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Predictive Maintenance Modelling for Through-Life Engineering Services
Predictive maintenance needs to forecast the numbers of rejections at any overhaul point before any failure occurs in order to accurately and proactively take adequate maintenance action. In healthcare, prediction has been applied to foretell when and how to administer medication to improve the health condition of the patient. The same is true for maintenance where the application of prognostics can help make better decisions. In this paper, an overview of prognostic maintenance strategies is presented. The proposed data-driven prognostics approach employs a statistical technique of (i) the parameter estimation methods of the time-to-failure data to predict the relevant statistical model parameters and (ii) prognostics modelling incorporating the reliability Weibull Cumulative Distribution Function to predict part rejection, replacement, and reuse. The analysis of the modelling uses synthetic data validated by industry domain experts. The outcome of the prediction can further proffer solution to designers, manufacturers and operators of industrial product-service systems. The novelty in this paper is the development of the through-life performance approach. The approach ascertains when the system needs to undergo maintenance, repair and overhaul before failure occurs
A framework development to predict remaining useful life of a gas turbine mechanical component
Power-by-the-hour is a performance based offering for delivering outstanding service to operators of civil aviation aircraft. Operators need to guarantee to minimise downtime, reduce service cost and ensure value for money which requires an innovative advanced technology for predictive maintenance. Predictability, availability and reliability of the engine offers better service for operators, and the need to estimate the expected component failure prior to failure occurrence requires a proactive approach to predict the remaining useful life of components within an assembly.
This research offers a framework for component remaining useful life prediction using assembly level data. The thesis presents a critical analysis on literature identifying the Weibull method, statistical technique and data-driven methodology relating to remaining useful life prediction, which are used in this research. The AS-IS practice captures relevant information based on the investigation conducted in the aerospace industry. The analysis of maintenance cycles relates to the examination of high-level events for engine availability, whereby more communications with industry showcase a through-life performance timeline visualisation. Overhaul sequence and activities are presented to gain insights of the timeline visualisation.
The thesis covers the framework development and application to gas turbine single stage assembly, repair and replacement of components in single stage assembly, and multiple stage assembly. The framework is demonstrated in aerospace engines and power generation engines. The framework developed enables and supports domain experts to quickly respond to, and prepare for maintenance and on-time delivery of spare parts.
The results of the framework show the probability of failure based on a pair of error values using the corresponding Scale and Shape parameters. The probability of failure is transformed into the remaining useful life depicting a typical Weibull distribution. The resulting Weibull curves developed with three scenarios of the case shows there are components renewals, therefore, the remaining useful life of the components are established. The framework is validated and verified through a case study with three scenarios and also through expert judgement
Advanced data-driven methods for prognostics and life extension of assets using condition monitoring and sensor data.
A considerable number of engineering assets are fast reaching and operating beyond their
orignal design lives. This is the case across various industrial sectors, including oil and
gas, wind energy, nuclear energy, etc. Another interesting evolution is the on-going
advancement in cyber-physical systems (CPS), where assets within an industrial plant are
now interconnected. Consequently, conventional ways of progressing engineering assets
beyond their original design lives would need to change. This is the fundamental research
gap that this PhD sets out to address. Due to the complexity of CPS assets, modelling
their failure cannot be simplistically or analytically achieved as was the case with older
assets. This research is a completely novel attempt at using advanced analytics techniques
to address the core aspects of asset life extension (LE). The obvious challenge in a system
with several pieces of disparate equipment under condition monitoring is how to identify
those that need attention and prioritise them. To address this gap, a technique which
combined machine learning algorithms and practices from reliability-centered
maintenance was developed, along with the use of a novel health condition index called
the potential failure interval factor (PFIF). The PFIF was shown to be a good indicator of
asset health states, thus enabling the categorisation of equipment as “healthy”, “good ” or
“soon-to-fail”. LE strategies were then devoted to the vulnerable group labelled “good –
monitor” and “soon-to-fail”. Furthermore, a class of artificial intelligence (AI) algorithms
known as Bayesian Neural Networks (BNNs) were used in predicting the remaining
useful life (RUL) for the vulnerable assets. The novelty in this was the implicit modelling
of the aleatoric and epistemic uncertainties in the RUL prediction, thus yielding
interpretable predictions that were useful for LE decision-making. An advanced analytics
approach to LE decision-making was then proposed, with the novelty of implementing
LE as an on-going series of activities, similar to operation and maintenance (O&M). LE
strategies would therefore be implemented at the system, sub-system or component level,
meshing seamlessly with O&M, albeit with the clear goal of extending the useful life of
the overall asset. The research findings buttress the need for a paradigm shift, from
conventional ways of implementing LE in the form of a project at the end of design life,
to a more systematic approach based on advanced analytics.Shafiee, Mahmood (Associate)PhD in Energy and Powe