AI-Driven Maintenance Support for Downhole Tools and Electronics Operated in Dynamic Drilling Environments

Kirschbaum, Lucas; Roman, Darius; Singh, Gurkirat; Bruns, Jens; Robu, Valentin; Flynn, David

doi:10.1109/access.2020.2990152

Cited by 27 publications

(15 citation statements)

References 79 publications

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“…This way, the digital twin concept bridges monitoring and modelling and eventually allows the use of data analytics and artificial intelligence-based prediction techniques to make real-time predictions of future behaviour and reliability. Examples of the combined use of artificial intelligence-based models and digital twins in offshore industry can be found in the works of Ellefsen et al (2019) ; Shirangi et al (2020) ; Tygesen et al (2019) ; Augustyn et al (2019) , and Kirschbaum et al (2020) . Additional examples implemented in other fields, such as manufacturing industries are provided by Cronrath et al (2019) ; Min et al (2019) , and Jaensch et al (2018) .…”

Section: Reliability Analysis Of the Integrated Systemmentioning

confidence: 99%

Reliability of multi-purpose offshore-facilities: Present status and future direction in Australia

Aryai

Abdussamie

Salehi

et al. 2021

Process Safety and Environmental Protection

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Sustainable use of the ocean for food and energy production is an emerging area of research in different countries around the world. This goal is pursued by the Australian aquaculture, offshore engineering and renewable energy industries, research organisations and the government through the “Blue Economy Cooperative Research Centre”. To address the challenges of offshore food and energy production, leveraging the benefits of co-location, vertical integration, infrastructure and shared services, will be enabled through the development of novel Multi-Purpose Offshore-Platforms (MPOP). The structural integrity of the designed systems when being deployed in the harsh offshore environment is one of the main challenges in developing the MPOPs. Employing structural reliability analysis methods for assessing the structural safety of the novel aquaculture-MPOPs comes with different limitations. This review aims at shedding light on these limitations and discusses the current status and future directions for structural reliability analysis of a novel aquaculture-MPOP considering Australia’s unique environment. To achieve this aim, challenges which exist at different stages of reliability assessment, from data collection and uncertainty quantification to load and structural modelling and reliability analysis implementation, are discussed. Furthermore, several solutions to these challenges are proposed based on the existing knowledge in other sectors, and particularly from the offshore oil and gas industry. Based on the identified gaps in the review process, potential areas for future research are introduced to enable a safer and more reliable operation of the MPOPs.

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Section: Reliability Analysis Of the Integrated Systemmentioning

confidence: 99%

Reliability of multi-purpose offshore-facilities: Present status and future direction in Australia

Aryai

Abdussamie

Salehi

et al. 2021

Process Safety and Environmental Protection

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show abstract

“…This can include degradation models or damage accumulation models based on failure modes mechanism, such as wear, fatigue, corrosion, and contamination [14]. On the other hand, the data-driven prognostics approach is an application of machine learning and statistical pattern recognition on data collected at system, subsystem or component level [32,36]. In practice, a prognostics architecture can rely on an individual method or a combination of the three.…”

Section: Prognostics and Health Managementmentioning

confidence: 99%

Prognostics and Health Management for the Optimization of Marine Hybrid Energy Systems

et al. 2020

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Decarbonization of marine transport is a key global issue, with the carbon emissions of international shipping projected to increase 23% to 1090 million tonnes by 2035 in comparison to 2015 levels. Optimization of the energy system (especially propulsion system) in these vessels is a complex multi-objective challenge involving economical maintenance, environmental metrics, and energy demand requirements. In this paper, data from instrumented vessels on the River Thames in London, which includes environmental emissions, power demands, journey patterns, and variance in operational patterns from the captain(s) and loading (passenger numbers), is integrated and analyzed through automatic, multi-objective global optimization to create an optimal hybrid propulsion configuration for a hybrid vessel. We propose and analyze a number of computational techniques, both for monitoring and remaining useful lifetime (RUL) estimation of individual energy assets, as well as modeling and optimization of energy use scenarios of a hybrid-powered vessel. Our multi-objective optimization relates to emissions, asset health, and power performance. We show that, irrespective of the battery packs used, our Relevance Vector Machine (RVM) algorithm is able to achieve over 92% accuracy in remaining useful life (RUL) predictions. A k-nearest neighbors algorithm (KNN) is proposed for prognostics of state of charge (SOC) of back-up lead-acid batteries. The classifier achieved an average of 95.5% accuracy in a three-fold cross validation. Utilizing operational data from the vessel, optimal autonomous propulsion strategies are modeled combining the use of battery and diesel engines. The experiment results show that 70% to 80% of fuel saving can be achieved when the diesel engine is operated up to 350 kW. Our methodology has demonstrated the feasibility of combination of artificial intelligence (AI) methods and real world data in decarbonization and optimization of green technologies for maritime propulsion.

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“…Artificial intelligence (AI) and robotics continue to grow and influence all aspects of industry and society, with the global market impact of robotics estimated to contribute up to 14% of global GDP by 2030, equivalent to around $15 trillion at today's values [1]. Countries around the world are moving to exploit this emergent industry in order to improve productivity within existing market operations, e.g., oil and gas [2], offshore wind [3], manufacturing, agriculture, etc., and to capture revenue from high growth disruptive services within those sectors, such as robotic inspections using aerial [4] and subsea platforms [5], autonomous logistics etc. The future operation and maintenance of offshore wind farms outlines a transition from semi to persistent autonomy to reduce costs, improve productivity and to remove humans from dangerous deployment [6,7].…”

Section: Introductionmentioning

confidence: 99%

Reliability and Safety of Autonomous Systems Based on Semantic Modelling for Self-Certification

et al. 2021

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A novel modelling paradigm for online diagnostics and prognostics for autonomous systems is presented. A model for the autonomous system being diagnosed is designed using a logic-based formalism. The model supports the run-time ability to verify that the autonomous system is safe and reliable for operation within a dynamic environment. The paradigm is based on the philosophy that there are different types of semantic relationships between the states of different parts of the system. A finite state automaton is devised for each sensed component and some of the non-sensed components. To capture the interdependencies of components within such a complex robotic platform, automatons were related to each other by semantic relationships. Modality was utilised by the formalism to abstract the relationships and to add measures for the possibility and uncertainty of the relationships. The complexity of the model was analysed to evaluate its scalability and applicability to other systems. The results demonstrate that the complexity is not linear and a computational time of 10 ms was required to achieve run-time diagnostics for 2200 KB of knowledge for complex system interdependences. The ability to detect and mitigate hardware related failures was demonstrated within a confined space autonomous operation. Our findings provide evidence of the applicability of our approach for the significant challenge of run-time safety compliance and reliability in autonomous systems.

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AI-Driven Maintenance Support for Downhole Tools and Electronics Operated in Dynamic Drilling Environments

Cited by 27 publications

References 79 publications

Reliability of multi-purpose offshore-facilities: Present status and future direction in Australia

Reliability of multi-purpose offshore-facilities: Present status and future direction in Australia

Prognostics and Health Management for the Optimization of Marine Hybrid Energy Systems

Reliability and Safety of Autonomous Systems Based on Semantic Modelling for Self-Certification

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