This research presents a comparative study focused on estimating the lifespan of galvanized steel pipes and stainless steel pipes within the context of a ballast system. Ballast systems play a crucial role in maintaining the stability and trim of vessels, making the longevity of the associated piping materials essential for maritime operations. This research aims to provide insights into the corrosion behavior and overall durability of galvanized steel and stainless steel pipes employed in ballast systems. The investigation involves an in-depth analysis of corrosion mechanisms specific to both galvanized steel and stainless steel pipes in the corrosive marine environment. The influence of factors such as salinity, and immersion time is examined. By understanding the distinct corrosion behavior of galvanized steel and stainless steel pipes, maritime industry stakeholders can make informed decisions regarding material selection, maintenance schedules, and potential retrofitting options. Ultimately, the insights gained from this study contribute to the sustainability and operational efficiency of maritime transport by enabling the optimization of ballast system infrastructure. As regulations and environmental considerations evolve, a comprehensive understanding of the lifespan estimation of galvanized steel and stainless steel pipes aids in mitigating potential failures, reducing downtime, and ensuring the safety and reliability of vessel operations. It is shown that the lifespan of stainless steel is longer than that of galvanized pipe.

Lifespan; corrosion rate; ballast system; galvanized steel pipe; stainless steel

Sankara Papavinasam, “Corrosion Control in the Oil and Gas Industry”. 1st Edition, 2013. Hardback ISBN: 9780123970220.

Alireza Bahadori, “Corrosion and Materials Selection A Guide for the Chemical and Petroleum Industries”. 1st Edition, 2014. Wiley ISBN: 9781118869208.

Branko N. Popov. “Corrosion Engineering: Principles and Solved Problems”. 2015. Elsevier. https://doi.org/10.1016/C2012-0-03070-0

Mohinder L. Nayyar, P.E, “Piping Handbook”. 7th Edition. 2000. ISBN 0-07-047106-1

Gerhardus H. Koch, Michiel Peter Hein Brongers. G. Thompson, “Corrosion Cost and Preventive Strategies in the United States”. 2001.

Charles Becht. “Process Piping: The Complete Guide to the ASME B31.3, Fourth Edition”. 2021. ASME. 9780791883792

Karan Sotoodeh, “Analysis and Improvement of Material Selection for Process Piping System in Offshore Industry”. American Journal of Mechanical Engineering, 2018, Vol. 6, No. 1, 17-26, DOI:10.12691/ajme-6-1-3.

Fei Du et al., “Life Cycle Analysis for Water and Wastewater Pipe Materials”. 2012. Journal of Environmental Engineering. Volume 139, No 5. https://doi.org/10.1061/(ASCE)EE.1943-7870.0000638

Tanzer Satir, “Ballast water treatment systems: design, regulations, and selection under the choice varying priorities”. 2014. Environmental Science and Pollution Research. DOI: 10.1007/s11356-014-3087-1

Junko Kazumi, “Ballast Water Treatment Technologies and Their Application for Vessels Entering the Great Lakes via the St. Lawrence Seaway”. 2007. Transportation Research Board Special Report 291- Great Lakes Shipping, Trade, And Aquatic Invasive Species.

Md. Imteaz Ahmed et al., “Determination of Corrosion Rate of Mild Steel in Different Medium Measuring Current Density”. 2017. Conference: 4th International Conference on Mechanical Engineering and Renewable Energy ICMERE 2017.

Hall, Jane, and Glenn Hollins. "Corrosion Rate Measurement using Electrochemical Technique." Paper presented at the CORROSION 2016, Vancouver, British Columbia, Canada, March 2016.

William Hawkes, “The Principle Mechanisms of Corrosion”. 2020. Graduate Diploma Spring Term 2013-2014.

Raghuvir Singh.” Corrosion Evaluation and Monitoring Practices”. Industrial Corrosion: Evaluation & Mitigation. pp. 48-67.

ASTM-G01–03. (2011). Standard Practice for Preparing, Cleaning, and Evaluating Corrosion Test Specimens. Annual Book of ASTM Standards, 1–9. https://doi.org/10.1520/G0001- 0.