The most ship accidents occurred on size between 35GT and 500GT, including traditional wooden boats. The accidents were dominated by capsizing due to bad weather. Therefore the safety of traditional wooden boats needs to be improved. This paper discusses the position of bilge keels and their impact on the roll motion performance of an Indonesian traditional wooden boat. The roll damping is determined by a roll decay test with three different positions of bilge keels, namely 15 degrees, 30 degrees, and 45 degrees. The roll amplitude is determined in the frequency domain by solving the uncoupled nonlinear roll motion equation with an effective wave slope coefficient calculated using the simplified Froude-Krylov assumption of roll exciting moment. The bilge keels position with the angle of 15 degrees reduced the roll amplitude of 18% while the position with an angle of 30 degrees decreases the roll amplitude by 7% of roll amplitude without bilge keels. The bilge keels position with an angle of 45 degrees reduced the roll amplitude by 2% of those without bilge keels. The natural roll period was not significantly affected by the bilge keels position. The bilge keels position with an angle of 15 degrees is the most effective position to reduce the roll amplitude.

D. Paroka, A.H. Muhammad, S. Rahman and M.A. Asis, “Operational limitatiton of Indonesia traditional wooden boat in the framework of the second generation intact stability criteria,” presented at the Sustainable Island Development Initiatives Conference, Surabaya, Indonesia, 2019.

B. Prihartono ”Development of tol laut in the Middle-term National Development Plan 2015-2020 and its implementation on 2015,” National Development Planning Agency of Indonesia, 2015 (in Indonesian).

W. Liu, Y.K. Demirel, E.B. Djatmiko, S. Nugroho, T. Tezdogan, R.E. Kurt, H. Supomo, I. Baihaqi, Z. Yuan and A. Incecik, “Bilge keel design for the traditional fishing boats of Indonesia’s East Java”., Int. J. of Naval Arch. and Ocean Eng., vol. 11(1), pp. 380 – 395, Jan. 2019.

C.C. Bassler and A.M. Reed, “An analysis of the bilge keel roll damping component model,” presented at the 10th Intl. Conf. On Stability of Ships and Ocean Vehicles, St. Petersburg, Rusia, 2009.

M.A.R. Irkal, S. Nallayarasu and S.K. Bhatracharyya, “Numerical prediction of roll damping of ships with and without bilge keel,” Ocean Engineering, vol. 179(2019) pp. 226-245, 2019.

G.G. Cox and A.R. Lloyd, “Hydrodynamic design basis for navy ship roll motion stabilization,” SNAME Transaction, vol. 85, pp. 51 – 93, 1977.

Y. Gu, S. Day and E. Boulougouris, “A study on the effect of bilge keels on roll damping coefficient,”presented at the 12th Int. Conf. on the Stability of Ships and Ocean Vehicles, Glasgow, UK, 2015.

E. Fesman, D. Bayraktar and M. Taylan, “Influence of damping on the roll motion of ships,” presnted at the 2nd Int. Conf. on Marine Research and Transportation, Naples, Italy, 2007.

D. Paroka, S. Asri, Rosmani and Hamzah, “Alternative assessment of weather criterion for ships with large breadth and draught ratio by model experiment: a case study on an Indonesian ro-ro ferry”, Int. J. of Maritime Engineering vol. 162(1), pp. 55 – 64, 2020.

Y. Ikeda, K. Komatsu, Y. Himeno and N. Tanaka, ”On roll damping force of ship –effect of hull surface pressure created by bilge keel,” Dept. of Naval Architecture, University of Osaka Prefecture, 1979.

H. Hendratmoko, Hasanudin and I.K.A.P. Utama, ”Experimental study on effect of bilge keels on roll motion,” J. Teknik vol.1(1), pp. G.94 – G.97, 2012 (in Indonesian).

P.K.D.N.Y. Putra, B.H. Iskandar and Y. Novita, “Using length of bilge keel to length of waterline ratio to reduce ship rolling motion,” Eng. Tech. & App. Science Research, vol. 8(2), pp. 2731 – 2734, 2018.

ITTC, “Recommended procedures: numerical estimation of roll damping,” presented at the 26th ITTC Specialist Committee on Stability in Waves, Rio de Jeneiro, Brazil, 2011.

IMO, “MSC.1/Circ.1200 – Interim guidelines for alternative assessment of the weather criterion,” London, UK, 2011.

IMO, “SDC 1/INF.6 – Development of second generation intact stability criteria: vulnerability assessment for dead-ship stability failure mode,” 2013.

P. Berrisford, D.P. Dee, P. Poli, R. Brugge, K. Fielding, M. Fuentes, P.W. Kallberg, S. Kobayashi, S. Uppala and A. Simmos, “The ERA Interim Archive Version 2.0. Report Series 1,” http://ecmwf.int/en/elibrary/8174, 2011.

M.A.R. Irkal, S. Nallayarasu and S.K. Bhattacharyya, “CFD approach to roll damping of ship with bilge keel with experimental validation,” App. Ocean Research, vol. 55, pp. 1 – 17, 2016.

T. Katayama, M. Matsuoka and K. Ikushima, “Characteristics of bilge keel roll damping component for shallow draft,” presented at the 13th Int. Conf. on the Stability of Ships and Ocean Vehicles Kobe, Japan, 2018.