Efficient Reliability Analysis of an Axial Compressor in Consideration of Epistemic Uncertainty

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

Autoren

  • Julian Salomon
  • Niklas Winnewisser
  • Pengfei Wei
  • Matteo Broggi
  • Michael Beer

Externe Organisationen

  • Northwestern Polytechnical University
  • Tongji University
  • The University of Liverpool
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Details

OriginalspracheEnglisch
Titel des SammelwerksProceedings of the 30th European Safety and Reliability Conference and the 15th Probabilistic Safety Assessment and Management Conference
Herausgeber/-innenPiero Baraldi, Francesco Di Maio, Enrico Zio
Seiten4791-4798
Seitenumfang8
PublikationsstatusVeröffentlicht - 2020
Veranstaltung30th European Safety and Reliability Conference, ESREL 2020 and 15th Probabilistic Safety Assessment and Management Conference, PSAM15 2020 - Venice, Italien
Dauer: 1 Nov. 20205 Nov. 2020

Abstract

The reliability of complex systems, e.g. infrastructure networks or turbines, and further its proper prediction, is of paramount importance to our modern society. The concept of survival signature enables to entirely separate the structure of a network and its components probabilistic properties. As a consequence, once survival signature of a network has been computed, a reliability analysis can be performed by evaluating only the probabilistic part of the network. It is precisely this advantage that makes the analysis particularly efficient and clearly distinguishes the concept from traditional approaches. In reality, epistemic uncertainties, as vague or varying expert knowledge on a component’s future behavior, impede a proper reliability analysis. Considering and quantifying these in a plausible manner is therefore of major interest to decision-makers. Fuzzy probabilities offer a naturally fitting approach for this purpose. Despite the advantageous efficiency of the survival signature, analyzing complex systems under considertaion of epistemic uncertainties implies high computational effort. In order to counteract these efforts, two extended Monte Carlo simulation methods, originally utilized for imprecise structural reliability problems, are adapted into the context of system reliability. By integrating fuzzy probabilities into the probability structure of the survival signature and employing advanced Monte Carlo methods, this paper provides an efficient approach to quantify the reliability of a complex system taking into account epistemic uncertainties. Beyond the merging of the theoretical aspects, the approach is applied to a functional model of an axial compressor, in order to demonstrate its usability.

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Efficient Reliability Analysis of an Axial Compressor in Consideration of Epistemic Uncertainty. / Salomon, Julian; Winnewisser, Niklas; Wei, Pengfei et al.
Proceedings of the 30th European Safety and Reliability Conference and the 15th Probabilistic Safety Assessment and Management Conference. Hrsg. / Piero Baraldi; Francesco Di Maio; Enrico Zio. 2020. S. 4791-4798.

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

Salomon, J, Winnewisser, N, Wei, P, Broggi, M & Beer, M 2020, Efficient Reliability Analysis of an Axial Compressor in Consideration of Epistemic Uncertainty. in P Baraldi, F Di Maio & E Zio (Hrsg.), Proceedings of the 30th European Safety and Reliability Conference and the 15th Probabilistic Safety Assessment and Management Conference. S. 4791-4798, 30th European Safety and Reliability Conference, ESREL 2020 and 15th Probabilistic Safety Assessment and Management Conference, PSAM15 2020, Venice, Italien, 1 Nov. 2020. https://doi.org/10.3850/978-981-14-8593-0_3685-cd
Salomon, J., Winnewisser, N., Wei, P., Broggi, M., & Beer, M. (2020). Efficient Reliability Analysis of an Axial Compressor in Consideration of Epistemic Uncertainty. In P. Baraldi, F. Di Maio, & E. Zio (Hrsg.), Proceedings of the 30th European Safety and Reliability Conference and the 15th Probabilistic Safety Assessment and Management Conference (S. 4791-4798) https://doi.org/10.3850/978-981-14-8593-0_3685-cd
Salomon J, Winnewisser N, Wei P, Broggi M, Beer M. Efficient Reliability Analysis of an Axial Compressor in Consideration of Epistemic Uncertainty. in Baraldi P, Di Maio F, Zio E, Hrsg., Proceedings of the 30th European Safety and Reliability Conference and the 15th Probabilistic Safety Assessment and Management Conference. 2020. S. 4791-4798 doi: 10.3850/978-981-14-8593-0_3685-cd
Salomon, Julian ; Winnewisser, Niklas ; Wei, Pengfei et al. / Efficient Reliability Analysis of an Axial Compressor in Consideration of Epistemic Uncertainty. Proceedings of the 30th European Safety and Reliability Conference and the 15th Probabilistic Safety Assessment and Management Conference. Hrsg. / Piero Baraldi ; Francesco Di Maio ; Enrico Zio. 2020. S. 4791-4798
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note = "Funding Information: Funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) ? SFB 871/3 ? 119193472; 30th European Safety and Reliability Conference, ESREL 2020 and 15th Probabilistic Safety Assessment and Management Conference, PSAM15 2020 ; Conference date: 01-11-2020 Through 05-11-2020",
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AU - Salomon, Julian

AU - Winnewisser, Niklas

AU - Wei, Pengfei

AU - Broggi, Matteo

AU - Beer, Michael

N1 - Funding Information: Funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) ? SFB 871/3 ? 119193472

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N2 - The reliability of complex systems, e.g. infrastructure networks or turbines, and further its proper prediction, is of paramount importance to our modern society. The concept of survival signature enables to entirely separate the structure of a network and its components probabilistic properties. As a consequence, once survival signature of a network has been computed, a reliability analysis can be performed by evaluating only the probabilistic part of the network. It is precisely this advantage that makes the analysis particularly efficient and clearly distinguishes the concept from traditional approaches. In reality, epistemic uncertainties, as vague or varying expert knowledge on a component’s future behavior, impede a proper reliability analysis. Considering and quantifying these in a plausible manner is therefore of major interest to decision-makers. Fuzzy probabilities offer a naturally fitting approach for this purpose. Despite the advantageous efficiency of the survival signature, analyzing complex systems under considertaion of epistemic uncertainties implies high computational effort. In order to counteract these efforts, two extended Monte Carlo simulation methods, originally utilized for imprecise structural reliability problems, are adapted into the context of system reliability. By integrating fuzzy probabilities into the probability structure of the survival signature and employing advanced Monte Carlo methods, this paper provides an efficient approach to quantify the reliability of a complex system taking into account epistemic uncertainties. Beyond the merging of the theoretical aspects, the approach is applied to a functional model of an axial compressor, in order to demonstrate its usability.

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