Failure Mechanism Analysis of 253MA Vortex Finder in A CFB Boiler Under High-Temperature Erosion and Refractory Deposit Exposure
DOI:
https://doi.org/10.59261/jequi.v8i3.342Keywords:
Vortex Finder, Material Failure, Hotspot, SEM-EDS, CFB Boiler, XRDAbstract
Background: Circulating fluidized bed (CFB) boilers are widely applied in coal-fired power plants due to their fuel flexibility and low emissions. The vortex finder, a key cyclone component, separates solid particles from flue gas and is prone to wear under high-temperature, erosive conditions.
Objective: This study aims to identify failure characteristics, analyze the causes, and explain the failure mechanism of a 253MA vortex finder in a 2 × 100 MW CFB boiler at PLTU Sebalang after 6,548 operating hours at 850–950°C.
Methods: A multi-method approach was employed, including visual inspection, positive material identification (PMI), tensile testing, microhardness testing, optical microscopy, scanning electron microscopy with energy-dispersive spectroscopy (SEM-EDS), and X-ray diffraction (XRD) analysis to assess mechanical and microstructural degradation.
Results: The vortex finder exhibited plastic deformation, material thinning, and deposition of foreign refractory material. Tensile strength decreased from 723.89 MPa to 677.84 MPa (6.36%), elongation decreased from 58% to 53%, and hardness decreased from 218.84 HV to 210.21 HV. Microstructural changes included grain coarsening and carbide precipitation, while SEM-EDS revealed surface roughening, early microcrack initiation, and compositional changes indicative of high-temperature oxidation. XRD confirmed that the deposits consisted of alumina–silica refractory material.
Conclusion: Failure resulted from a synergistic mechanism involving high-velocity particle erosion, refractory deposit accumulation, and progressive microstructural degradation. Crack initiation and propagation ultimately led to structural failure. Recommendations include implementing erosion control measures, maintaining refractory linings, applying more erosion-resistant coatings or alternative materials, and adopting condition-based inspection strategies to enhance component reliability.
Downloads
References
Alviana, R. M., Anwar, M. S., & Siradj, E. S. (2023). Evaluation Of Microstructure High Chrome Austenitic Stainless-Steel Grade 253ma After Creep Test At Temperature Of 700 C. Jurnal Pendidikan Teknologi Kejuruan, 6(1), 41–47.
Arjunwadkar, A., Basu, P., & Acharya, B. (2016). A Review Of Some Operation And Maintenance Issues Of Cfbc Boilers. Applied Thermal Engineering, 102, 672–694.
Baskoro, Y., & Wardhana, M. (2026). Peningkatan Proses Pemeliharaan Pada Pembangkit Listrik Pltu Jeranjang Ntb Dengan Memadukan Proses Outage Management Framework Dan Design Thinking. Jurnal Locus Penelitian Dan Pengabdian, 5(3), 1599–1617.
Basu, P. (2006). Circulating Fluidized Bed Boiler Bt - Combustion And Gasification In Fluidized Beds. CRC Press.
Dagdag, O., Haldhar, R., Thakur, A., Daoudi, W., Berisha, A., Berdimurodov, E., & Kim, H. (2025). Corrosion In The Power Plant Industry. Industrial Corrosion: Fundamentals, Failure, Analysis And Prevention, 105–130.
Darmawan, S., & Wibowo, P. (2024). Analisis Perbandingan Kinerja Pembangkit Listrik Tenaga Surya Dan Pembangkit Listrik Tenaga Uap Pada Lingkungan PT. RAPP. Jurnal Engine: Energi, Manufaktur, Dan Material, 8(2), 161–174.
Facheruddin, M. (2023). Analisa Kegagalan Material Pipa Superheater Pada Boiler Type CFB (Circulating Fluidized Bed).
Hadining, W. N., & Basuki, E. A. (2023). Pengaruh Pelapisan Aluminida Paduan Ti-47al-2nb-2cr-0.5zr-0.5y Terhadap Oksidasi Siklik Pada Temperatur 900, 1000, Dan 1100 C. Journal Of Metallurgical Engineering And Processing Technology, 146–158.
Hagman, H., Bostrom, D., Lundberg, M., & Backman, R. (2019). Alloy Degradation In A Co-Firing Biomass CFB Vortex Finder Application At 880 C. Corrosion Science, 150, 136–150.
Ismail, I., Saiful, M. S., Aprilia, S., & Mulana, I. F. (2026). Material Komposit. USK Press.
Jamilatun, S., Rhomadoni, F. R., Astuti, E., Wardhana, B. S., Idris, M., & Auliasari, P. A. (2025). Peran Manajemen Energi Terhadap Efisiensi Konsumsi Listrik Rumah Tangga Di Indonesia. Prosiding Semnastek.
Kementerian ESDM. (2022). Content Handbook Of Energy And Economic Statistics Of Indonesia 2022.
Konist, A. (2023). Investigation Of Fouling And Corrosion Of Low-Temperature Reheater In A CFBC Boiler. Fuel, 338, 127373.
Malik, E. (2024). Pengaruh Lapisan Erosion Shield Terhadap Efektivitas Perpindahan Panas Pada Primary Superheater Boiler Unit 7 Di PT. PLN Indonesia Power UBP Suralaya.
Maulana, N. U. R. R. (2026). Analisis Implementasi Preventive Maintenance Pada Boiler Unit 3 Di PT CCEPC. Prosiding Seminar Nasional Energi, Telekomunikasi Dan Otomasi (SNETO), 121–128.
Mawuntu, D. J., Makasarat, O., Koraag, R. A., Poli, A. E., & Najoan, H. K. (2024). Analisa Daya Mampu Pasokan Listrik Di Pulau Marampit Kabupaten Kepulauan Talaud. Riggs: Journal Of Artificial Intelligence And Digital Business, 3(2), 1–5.
Negara, P. L. (2024). Annual Report PLN 2024.
Nugroho, R. F. D. W. I. (2019). Hak Kreditor Separatis Menurut Pasal 55 Ayat (1) Juncto Pasal 56 Ayat (1) Dan Pasal 59 Uu No 37 Tahun 2004 Tentang Kepailitan Dalam Eksekusi Barang Jaminan Milik Debitor.
Pamungkas, I., Irawan, H. T., & Pandria, T. M. A. (2021). Implementasi Preventive Maintenance Untuk Meningkatkan Keandalan Pada Komponen Kritis Boiler Di Pembangkit Listrik Tenaga Uap. Vocatech: Vocational Education And Technology Journal, 2(2), 73–79.
Triasdian, Y., Busairi, N. A., Parningotan Ts, H., & Muflikhun, M. A. (2021). Failure Analysis Of Water Wall Tube In Circulating Fluidized Bed Boiler. Aip Conference Proceedings, 2403(1), 30001.
Widjajanto, T., Darmadi, D. B., Irawan, Y. S., & Gapsari, F. (2024). Failures Analysis Of Tube Coating In Circulating Fluidized Bed (CFB) Boiler. Heliyon, 10(4).
Yohana, E., Tauviqirrahman, M., Prakoso, B. K., Choi, K. H., & Charles, H. (2023). Karakteristik Dan Performa Cyclone Separator Dengan Penambahan Vortex Finder (Tappered Out-Cylinder In) Dan Variasi Pendinginan Pada Cone Cyclone Dengan Menggunakan Simulasi Numerik. Jurnal Teknik Mesin, 11(2), 191–204.
Downloads
Published
Issue
Section
License
Copyright (c) 2026 Martua Haposan Echo Sihite, Kusmono Kusmono

This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.
Authors who publish with this journal agree to the following terms:
- Authors retain copyright and grant the journal right of first publication with the work simultaneously licensed under a Creative Commons Attribution-ShareAlike 4.0 International (CC-BY-SA). that allows others to share the work with an acknowledgement of the work's authorship and initial publication in this journal.
- Authors are able to enter into separate, additional contractual arrangements for the non-exclusive distribution of the journal's published version of the work (e.g., post it to an institutional repository or publish it in a book), with an acknowledgement of its initial publication in this journal.
- Authors are permitted and encouraged to post their work online (e.g., in institutional repositories or on their website) prior to and during the submission process, as it can lead to productive exchanges, as well as earlier and greater citation of published work.



