an analytical method. This mathematical model makes it possible to simplify the calculation of nonstationary modes of power transmission lines. The proposed electro-thermal model was used by the authors of [6] to monitor the temperature in power transmission lines in stationary and non-stationary modes. The influence of the current in the conductor and the weather conditions on the resistance of the conductor was separately analyzed in [7]. This analysis makes it possible to distinguish the effect of each component of the heat balance equation on the conductor temperature.

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1.
S.S. Girshin, V.N. Goryunov and E.A. Kuznetsov, "Thermal Rating of Overhead Insulation-Covered Conductors in the Steady-State Regime", MATEC Web of Conf., vol. 70, 2016.
CrossRef Google Scholar
2.
S.S. Girshin, A.A. Bubenchikov, T.V. Bubenchikova, V.N. Goryunov and D.S. Osipov, "Mathematical model of electric energy losses calculating in crosslinked four-wire polyethylene insulated (XLPE)aerial bundled cables", 2016 ELEKTRO Strbske Pleso, pp. 294-298, 2016.
View Article
Google Scholar
3.
V.N. Goryunov, S.S. Girshin, E.A. Kuznetsov, E.V. Petrova and A.Y. Bigun, "A mathematical model of steady-state thermal regime of insulated overhead line conductors", 2016 IEEE 16th Int. Conf. on Environment and Electrical Engineering (EEEIC), pp. 1-5, 2016.
View Article
Google Scholar
4.
S.S. Girshin, V.N. Goryunov, E.A. Kuznetsov, A.Y. Bigun, E.V. Petrova and A.A. Bubenchikov, "Comparative analysis of insulation-covered and bare conductors of overhead lines with variation of load currents considering weather conditions", 2016 Dynamics of Systems Mechanisms and Machines (Dynamics), pp. 1-6, 2016.
View Article
Google Scholar
5.
S.S. Girshin, V.N. Gorjunov, A.Y. Bigun, E.V. Petrova and E.A. Kuznetsov, "Overhead power line heating dynamic processes calculation based on the heat transfer quadratic model", 2016 Dynamics of Systems Mechanisms and Machines (Dynamics), pp. 1-5, 2016.
View Article
Google Scholar
6.
A. Kubis and C. Rehtanz, "Synchrophasor based thermal overhead line monitoring considering line spans and thermal transients", IET Generation Transmission & Distribution, vol. 10, no. 5, pp. 1232-1239, 2016.
CrossRef Google Scholar
7.
J.R. Santos, A.G. Exposito and F.P. Sanchez, "Assessment of conductor thermal models for grid studies", IET Generation Transmission & Distribution, vol. 1, no. 1, pp. 155-161, 2007.
CrossRef Google Scholar
8.
L.W. Pierce, "An investigation of the thermal performance of an oil filled transformer winding", IEEE Transactions on Power Delivery, vol. 7, no. 3, pp. 1347-1358, 1992.
View Article
Google Scholar
9.
L.W. Pierce, "Predicting liquid filled transformer loading capability", Record of Conference Papers Industry Applications Society 39th Annual Petroleum and Chemical Industry Conf., pp. 197-207, 1992.
View Article
Google Scholar
10.
Y. Cui, H. Ma, T. Saha, C. Ekanayake and G. Wu, "Multi-physics modelling approach for investigation of moisture dynamics in power transformers", IET Generation Transmission and Distribution, vol. 10, no. 8, pp. 1993-2001, 2016.
CrossRef Google Scholar
11.
M.F. Lachman, P.J. Griffin, W. Walter and A. Wilson, "Real-time dynamic loading and thermal diagnostic of power transformers", IEEE Transactions on Power Delivery, vol. 18, no. 1, pp. 142-148, 2003.
View Article
Google Scholar
12.
M.Z. Degefa, R.J. Millar, M. Lehtonen and P. Hyvönen, "Dynamic Thermal Modeling of MV/LV Prefabricated Substations", IEEE Transactions on Power Delivery, vol. 29, no. 2, pp. 786-793, 2014.
View Article
Google Scholar
13.
Y.B. Zhang, Y.L. Xin, T. Qian, X. Lin, W.H. Tang and Q.H. Wu, "2-D coupled fluid-thermal analysis of oil-immersed power transformers based on finite element method", 2016 IEEE Innovative Smart Grid Technologies - Asia (ISGT-Asia), pp. 1060-1064, 2016.
View Article
Google Scholar
14.
A. Kr. Naskar, N. Kr. Bhattacharya, S. Saha and S.N. Kundu, "Thermal analysis of underground power cables using two dimensional finite element method", 2013 IEEE 1st Int. Conf. on Condition Assessment Techniques in Electrical Systems (CATCON), pp. 94-99, 2013.
View Article
Google Scholar
15.
F.A. Gomez, J.M. Garcia De Maria, D. Garcia Puertas, A. Bairi and R. Granizo Arrabe, "Numerical study of the thermal behaviour of bare overhead conductors in electrical power lines", Proc. of the 10th WSEAS int. conf. on communications electrical & computer engineering, pp. 149-153, 2011.
Google Scholar
16.
V.N. Goryunov, V.E. Til’ and L.E. Serkova, "Finite-element models of linear motors with permanent magnets", Electrical Engineering, no. 2, pp. 20-24, 1994.
Google Scholar
17.
V.N. Goryunov, V.N. Kozlov, L.E. Serkova and V. Eh. Til, "A finite element model of magnetic systems for multipole disc electromechanical devices with permanent magnets", Electrical Engineering, no. 12, pp. 54-58, 1994.
Google Scholar
18.
S.S. Girshin, A.Y. Bigun and E.V. Petrova, "Analysis of dynamic thermal rating of overhead power lines in the conditions of forced convection considering non-linearity of heat transfer processes", 2016 2nd Int. Conf. on Industrial Engineering Applications and Manufacturing (ICIEAM), pp. 1-6, 2016.
View Article
Google Scholar
19.
P.M. Tikhomirov, Calculation of transformers., Energoatomizdat, 1986.
Google Scholar
20.
"GOST 14209–85", Manual for load of power oil transformers, 2013.
Google Scholar

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