Abstract
The evaluation of the safe maximum working pressure and the probability of failure of corroded pipes are important steps in the development of risk-based strategies for the inspection and maintenance of pipes carrying oil and gas. These parameters are often calculated based on the inspection results and using probabilistic analysis. To account for the variations in the dimensions of the inspected corrosion pits, the probabilistic approach combines a corroded pipe integrity model, like the ASME B31G, with the probability density functions of the input parameters—pipe wall thickness, corrosion pit length, corrosion pit depth and applied pressure—to predict the probability of failure. This paper compares the traditional probabilistic approach with an alternative possibilistic approach. In the possibilistic approach the input variables are regarded as fuzzy variables whose membership functions are developed from the statistical inspection data. The calculations are carried out using fuzzy arithmetic based on extended interval analysis. Instead of the probability of failure, the possibilistic approach gives the possibility and necessity measures of the likelihood of failure. The possibility and necessity measures are, respectively, more and less conservative than the probability of failure.
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References
Ahammed M (1997) Prediction of remaining strength of corroded pressurised pipelines. Int J Press Vessel Pip 71:213–217
Ahammed M (1998) Probabilistic estimation of remaining life of a pipeline in the presence of active corrosion defects. Int J Press Vessels Pip 75:321–329
Ahammed M, Melchers RE (1996) Reliability estimation of pressurised pipelines subject to localised corrosion defects. Int J Press Vessels Pip 69:267–272
ANSI/ASME (1991) ASME B31G-1991: manual for determining the remaining strength of corroded pipelines. The American Society of Mechanical Engineers
Ayyub BM, Chao R-J (1998) Uncertainty modeling in civil engineering with structural and reliability applications. In: Ayyub BM (ed) Uncertainty modeling and analysis in civil engineering. CRC Press, Boca Raton, pp 3–31
Ayyub BM, Klir GJ (2006) Uncertainty modeling and analysis in engineering and sciences. Chapman & Hall/CRC Press, Boca Raton
Dubois D, Foulloy L, Mauris G, Prade H (2004) Probability–possibility transformations, triangular fuzzy sets, and probabilistic inequalities. Reliab Comput 10:273–297
Freire JLF, Vieira RD, Castro JTP, Benjamin AC (2006) Burst tests of pipeline with extensive longitudinal metal loss. Exp Tech 30(6):60–65
Guyonnet D, Come B, Perrochet P, Parriaux A (1999) Comparing two methods for addressing uncertainties in risk assessments. J Environ Eng 125(7):660–666
Karimi I, Hüllermeier E (2007) Risk assessment system of natural hazards: A new approach based on fuzzy probability. Fuzzy Sets Syst 158:987–999
Mauris G, Lasserre V, Foulloy L (2001) A fuzzy approach for the expression of uncertainty in measurement. Measurement 29:165–177
Melchers RE (2001) Structural reliability analysis and prediction. Wiley, Chichester
Ross TJ (2004) Fuzzy logic with engineering applications, 2nd edn. Wiley, New Mexico
Singh M, Markeset T (2007) Risk analysis of oil and gas pipelines subjected to CO2 corrosion. In: Proceedings of the ESREL 2007 conference, University of Stavanger, Stavanger, 25–27 June 2007
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Singh, M., Markeset, T. Handling of variability in probabilistic and possibilistic failure analysis of corroded pipes. Int J Syst Assur Eng Manag 5, 503–512 (2014). https://doi.org/10.1007/s13198-013-0197-y
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DOI: https://doi.org/10.1007/s13198-013-0197-y