Analysis of Determining the Surge Arrester Protective Distance for Protection on 60 MVA Power Transformers at the 150 KV Main Substation in Surabaya Barat
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References
[1] Widagdo, R. S., & Andriawan, A. H. (2023). Analysis of Losses Due to Load Unbalance in a 2000 KVA Transformer at Supermall Mansion 2 Tower Tanglin Surabaya. Journal of Engineering and Scientific Research, 5(2), 78-84.
[2] Widagdo, R. S., & Andriawan, A. H. (2023). Prediction of Age Loss on 160 KVA Transformer PT. PLN ULP Kenjeran Surabaya using The Linear Regression Method. Jurnal Riset Rekayasa Elektro, 5(2), 83-92.
[3] Marlanfar, M., Yusmartato, Y., Yusniati, Y., & Pelawi, Z. (2020). Analisa Penempatan Lightning Arester Pada Gardu Induk Tanjung Morawa. Buletin Utama Teknik, 15(3), 229-233.
[4] Ridal, Y. (2022). Studi Analisis Kemampuan Lightning Arrester Sebagai Proteksi Transformator Daya pada Gardu Induk Padang Luar ULTG Bukit Tinggi. Jurnal Teknik Industri Terintegrasi (JUTIN), 5(2), 270-275.
[5] Manihuruk, J., Simorangkir, T., & Sitanggang, N. L. (2021). Studi Kemampuan Arrester Untuk Pengaman Transformator Pada Gardu Induk Tanjung Morawa 150 KV. Jurnal ELPOTECS, 4(1), 16-25.
[6] Asna, I. M., Suriana, I. W., Sugarayasa, I. W., Sutama, W., Pancane, I. W. D., Adrama, I. N. G., & Sariana, I. M. (2021). Analisis Konstruksi Posisi Lightning Arrester Di Gardu Distribusi Km 0003 Penyulang Subagan Wilayah Kerja PT PLN (Persero) ULP Karangasem. Jurnal Ilmiah Telsinas Elektro, Sipil dan Teknik Informasi, 4(1), 46-55.
[7] Azis, A., & Alimin Nurdin, H.). Analisa Jarak Lindung Lighting Arrester Terhadap Transformator Daya 20 Mva Gardu Induk Sungai Juaro Palembang. TEKNIKA: Jurnal Teknik, 7(1), 106-120.
[8] Zainuddin, M., & Bima, L. (2023). Jarak Penempatan Lightning Arrester sebagai Pelindung Transformator terhadap Tegangan Lebih pada Gardu Induk 150 KV Harapan Baru. Mutiara: Jurnal Ilmiah Multidisiplin Indonesia, 1(2), 164-185.
[9] Wirawan, H. Y., Al-Amin, M. S., & Emidiana, E. (2021). Kemampuan Arrester Sebagai Pengaman Transformator. Jurnal Tekno, 18(1), 72-78.
[10] Rao, M. M., Lanjewar, A., & Tiwari, N. (2022). Analytical and experimental studies on 245 KV gas insulated surge arrester. Electric Power Systems Research, 204, 107713.
[11] Shariatinasab, R., & Azimi, R. (2020). A methodology for optimal design of transmission lines to protection against lightning surges in presence of arresters. Advanced Electromagnetics, 9(1), 105-110.
[12] Boumous, S., Boumous, Z., Latréche, S., & Nouri, H. (2023). Influence of the lightning arrester position on protection of the 220KV Overhead transmission line. Przeglad Elektrotechniczny, 99(5).
[13] Castro, W. S., Lopes, I. J., Missé, S. L., & Vasconcelos, J. A. (2022). Optimal placement of surge arresters for transmission lines lightning performance improvement. Electric Power Systems Research, 202, 107583.
[14] Datsios, Z. G., Mikropoulos, P. N., Tsovilis, T. E., Thalassinakis, E., & Pagonis, G. (2022). Investigation of line surge arresters application to the 150 KV system of Rhodes. Electric Power Systems Research, 213, 108763.
[15] Olesz, M., Litzbarski, L. S., & Redlarski, G. (2023). Leakage Current Measurements of Surge Arresters. Energies, 16(18), 6480.
[16] Visacro, S., Silveira, F. H., Pereira, B., & Gomes, R. M. (2020). Constraints on the use of surge arresters for improving the backflashover rate of transmission lines. Electric Power Systems Research, 180, 106064.
[17] Handoko, S. R. (2023). Analisa Peralatan Lightning Arrester Pada Gardu Induk 150 KV PLTU Rembang. JETI (Jurnal Elektro dan Teknologi Informasi), 2(1), 17-21.
[18] Munir, A., Abdul-Malek, Z., & Arshad, R. N. (2021, July). Resistive leakage current based condition assessment of zinc oxide surge arrester: a review. In 2021 IEEE International Conference on the Properties and Applications of Dielectric Materials (ICPADM) (pp. 183-186). IEEE.
[19] Castro, W. S., Lopes, I. J., Missé, S. L., & Vasconcelos, J. A. (2022). Optimal placement of surge arresters for transmission lines lightning performance improvement. Electric Power Systems Research, 202, 107583.
[20] Cao, J., Du, Y., Ding, Y., Lyu, J., Qi, R., Chen, M., & Andreotti, A. (2023). Lightning protection with a differentiated arrester configuration for distribution networks using a multi-objective optimization procedure. IEEE Transactions on Power Delivery, 38(3), 2149-2159.
[21] Khodsuz, M. (2022). Externally gapped line arrester performance in high voltage transmission line using frequency grounding system: Absorbed energy and expected life assessment. IET Science, Measurement & Technology, 16(7), 426-440.
[22] Ranjbar, B., Darvishi, A., Dashti, R., & Shaker, H. R. (2022). A survey of diagnostic and condition monitoring of metal oxide surge arrester in the power distribution network. Energies, 15(21), 8091.
[23] Sabiha, N. A., Mahmood, F., & Abd-Elhady, A. M. (2020). Failure risk assessment of surge arrester using paralleled spark gap. IEEE Access, 8, 217098-217107.
[24] Doorsamy, W., & Bokoro, P. (2018, September). Condition monitoring of metal-oxide surge arresters using leakage current signal analysis. In 2018 IEEE International Conference on High Voltage Engineering and Application (ICHVE) (pp. 1-4). IEEE.
[25] Dobric, G., Stojkovic, Z., & Stojanovic, Z. (2020). Experimental verification of monitoring techniques for metal‐oxide surge arrester. IET Generation, Transmission & Distribution, 14(6), 1021-1030.
[26] Shu, S., Zhang, X., Wang, G., Zeng, J., & Ruan, Y. (2023). A Fault Identification Method for Metal Oxide Arresters Combining Suppression of Environmental Temperature and Humidity Interference with a Stacked Autoencoder. Energies, 16(24), 8033.
[27] Fu, Y., Li, T., Li, Y., Hu, X., Jiang, X., Dong, Y., ... & Wang, J. (2023). Research on Field Source Characteristics of Leakage Current of Arrester Based on TMR Sensor. Sensors, 23(8), 3830.
[28] Khodsuz, M., Teymourian, M. H., & Seyyedbarzegar, S. (2024). New criteria for metal oxide surge arrester condition monitoring based on leakage current analysis: Considering non‐uniform pollution effect. IET Generation, Transmission & Distribution.
[29] Shi, W., Yuan, H., Li, J., Zhang, P., & Zhou, C. (2020, June). Analysis on the natural pollution characteristics of metal-oxide surge arrester with different external insulation material. In 2020 5th Asia Conference on Power and Electrical Engineering (ACPEE) (pp. 2237-2241). IEEE.
[30] Papliński, P., Wańkowicz, J., Śmietanka, H., Ranachowski, P., Ranachowski, Z., Kudela, S. J., & Aleksiejuk, M. (2020). Comparative studies on degradation of varistors subjected to operation in surge arresters and surge arrester counters. Archives of Metallurgy and Materials, 65(1), 367-374.
DOI: 10.30595/jrre.v6i1.21555
This work is licensed under a Creative Commons Attribution 4.0 International License.
ISSN: 2685-5313