Shipyard is an industry engaged in the maintenance and repair of ships and constructing a new ship. In ship repair operations, there are many activities in this operation. Propeller inspection, blasting, replating, welding, general work, electric work is an activity in ship repair operation. This research proposed a methodology to risk analysis ship maintenance operation, integrating Job Safety Analysis (JSA) with Bayesian Network (BN) and Fuzzy Inferences System (FIS). JSA method is used to find the hazards and the consequences of the maintenance operation. BN is developed for probability calculating of likelihood factors. Meanwhile, the FIS is used as a method to calculate the risk level. The FIS using the Mamdani algorithm based on the expert’s knowledge and experience. The integration of three methods is used to complete the risk assessment for replating activities. The proposed method is used to find out the risk level of replating activity on ship maintenance. Based on the result, the proposed model is more accurate, precise, and flexible depending on the basic factor that influences the operation. It would help to reduce the potential accident on the operation. This proposed method could be the other option as a tool to calculate risk assessment in other operations.

Job Safety Analysis; Bayesian Networks; Fuzzy; Replating; Risk Assessment

Barlas B. Shipyard fatalities in Turkey. Safety Science 2012;50(5):1247–1252.

Basuki M, Artana KB, Nugroho S, Dinariyana AAB. Shipbuilding Industry in Indonesia, a Risk Perspective (in Indonesia). In: Proceedings of national Seminar of Postgraduate study Surabaya: Institut Teknologi Sepuluh Nopember Surabaya; 2010. p. 1–6.

Jamshidi A, Yazdani-Chamzini A, Yakhchali SH, Khaleghi S. Developing a new fuzzy inference system for pipeline risk assessment. Journal of Loss Prevention in the Process Industries 2013;26(1):197–208.

Chao EL, Henshaw JL. Job Hazard Analysis. OSHA Publication 3071 2002 (Revised),” Occupational Safety and Health Administration. In: Job Hazard Analysis, vol. 29 Washington: US Department of Labor; 2002.p. 1–21.

Holt ASJ. Principles of Construction Safety. London: Blackwell Science; 2011.

Santoso B. Perbandingan Pendekantan Muhlbauer dan Fuzzy Inference System Pada Proses Penilaian Resiko: Studi kasus Pipa Bawah Laut 14" PHE-WMO. PhD thesis, Institut Teknologi Sepuluh Nopember Surabaya; 2014.

Friis-Hansen P, Simonsen BC. GRACAT: software for grounding and collision risk analysis. Marine Structures 2002;15(4- 5):383–401.

Medina Oliva G, Weber P, Simon C, Iung B. Bayesian networks applications on dependability, risk analysis and maintenance. 2nd IFAC Workshop on Dependable Control of Discrete System 2009;2:245–250.

Kurniawan A, Santoso M, Dhani MR. Identifikasi Bahaya Pada Pekerjaan Maintenance Kapal Menggunakan Metode HIRARC dan FTA Dengan Pendekatan Fuzzy di Industri Kapal. In: Proceeding 1st Conference on Safety Engineering and Its Application Surabaya, Indonesia: Politeknik Perkapalan Negeri Surabaya; 2017. p. 182–186.

Oktavia CA, Maulidi R. Penerapan Logika Fuzzy Sugeno untuk Penenuan Reward pada Game Edukasi Aku Bisa. JUTI: Jurnal Ilmiah Teknologi Informasi 2019 aug;17(2):117–124.

Farosanti L, Fatichah C. Perbaikan Segmentasi Pembuluh Darah Tipis Pada Citra Retina Menggunakan Fuzzy Entropy. JUTI: Jurnal Ilmiah Teknologi Informasi 2019 aug;17(2):135.

Administration OS, Health. Job Hazard Analysis. Washington: US Department of Labor; 2002.

Swartz G. Job Hazard Analysis - a primer on identifying and controlling hazards. Professional Safety 2002;47(11):27–33.

Raveggi F, Mazzetti S. Job Safety Analysis as a mean to increase safety awareness and achieve sustainable improvements in safety performance. Chemical Engineering Transactions 2010;19:421–425.

Pearl J. Probabilistic Reasoning in Intelligent Systems. San Francisco, CA: Morgan Kauffman; 1975.

Wang ZZ, Chen C. Fuzzy comprehensive Bayesian network-based safety risk assessment for metro construction projects. Tunnelling and Underground Space Technology 2017;70:330–342.

Nguyen LD, Tran DQ, Chandrawinata MP. Predicting safety risk of working at heights using bayesian networks. Journal of Construction Engineering and Management 2016;142(9):040–16041.

Murphy kP. Dynamic Bayesian Networks: Representation, Inference and Learning. PhD thesis, University of California, Berkeley; 2002.

Wang Y, Li L, Chang M, Chen H, Dong X, Ren Y, et al. Fault Diagnosis Expert System Based on Integration of FaultTree and Neural Network. In: Proceedings - 2009 International Conference on Computational Intelligence and Software Engineering, CiSE 2009 IEEE; 2009. p. 1–4.

Jaderi F, Ibrahim ZZ, Zahiri MR. Criticality analysis of petrochemical assets using risk based maintenance and the fuzzy inference system. Process Safety and Environmental Protection 2019;121:312–325.

Ghaseni E, Ataei M. Application of fuzzy logic for predicting roof fall rate in coal mines. Neural Comput & Applic 2013;22(1):S311–S321.

Daftaribesheli A, Ataei M, Sereshki F. Assessment of rock slope stability using the Fuzzy Slope Mass Rating (FSMR) system Abbas. Applied Soft Computing Journal 2011;11(8):4465–4473.

Markowski AS, Mannan MS. Fuzzy logic for piping risk assessment (pfLOPA). Journal of Loss Prevention in the Process Industries 2009;22(6):921–927.