A neural network model for predicting the temperature of insulated overhead lines

In this work, we develop a neural network model based on experimental heating and cooling curves of insulated wires of overhead lines under changes in wind speed and its direction relative to the wire axis. Insulated SIP-3 wire used in overhead lines was investigated. A multilayer perceptron neural network was employed to model the process of heating and cooling of insulated wire under changes in wind speed and its direction. The average absolute error was taken as a criterion for evaluating the prediction accuracy of wire core and insulation temperatures. The main parameters of the developed neural network model include the number of hidden layers and neurons in each hidden layer, the degree of regulation, and the regulatory rigidity of the model. The modelled heating and cooling curves of insulated wire were compared with those obtained experimentally. The average absolute error was equal to 1.74 and –4.08°C for the predicted core and insulation temperatures, respectively. The difference between the heating curves at low wind speeds was found to range within 9°C. It was shown that an increase in wind speed leads to a decrease in the difference between the curves. Our analysis showed that neural network models used for predicting variations in the temperature of insulated overhead lines should be trained using a larger number of input parameters. This is the main prerequisite for high prediction accuracy of such models, when the difference between the simulated and experimental data does not exceed 5%.

1. Alassi A., Banales S., Ellabban O., Adam G., MacIver C. HVDC transmission: technology review, market trends and future outlook. Renewable and Sustainable Energy Reviews. 2019;112:530-554. https://doi.org/10.1016/j.rser.2019.04.062.

2. Arcia-Garibaldi G., Cruz-Romero P., Gomez-Exposito A. Future power transmission: visions, technologies and challenges. Renewable and Sustainable Energy Reviews. 2018;94:285-301. https://doi.org/10.1016/j.rser.2018.06.004.

3. Bedialauneta M.T., Fernandez E., Albizu I., Mazon A.J., Valverde V., Buigues G. Pilot installation for the monitoring of the tension-temperature curve of a distribution overhead line. In: IEEE International Energy Conference and Exhibition. 9–12 September 2012, Florence. Florence: IEEE; 2012, р. 305-314. https://doi.org/10.1109/EnergyCon.2012.6347772.

4. Beryozkina S. Evaluation study of potential use of advanced conductors in transmission line projects. Energies. 2019;12(5):822. https://doi.org/10.3390/en12050822.

5. Capelli F., Riba J.-R., Gonzalez D. Thermal behavior of energy-efficient substation connectors // 10th International Conference on Compatibility, Power Electronics and Power Engineering. 29 June 2016 – 1 July 2016, Bydgoszcz. Bydgoszcz: IEEE; 2016, р. 104-109. https://doi.org/10.1109/CPE.2016.7544167.

6. Capelli F., Riba J.-R., Sanllehi J. Finite element analysis to predict temperature rise tests in high capacity substation connectors. IET Generation, Transmission & Distribution. 2017;11(9):2283-2291. https://doi.org/10.1049/ietgtd.2016.1717.

7. Rashmi, Shivashankar G.S., Poornima. Overview of different overhead transmission line conductors. Materials Today: Proceedings Journal. 2017;4(10):11318-11324. https://doi.org/10.1016/j.matpr.2017.09.057.

8. Situmorang Yо.A., Zhao Zhongkai, Yoshida A., Abudula A., Guan Guoqing. Small-scale biomass gasification systems for power generation (<200 kW class): a review. Renewable and Sustainable Energy Reviews. 2020;117:109486. https://doi.org/10.1016/j.rser.2019.109486.

9. Zheng Yanchong, Niu Songyan, Shang Yitong, Shao Ziyun, Jian Linni. Integrating plug-in electric vehicles into power grids: a comprehensive review on power interaction mode, scheduling methodology and mathematical foundation. Renewable and Sustainable Energy Reviews. 2019;112:424-439.

10. Andronov Yu.V., Melnikov V.N., Strekalov A.V. Assessment of predicting capacities of multi-layer perceptron with various functions of activation and training algorithms. Geologiya, geofizika i razrabotka neftyanyh i gazovyh mestorozhdenij. 2015;9:18-20. (In Russ.). EDN: UIKRNB.

11. Beliy V.B., Kunitsyn R.A. Evaluation of ways to reduce voltage losses in rural power supply systems. Bulletin of Altai State Agricultural University. 2023;4:107-113. (In Russ.). https://doi.org/10.53083/1996-4277-2023-2224-107-113. EDN: TBGICK.

12. Bigun A.Ya. The analysis of non-stationary thermal modes of overhead power lines with the non-linearity of heat transfer processes and climatic factors. Omsk Scientific Bulletin. 2018;1:40-44. (In Russ.). https://doi.org/10.25206/1813-8225-2018-157-40-44. EDN: YSCCXT.

13. Bigun A.Ya., Vladimirov L.V. Heating and cooling of insulated wires of overhead power lines with variations in wind direction. Yugra State University Bulletin. 2023;3:107-116. (In Russ.). https://doi.org/10.18822/byusu202303107-116. EDN: FKPBSG.

14. Bigun A.Ya., Sidorov O.A., Osipov D.S., Girshin S.S., Goryunov V.N., Petrova E.V. Influence of regime and climatic factors on energy losses under non-stationary thermal conditions of power lines. Dinamika sistem, mekhanizmov i mashin. 2017;5(3):8-17. (In Russ.). https://doi.org/10.25206/2310-9793-2017-5-3-08-17. EDN: ZTSRLJ.

15. Bubenchikov A.A., Bubenchikova T.V. Analysis of the insulated self-supporting conductor obstacle. Yugra State University Bulletin. 2023;4:153-160. (In Russ.). https://doi.org/10.18822/byusu202304153-160. EDN: BFLWWO.

16. Galstyan R.A., Tsygulev N.I., Antonov M.A., Tkachenko A.S. Increasing the efficiency of electricity transmission in the electrical network by flexible regulation of reactive power. Energosberezhenie i vodopodgotovka. 2022;5:51-55. (In Russ.). EDN: JFQMQF.

17. Ded A.V., Goryunov V.N., Girshin S.S., Bubenchikov A.A., Petrov A.S., Petrova E.V., et al. Improving calculation accuracy of electric energy technological losses in overhead lines based on regime and climatic factors. Omsk Scientific Bulletin. 2010;1:114-119. (In Russ.). EDN: QBNDMT.

18. Ignatenko I.V., Vlasenko S.A., Puhova A.I., Tryapkin E.Yu., Kazakul A.A., Varygina A.O. Algorithm for power line currents monitoring under specified operating conditions. Energy of Unified Grid. 2021;3:44-53. (In Russ.). EDN: OTPUHZ.

19. Latypov I.S., Sushkov V.V., Khmara G.A., Parshukov A.N., Khamitov R.N. The electric grid capacity increasing and the energy efficiency improving for the existing oil and gas consumers’ electric power system. Tomsk Polytechnic University. Geo Assets Engineering. 2022;333(4):236-247. (In Russ.). https://doi.org/10.18799/24131830/2022/4/3497. EDN: EVHKHG.

20. Figurnov E.P., Kharchevnikov V.I. Experiments on heating uninsulated wires of overhead transmission lines. Power Technology and Engineering. 2016;11:41-47. EDN: XALDST. (In Russ.).