Reliability analysis of complex shipyard transportation system with dependent components

• Autorzy: Blokus-Roszkowska A. , Kołowrocki K.
• Języki publikacji: EN

Abstrakty

EN

In the paper an approach to the reliability analysis of multi-state systems with dependent components operating at variable operation conditions is presented. The multi-state reliability function of complex system is defined and determined for the shipyard rope ship elevator. In developed models, it is assumed that system components have the multi-state exponential reliability functions with interdependent departures rates from the subsets of reliability states.

Słowa kluczowe

EN

reliability; multi-state system; ageing; operation process; dependability; complex system; shipyard transportation system

• Wydawca: Polskie Towarzystwo Bezpieczeństwa i Niezawodności
• Czasopismo: Journal of Polish Safety and Reliability Association
• Rocznik: 2014
• Tom: Vol. 5, No. 1
• Strony: 21--32
• Opis fizyczny: Bibliogr. 16 poz., rys., tab., wykr.

Twórcy

autor

Blokus-Roszkowska A.

• Maritime University, Gdynia, Poland

autor

Kołowrocki K.

• Maritime University, Gdynia, Poland

Bibliografia

• [1] Blokus-Roszkowska, A. (2007). On component failures’ dependency influence on system’s lifetime. Int J of Reliab, Quality and Safety Eng. Special Issue: System Reliability and Safety 14(6), 1-19.
• [2] Blokus-Roszkowska, A. (2007). Reliability analysis of homogenous large systems with component dependent failures. PhD Thesis, Gdynia Maritime University – System Research Institute Warsaw, (in Polish).
• [3] Blokus-Roszkowska, A. & Kołowrocki, K. (2008). Modelling environment and infrastructure of shipyard transportation systems and processes. Int J of Mat & Struct Reliab 6(2), 153-166.
• [4] Blokus-Roszkowska, A. & Kołowrocki, K. (2014). Reliability analysis of ship-rope transporter with dependent components. Proc. European Safety and Reliability Conference – ESREL 2014, Poland, Wrocław, (in prep.).
• [5] Grabski, F. (2002). Semi-Markov Models of Systems Reliability and Operations Analysis. System Research Institute, Polish Academy of Science, (in Polish).
• [6] Kołowrocki, K. (2013). On safety of critical infrastructures. Journal of Polish Safety and reliability Association, Summer Safety and Reliability Seminars 4(1), 51-72.
• [7] Kołowrocki, K. (2014). Reliability of Large and Complex Systems. Elsevier.
• [8] Kołowrocki, K. & Soszyńska-Budny, J. (2011). Reliability and Safety of Complex Technical Systems and Processes: Modeling – Identification – Prediction – Optimization. Springer.
• [9] Limnios, N. & Oprisan, G. (2005). Semi-Markov Processes and Reliability. Birkhauser, Boston.
• [10] Pradhan, S. & Chakrabarti, Bikas K. (2003). Failure properties of fiber bundles. Int. J. Mod. Phys. B 17, 5565.
• [11] Pradhan, S. & Hansen, A. (2005). Failure properties of fiber bundle model having lower cutoff in fiber threshold distribution. Phys. Rev. E. 72, 026111.
• [12] Soszyńska, J. (2007). Systems reliability analysis in variable operation conditions. PhD Thesis, Gdynia Maritime University-System Research Institute Warsaw, (in Polish).
• [13] Xue, J. (1985). On multi-state system analysis. IEEE Trans on Reliab. 34, 329-337.
• [14] Xue, J. & Yang, K. (1995). Dynamic reliability analysis of coherent multi-state systems. IEEE Trans on Reliab. 4(44), 683-688.
• [15] Xue, J. & Yang, K. (1995). Symmetric relations in multi-state systems. IEEE Trans on Reliab 4(44), 689-693.
• [16] Yu, K., Koren, I. & Guo, Y. (1994). Generalised multi-state monotone coherent systems. IEEE Trans on Reliab 43, 242-250.