Diagnostics and prognostics for complex systems: A review of methods and challenges

Soleimani, Morteza; Campean, Felician; Neagu, Daniel

doi:10.1002/qre.2947

Cited by 23 publications

(8 citation statements)

References 211 publications

(550 reference statements)

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“…Moreover, the datasets at hand might not sufficiently capture the wide spectrum of WT configurations, environmental conditions, and operational scenarios. Dealing with miscellaneous data with multifarious characteristics is one of the main challenges [53]. Additionally, enterprises often exhibit reluctance to share data with external entities for constructing predictive and prognostic models.…”

Section: Data Challengesmentioning

confidence: 99%

Challenges on prognostics and health management for wind turbine components

Cuesta,

Leturiondo,

Vidal

et al. 2024

J. Phys.: Conf. Ser.

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This paper explores the applicability of prognostics and health management (PHM) for wind turbines (WTs), presenting the PHM approach along with challenges and opportunities in the context of WT components. First, the PHM framework is introduced, consisting of three blocks: observation, analysis, and action. Critical components and failure modes for WTs are identified, and data acquisition strategies using supervisory control and data adquisition (SCADA) and condition monitoring (CM) data are discussed. Prognostics, specifically remaining useful life (RUL) estimation, employs physics model-based, data-driven, and hybrid models. Finally, challenges and opportunities related to data, analysis and CM, and developing RUL prediction models have been found. Data challenges include data standardization, limited public datasets, and data quality issues. Analysis and CM challenges address new sensorless and non-intrusive techniques, as well as the fusion of data sources. Prognostics model challenges involve uncertainty management, interpretability issues, and the need for online updates. Addressing challenges requires incorporating physical knowledge, utilizing transfer learning, and improving online RUL prediction methods.

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Section: Data Challengesmentioning

confidence: 99%

Challenges on prognostics and health management for wind turbine components

Cuesta,

Leturiondo,

Vidal

et al. 2024

J. Phys.: Conf. Ser.

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“…Because these models describe physical processes, they directly and indirectly influence the operational state of equipment (Nunes, Santos and Rocha, 2023). Physics-based approaches can be used when precise mathematical models are available for a production system, based on its physical features (Soleimani, Campean and Neagu, 2021). These models provide a better way to handle the bias in the measured data and can describe the behaviour of a system, in different operating conditions.…”

Section: Literature Reviewmentioning

confidence: 99%

Proposal of a Machine Learning Predictive Maintenance Solution Architecture

Pătrașcu,

Bucur,

Tănăsescu

et al. 2024

INT J COMPUT COMMUN, Int. J. Comput. Commun. Control

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This article proposes an architecture model for a predictive maintenance solution that can be used to detect degradation of equipment in industrial units. This platform is compliant with Industry 4.0 standards and employs machine-learning algorithms alongside with data analytics methodologies to model the kinetics of equipment degradation. This serves the overarching aim of Industry 4.0 by enabling real-time, data-driven decision-making and complex asset management. To model the deterioration of the equipment, advanced data analysis techniques and machine learning were used, thus allowing for the early identification of imminent failures and reducing system downtime. The proposed solution was validated through numerous experiments and a comprehensive analysis of data. The results indicate not only enhanced operational reliability but also a reduction in environmental impact, thereby highlighting the value of intersecting Industry 4.0 and Sustainability paradigms in the field of industrial systems.

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“…Physical models are accurate mathematical models in which a failure mechanism is quantitatively characterized using physical laws. 11 These methods simulate the degradation of a component 12,13 with a mathematical model and usually address a unique failure mechanism. However, this may complicate the coverage of the total degradation (typically being a combination of different failure mechanisms) in a real application.…”

Section: Introductionmentioning

confidence: 99%

Integration of multiple failure mechanisms in a life assessment method for centrifugal pump impellers

Silveira

Meghoe

Tinga

2023

Advances in Mechanical Engineering

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Methods in predictive maintenance are frequently confronted with limited applicability to realistic scenarios. The available approaches are often used for a single design, requiring an entirely new analysis for a slightly different case. A solution for this issue could be using a physical model. However, physical models focus on one unique failure mechanism, while, in a practical application, several mechanisms are typically active at the same instant. This work proposes and demonstrates a new methodology that combines different failure mechanism into an integrated life prediction model. Failure Modes and Effects Analysis is used to identify the different failure mechanisms that occur in a component simultaneously. Physical and empirical models are then analyzed and modified to be implemented in a realistic case of a centrifugal pump impeller applied in a maritime environment. As erosion, cavitation, and corrosion are the main failure mechanisms of an impeller, the combination of them quantifies the degradation increment during different types of pump operation. The proposed methodology is compared with traditional failure rate models and an established cavitation model that uses an aging factor to cover other failure mechanisms. In conclusion, it is demonstrated that the proposed methodology is more sensitive and reliable in describing the degradation process for a wide range of operating conditions, since all the mechanisms are considered.

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Diagnostics and prognostics for complex systems: A review of methods and challenges

Cited by 23 publications

References 211 publications

Challenges on prognostics and health management for wind turbine components

Challenges on prognostics and health management for wind turbine components

Proposal of a Machine Learning Predictive Maintenance Solution Architecture

Integration of multiple failure mechanisms in a life assessment method for centrifugal pump impellers

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