ANALISA PENGARUH PEMASANGAN FLOW ADJUSTER UNTUK MENGURANGI COAL SPILAGE UNTUK MENGHINDARI KEBAKARAN PADA COAL HANDLING SYSTEM DI PLTU TANJUNG JATI B

Authors

ANDIKA SYAHRUL PRADANA UNIVERSITAS NEGERI SURABAYA
Rachmad Syarifudin Hidayatullah UNIVERSITAS NEGERI SURABAYA

Keywords:

Flow Adjuster, Coal Spillage, Conveyor, Kebakaran, PLTU.

Abstract

Coal spillage in the coal handling system at the Tanjung Jati B PLTU is a serious problem that can disrupt operations and increase the risk of fire. This study aims to analyze the effect of installing flow adjusters on belt conveyors 105A and 105B in reducing coal spillage volume and preventing fires. The study used a quantitative, experimental approach, where measurements were taken before and after the flow adjuster installation using volumetric and gravimetric methods to measure coal spillage volume. The results show that installing flow adjusters can regulate coal flow more efficiently, reducing coal spillage by up to 40% and reducing the risk of fires due to coal accumulation that can potentially create hot spots. Therefore, the use of flow adjusters has proven effective in improving the efficiency of the coal transportation system and operational safety at the Tanjung Jati B PLTU.

Keywords: Flow Adjuster, Coal Spillage, Conveyor, Fire, Coal Power Plant

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References

DAFTAR PUSTAKA

1. Bahrun et al. (2021). Coal Flowability Control on Preventing Spillage on Conveyor Belt Through Modeling and Simulation for Improving its Performance. Journal of Advanced Research in Fluid Mechanics and Thermal Sciences, 90(1), 130-145.

2. Bhatt, S., & Rajkumar, N. (2016). Effect of moisture in coal on station heat rate and fuel cost for Indian thermal power plants. Power Research, 11, 773-786.

3. Dwikusumah, R., & Nurbanasari, M. (2021). Pemeriksaan Serangan Korosi Pada Struktur Conveyor Pengangkut Batu Bara Di PLTU. Prosiding Diseminasi FTI Genap.

4. Kementrian Energi dan Sumber Daya Mineral (ESDM). (2021). Handbook Of Energy & Economic Statistics Of Indonesia (HEESI) 2021.

5. Manfaluthy, M., Pratama, R., & Kurniawan, D. (2022). Pengembangan sistem deteksi dini kebakaran berbasis sensor pada sistem coal handling. Laporan internal, PLTU XYZ.

6. Febriyanti, R., & Sayidatun, N. (2023). Perencanaan pengendalian emisi debu pada coal yard PT PLN (Persero) UIK Tanjung Jati B Unit 1-2 & 3-4. Skripsi, Universitas Diponegoro.

7. Marshall. (2013). Improving Dust Control to Upgrade PRB Coal Handling.

8. Perusahaan Listrik Negara. (1989). Standar Operasi Pusat Listrik Tenaga Gas, Jakarta: PT PLN (Persero).

9. Syahputera, M. I., Kamal, D. M., & Ekayuliana, A. (2018). Analisis pengaruh nilai kalori batu bara terhadap konsumsi bahan bakar dan biaya produksi listrik. Seminar Nasional Teknik Mesin, 474-483.

10. Wen, L., Liang, B., Zhang, L., Hao, B., & Yang, Z. (2024). Research on coal volume detection and energy-saving optimization intelligent control method of belt conveyor based on laser and binocular visual fusion. IEEE Access, 12, 75238-75248.

11. Zimroz, R., & Król, R. (2009). Failure analysis of belt conveyor systems for condition monitoring purposes. Mining Science, 128, 255-270.

12. Zuniawan, A., & Sriwana, I. K. (2019). Handling of coal dust at coal handling facility in coal power plant using soft system methodology (SSM) approach. Sinergi, 23(3), 223.

13. Zhao, L., & Lin, Y. (2011). Operation and maintenance of coal handling system in thermal power plant. Procedia Engineering, 26, 2032-2037.