Assessment of wind power plant performance using turbine performance and power curves: a case study of PLTB TOLO I Jeneponto

Sofyan; Ahmad Rosyid Idris; Muh. Ardiansyah Latif; Sarma Thaha; Andarini Asri; Muhammad Thahir; Sitti Wetenriajeng Sidehabi

doi:10.31963/elekterika.v21i2.5116

Authors

Sofyan State Polytechnic of Ujung Pandang
Ahmad Rosyid Idris State Polytechnic of Ujung Pandang
Muh. Ardiansyah Latif State Polytechnic of Ujung Pandang
Sarma Thaha State Polytechnic of Ujung Pandang
Andarini Asri State Polytechnic of Ujung Pandang
Muhammad Thahir
Sitti Wetenriajeng Sidehabi State Polytechnic of Ujung Pandang

DOI:

https://doi.org/10.31963/elekterika.v21i2.5116

Keywords:

wind speed, Maximum power output, Wind Turbine, assessment, Power Coefficient

Abstract

Jeneponto Regency in South Sulawesi possesses significant wind potential, making it an ideal location for the development of Wind Power Plants (WPP). However, these WPPs are intermittent due to the inconsistent nature of wind energy, presenting challenges that affect the performance and efficiency of turbines in generating electricity. Therefore, this study aims to evaluate the performance of the SWT-3.6-130 wind turbines at the Tolo 1 WPP in Jeneponto to determine their capability in converting wind energy into electrical energy at specific wind speeds. The evaluation results indicate that the performance of the SWT-3.6-130 wind turbines at the Tolo WPP in February 2022 was not optimal. The maximum output power generated by these turbines approached the maximum capacity of 3.6 MW, with Turbine 06 producing 3.57 MW at a wind speed of 13.07 m/s, Turbine 09 producing 3.57 MW at a wind speed of 12.27 m/s, and Turbine 013 producing 3.58 MW at a wind speed of 12.11 m/s. Although the power generated was close to the maximum capacity, the performance variation among turbines indicates the need for further evaluation to address factors reducing efficiency. Power coefficient analysis shows that Turbine T13 exhibited the best performance, with the fewest instances of power coefficient values not meeting standards. This study provides crucial insights for improving performance and preventing failures at the Tolo WPP in the future.

References

[1] G. R. Soekarno, S. Sundari, M. S. Boedoyo, and L. Sianipar, “Pajak Karbon sebagai Instrumen Kebijakan untuk Mendorong Transisi Energi dan Pertumbuhan Ekonomi yang Berkelanjutan,” El-Mal J. Kaji. Ekon. Bisnis Islam, vol. 5, no. 4, pp. 2015–2026, Feb. 2024, doi: 10.47467/elmal.v5i4.870.

[2] M. R. Fachri and H. Hendrayana, “Analisa Potensi Energi Angin dengan Distribusi Weibull Untuk Pembangkit Listrik Tenaga Bayu (PLTB) Banda Aceh,” CIRCUIT J. Ilm. Pendidik. Tek. Elektro, vol. 1, no. 1, pp. 1–8, May 2017, doi: 10.22373/crc.v1i1.1377.

[3] M. Y. Khalid, Z. U. Arif, M. Hossain, and R. Umer, “Recycling of wind turbine blades through modern recycling technologies: A road to zero waste,” Renew. Energy Focus, vol. 44, pp. 373–389, Mar. 2023, doi: 10.1016/j.ref.2023.02.001.

[4] S. Samhati, A. Hidayat, and M. N. Makhroja, “Kerjasama Bilateral Indonesia dan Denmark dalam Pembangunan Pembangkit Listrik Tenaga Bayu (Studi Kasus: Pembangunan Pembangkit Listrik Tenaga Bayu untuk Keberlanjutan Energi di Sulawesi Selatan),” Indones. J. Glob. Discourse, vol. 5, no. 1, pp. 90–109, Jun. 2023, doi: 10.29303/ijgd.v5i1.83.

[5] M. Abdy and W. Sanusi, “Karakteristik Kategori Kecepatan Angin di Kota Majene dengan Pendekatan Rantai Markov,” SAINTIFIK, vol. 6, no. 1, pp. 85–90, Jan. 2020, doi: 10.31605/saintifik.v6i1.305.

[6] N. I. Z. Muksin, R. Rahmi, and A. abdi Amsir, “Kerjasama Indonesia dan Denmark dalam Membangun Energi Terbarukan di Sulawesi Selatan (Pembangkit Listrik Tenaga Bayu PLTB di Jeneponto),” J. Fase Kemajuan Sos. dan Polit. Faksi, vol. 10, no. 1 SE-Articles, pp. 1–16, Mar. 2024, doi: 10.33506/jf.v10i1.3597.

[7] A. Prasetyo, D. Notosudjono, and H. Soebagja, “Studi Potensi Penerapan Dan Pengembangan Pembangkit Listrik Tenaga Angin Di Indonesia,” J. Online Mhs., vol. 8, no. 2, pp. 1–12, 2019.

[8] K. Fandhy, A. U. Krismanto, and W. P. Muljanto, “Rancang Bangun Remote Monitoring Wind Turbine Pada PLTB Skala Mikro,” Magn. J. Mhs. Tek. Elektro, vol. 8, no. 1, pp. 441–450, 2024.

[9] M. Iqbal and R. M. S. Adinandra, “Pembuatan Sistem Pembangkit Listrik Tenaga Angin Berkapasitas 100 Watt,” Skripsi, pp. 1–30, 2018.

[10] M. E. Murniati, “Analisis Potensi Energi Angin Sebagai Pembangkit Enegi Listrik Tenaga Angin Di Daerah Banyuwangi Kota Menggunakan Database Online-BMKG,” J. SURYA ENERGY, vol. 6, no. 1, pp. 9–16, Apr. 2022, doi: 10.32502/jse.v6i1.3364.

[11] A. Nugraha, “RANCANG BANGUN TRAINER KIT TURBIN MODEL SAVONIUS SEBAGAI MEDIA PEMBELAJARAN,” J. Tek. Ibnu Sina, vol. 8, no. 02, pp. 100–107, Dec. 2023, doi: 10.36352/jt-ibsi.v8i02.724.

[12] S. S. Putri, . S., and . Y., “Analisis Cara Kerja Turbin Angin Sumbu Vertikal,” J. Pendidikan, Sains Dan Teknol., vol. 2, no. 2, pp. 1034–1036, Dec. 2023, doi: 10.47233/jpst.v2i2.1356.

[13] Aidil Bahari, “Pengaruh kinerja maximum power point tracking (MPPT) terhadap potensi daya listrik pada turbin angin simulasi menggunakan MATLAB-SIMULINK,” UNIVERSITAS SUMATERA UTARA, 2017. [Online]. Available: http://repository.usu.ac.id/handle/123456789/66662?show=full

[14] R. S. Salam and D. Supriyatna, “KAJIAN LITERATUR TENTANG PERBANDINGAN PERFORMA BILAH TAPERLESS AIRFLOW NACA 4412 DENGAN AIRFLOW NACA 2412 PADA HORIZONTAL AXIS WIND TURBINE,” Kohesi J. Sains dan Teknol., vol. 2, no. 11, pp. 48–58, 2024.

[15] M. H. Kurniawan, K. K. Ayuningtiyas, and R. D. Syahrial, “Desain Turbin Angin Sumbu Horisontal Sudu Airfoil NREL S823 dan NREL S823 Sebagai Energi Alternative Di Kabupaten Malang,” Metrotech (Journal Mech. Electr. Technol., vol. 2, no. 1, pp. 30–40, Jan. 2023, doi: 10.33379/metrotech.v2i1.2116.

[16] R. A. Fadiilah, M. Santoso, M. Abu, and G. E. Kusuma, “Optimasi Konversi Daya Turbin Angin Melalui Pengaturan Tsr ( Tip Speed Ratio ) dan Jenis Turbin,” in Proceedings Conference on Marine Engineering and its Application, 2021, pp. 1–6.

[17] Q. Aini and Sudarti, “Analisis Potensi Angin Menggunakan Turbin Angin Sebagai Energi Terbarukan Pembangkit Listrik Tenaga Bayu (Pltb),” J. Multidisiplin Saintek, vol. 01, no. 11, pp. 71–80, 2023.

[18] M. Z. R. Amin and B. S. Kaloko, “Sistem Kontrol Sudut Blade Turbin Savonius dengan Metode Regresi Linier Berganda untuk Optimasi Pembangkit Listrik Tenaga Angin,” Techné J. Ilm. Elektrotek., vol. 23, no. 1, pp. 11–20, Apr. 2024, doi: 10.31358/techne.v23i1.378.

[19] F. P. Wulandari, Yushardi, and Sudarti, “Analisis Perkembangan Pemanfaatan Energi Listrik Tenaga Bayu Sebagai Energi Alternatif Jurnal Teknologi Pendidikan Dan Pembelajaran ( JTPP ),” vol. 01, no. 01, pp. 101–105, 2023.

[20] C. F. Refwalu, W. M. Rumaherang, and S. Maitimu, “STUDI PERFORMANCE TURBIN ANGIN AKSIAL KECEPATAN RENDAH 3 BLADE DENGAN PROFIL AIRFOIL NACA 6 DIGIT,” J. Tek. Mesin, Elektro, Inform. Kelaut. dan Sains, vol. 3, no. 2, pp. 53–61, Oct. 2023, doi: 10.30598/metiks.2023.3.2.53-61.