Pengaruh Variasi Jenis Anoda Korban terhadap Laju Korosi Pipa ASTM A53 pada Media Tanah Liat
DOI:
https://doi.org/10.29407/jmn.v9i1.27019Keywords:
ASTM A53, anoda korban, laju korosi, proteksi katodik, polarisasi potensiodinamikAbstract
Korosi pada pipa baja ASTM A53 yang tertanam di dalam tanah dapat menurunkan umur pakai serta keandalan sistem perpipaan. Salah satu metode yang banyak digunakan untuk mengendalikan korosi adalah proteksi katodik menggunakan anoda korban. Penelitian ini bertujuan menganalisis pengaruh variasi jenis anoda korban, yaitu magnesium (Mg), aluminium (Al), dan seng (Zn), terhadap laju korosi pipa ASTM A53 pada media tanah liat. Pengujian dilakukan dengan metode polarisasi potensiodinamik mengacu pada ASTM G102 setelah spesimen dipendam selama 30 hari. Nilai laju korosi dihitung berdasarkan arus korosi (Icorr) yang diperoleh dari hasil pengujian. Hasil penelitian menunjukkan bahwa penggunaan anoda korban mampu menurunkan laju korosi dibandingkan spesimen tanpa proteksi. Anoda magnesium memberikan perlindungan paling efektif dengan laju korosi sebesar 0,3110 mmpy, atau menurunkan laju korosi sebesar 86,2% dibandingkan spesimen tanpa anoda yang memiliki laju korosi 2,2568 mmpy. Sementara itu, anoda aluminium dan seng juga mampu menurunkan laju korosi, namun efektivitasnya lebih rendah dibandingkan magnesium. Hasil penelitian menunjukkan bahwa pemilihan jenis anoda korban berpengaruh signifikan terhadap efektivitas proteksi katodik pada pipa ASTM A53 di lingkungan tanah liat, dengan magnesium sebagai material anoda yang memberikan kinerja perlindungan terbaik
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[1] D. S. P. T. Iswanto, “Desain Proteksi Katodik pada Struktur Baja di Laut dan di Darat untuk Masa Layan 10 Tahun,” vol. 2, no. 2, pp. 77–86, 2020.
[2] D. Rosalina and S. Komalasari, “Proteksi Katodik Dengan Menggunakan Anoda Korban Pada Struktur Baja Karbon Untuk Mengendalikan Laju Korosi,” vol. 6, pp. 2–6, 2019.
[3] N. Mulyaningsih, A. Muhib, and S. Hastuti, “Penggunaan Proteksi Katodik pada Pipa Air PDAM di Lingkungan Tanah Alluvial,” vol. 6, no. 2, pp. 65–68, 2022.
[4] T. T. Windriawan, N. Mulyaningsih, and A. N. S. H. Darmo, “Pengaruh Jarak Anoda Korban Aluminium Terhadap Laju Korosi Baja ASTM A36 Dalam Lingkungan Air Laut,” Majamecha, vol. 7, no. 1, pp. 1–12, 2025.
[5] H. Wicaksono and B. Sulaksono, “ANALYSIS OF CATHODIC PROTECTION SYSTEM TYPE OF VICTIM ANODES USING MAGNESIUM AND ZINC,” pp. 9–10, 2019.
[6] “Electrochemical Evaluation of Mg and a Mg-Al 5%Zn Metal Rich Primers for Protection of Al-Zn- Mg-Cu Alloy in NaCl A. Korjenic”.
[7] R. Indarti, Y. T. Sarungu, and C. Magesang, “KARAKTERISASI SIMULATOR SISTEM PROTEKSI PERPIPAAN YANG TERTANAM DALAM TANAH,” pp. 41–45, 1997.
[8] T. Kyada, S. Patel, A. Babu, S. Lulaniya, and T. Rakholiya, “Aluminum Alloy as Sacrificial Anode for Corrosion Protection : A Review,” vol. 11, no. 2, pp. 1–13, 2025.
[9] K. Lama, “Rancangan Dasar Perhitungan Proteksi Katodik dengan Menggunakan Anoda Korban Pada Struktur Baja Anjungan Minyak di Lingkungan Air Laut,” vol. 45, no. 1, pp. 79–90, 2011.
[10] J. R. Material et al., “FT-UMSU FT-UMSU,” vol. 7, no. 2, pp. 236–243, 2024.
[11] P. Potensiodinamik, B. Beton, K. Puspiptek, and T. Selatan, “AIR LAUT DAN KARBONAT,” pp. 165–171, 2016.
[12] D. N. Abdulamer, “Journal of Petroleum Research & Studies,” no. 9.
[13] S. M. A. Bukhari, S. A. R. Gardezi, N. Husnain, R. Ahmad, M. F. Zaman, and R. Qurashi, “Asia - Pacific Journal of Science and Technology Modelling and simulation of cathodic protection using magnesium sacrificial anode for steel Bent-Y-Pipe in seawater environment”.
[14] L. Pongsapan and A. Suhadi, “Efektivitas Penggunaan Anoda Korban Paduan Seng Pada Pelat Baja Kapal AISI E 2512 Terhadap Laju Korosi Di Dalam Media Air Laut,” vol. 1, no. 1, pp. 40–47.
[15] D. Tamhane, J. Thalapil, S. Banerjee, and S. Tallur, “Smart cathodic protection system for real-time quantitative assessment of corrosion of sacrificial anode based on Electro-Mechanical Impedance (EMI),” 2024.
[16] G. Priyotomo and L. Nuraini, “The Selection of Magnesium alloys as Sacrificial Anode for the Cathodic Protection of Underground Steel Structure,” vol. 51, no. 2, pp. 78–82, 2017.
[17] S. Anwar, Y. Octavitri, I. Purnaningratri, and I. M. Sofian, “Electrochemical Performance of Sacrificial Anode Metals in Preventing Corrosion on Ships : A Literature Review,” vol. 4, no. 1, pp. 2208–2216, 2025.
[18] A. Mahgoub and G. Houtan, “Limitation of Aluminum Anode in Cathodic Protection Applications,” vol. 10, no. 2, pp. 9–17, 2024.
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