Analisis Terjadinya Korosi pada Pesawat Seaplane Amphibian Cessna 172 SP Menggunakan Fishbone di Api Banyuwangi

Authors

  • Sabrina Analisristianti Akademi Penerbang Indonesia
  • Andung Luwihono Akademi Penerbang Indonesia
  • Kukuh Tri Prasetyo Akademi Penerbang Indonesia
  • I Made Dwi Surya Dharma Akademi Penerbang Indonesia
  • Sabam Danny Sulung Akademi Penerbang Indonesia

DOI:

https://doi.org/10.55606/jurritek.v4i3.6733

Keywords:

AeroShell Fluid 41, Corrosion, Fishbone Diagram, Prevention, Seaplane Aircraft

Abstract

Amphibian Cessna 172 SP is an aircraft designed to operate in aquatic environments and is frequently exposed to seawater, which is highly corrosive. Such exposure poses a serious issue of corrosion affecting both the structure and components of the aircraft, particularly the floats, lower fuselage, and propeller. Corrosion not only reduces the quality and integrity of the material but also potentially compromises flight safety and increases maintenance costs. This study aims to analyze the causes of corrosion on the Seaplane Amphibian Cessna 172 SP using the fishbone diagram to identify the main contributing factors, including material, method, environment, manpower, and machine. In addition, the 5W+1H approach is employed to examine the problem in greater detail and develop preventive strategies. The results of the analysis indicate that the dominant factors causing corrosion are the high intensity of direct contact with seawater, suboptimal cleaning processes due to limited manpower, and the use of cleaning agents not fully compatible with aircraft materials. Mitigation efforts include implementing more effective cleaning procedures, applying anti-corrosion chemicals such as AeroShell Fluid 41, Bonderite Turco S.S.2, Ardrox AV-15, CorrosionX, Toolmates Dry Film Lubricant 6075, and Ultra Tef-Gel, as well as conducting scheduled inspections at specific intervals. This research is expected to provide more appropriate preventive strategies to extend the service life of the aircraft structure while maintaining both operational safety and efficiency.

Downloads

Download data is not yet available.

References

Azmi, N. (2018). Studi kasus pada aluminium tipe 2024-T4 dan 7075-T6 sebagai kandidat material struktur lavatory modul pesawat Boeing 737NG. Tugas Akhir, 1–52.

Cessna Aircraft. (2017). Cessna Aircraft Company. April 2014, 1–12.

Consequences, T. (2024). Part I: General aspects of corrosion, corrosion control, and corrosion prevention. Corrosion Atlas Case Studies, xxix–xlvi. https://doi.org/10.1016/b978-0-443-13228-5.09993-1

Darmawi, D., T. K., Alian, H., & Ginting, K. (2022). Ahli Korosi Dasar. 190 halaman.

Fakhri, M. N. A. F., Susanto, H., & Luqman Bukhori, M. (2022). Analisis material aluminium alloy terhadap laju korosi yang disebabkan oleh udara laut pada struktur leading edge pesawat. Teknika STTKD: Jurnal Teknik, Elektronik, Engine, 8(2), 289–294. https://doi.org/10.56521/teknika.v8i2.664

Farhan, M. N. (2021). Politeknik Negeri Jakarta Soal-Soal: 021, 21–22.

Karo-Karo, et al. (2020). Pengaruh aging dan variasi kecepatan putaran terhadap laju korosi propeller berbahan aluminium panduan. 2507(February), 1–9.

Kementrian Perhubungan Indonesia. (2006). Civil Aviation Safety Regulation (CASR) Part 1: Definitions and Abbreviations. Republic of Indonesia Ministry of Transportation, May 23, 2006, 47.

Knop, K., & Mielczarek, K. (2018). Using 5W-1H and 4M methods to analyse and solve the problem with the visual inspection process – Case study. MATEC Web of Conferences, 183, 1–6. https://doi.org/10.1051/matecconf/201818303006

Mulyati, B. (2019). Tanin dapat dimanfaatkan sebagai inhibitor korosi. Jurnal Industri, Elektro, dan Penerbangan, 8(1), 1–4.

Noval Ardiansyah, M., Dwi Cahyo, B., & Silk Moonlight, L. (2022). Analisis pengaruh larutan natrium klorida dan asam klorida terhadap laju korosi pada aluminium 1100. 1–7.

Pei, Z., Cheng, X., Yang, X., Li, Q., Xia, C., Zhang, D., & Li, X. (2021). Understanding environmental impacts on initial atmospheric corrosion based on corrosion monitoring sensors. Journal of Materials Science and Technology, 64, 214–221. https://doi.org/10.1016/j.jmst.2020.01.023

Perhubungan, K. (2003). Republic of Indonesia Ministry of Transportation Civil Aviation Safety Regulation (CASR). Certification and Operating Requirements: Domestic, Flag, and Supplemental Air Carriers, Amdt 12 (14 Agustus 2017), 263.

Rizki Ornelasari, M. (2015). Analisa laju korosi pada stainless steel 304 menggunakan metode ASTM G31-72 pada media air nira aren. JTM, 01(01), 112–117.

Undang-Undang RI tentang Penerbangan. (2009). 57, 3 May.

Utomo, B. (2012). Jenis korosi dan penanggulangannya. Kapal: Jurnal Ilmu Pengetahuan dan Teknologi Kelautan, 6(2), 138–141. https://doi.org/10.14710/kpl.v6i2.2731

Downloads

Published

2025-09-22

How to Cite

Sabrina Analisristianti, Andung Luwihono, Kukuh Tri Prasetyo, I Made Dwi Surya Dharma, & Sabam Danny Sulung. (2025). Analisis Terjadinya Korosi pada Pesawat Seaplane Amphibian Cessna 172 SP Menggunakan Fishbone di Api Banyuwangi. JURAL RISET RUMPUN ILMU TEKNIK, 4(3), 347–359. https://doi.org/10.55606/jurritek.v4i3.6733

Issue

Vol. 4 No. 3 (2025): Desember : Jurnal Riset Rumpun Ilmu Teknik

Section

Articles

License

Copyright (c) 2025 JURAL RISET RUMPUN ILMU TEKNIK

Creative Commons License

This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.