Developing RCM Strategy for Hydrogen Fuel Cells Utilizing On Line E-Condition Monitoring

Fuel cell vehicles are considered to be a viable solution to problems such as carbon emissions and fuel shortages for road transport. Proton Exchange Membrane (PEM) Fuel Cells are mainly used in this purpose because they can run at low temperatures and have a simple structure. Yet high maintenance c...

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Veröffentlicht in:	Journal of physics. Conference series 2012-01, Vol.364 (1), p.12006-11
Hauptverfasser:	Baglee, D, Knowles, M J
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Sprache:	eng
Schlagworte:	Carbon Condition monitoring Critical components Electric vehicles Faults Fuel cells Hydrogen fuels Low temperature Maintenance Maintenance costs Maintenance management Personal digital assistants Physics Proton exchange membrane fuel cells Radio frequency identification RCM Reliability Road transportation State-of-the-art reviews Strategy
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creator	Baglee, D Knowles, M J
description	Fuel cell vehicles are considered to be a viable solution to problems such as carbon emissions and fuel shortages for road transport. Proton Exchange Membrane (PEM) Fuel Cells are mainly used in this purpose because they can run at low temperatures and have a simple structure. Yet high maintenance costs and the inherent dangers of maintaining equipment using hydrogen are two main issues which need to be addressed. The development of appropriate and efficient strategies is currently lacking with regard to fuel cell maintenance. A Reliability Centered Maintenance (RCM) approach offers considerable benefit to the management of fuel cell maintenance since it includes an identification and consideration of the impact of critical components. Technological developments in e-maintenance systems, radio-frequency identification (RFID) and personal digital assistants (PDAs) have proven to satisfy the increasing demand for improved reliability, efficiency and safety. RFID technology is used to store and remotely retrieve electronic maintenance data in order to provide instant access to up-to-date, accurate and detailed information. The aim is to support fuel cell maintenance decisions by developing and applying a blend of leading-edge communications and sensor technology including RFID. The purpose of this paper is to review and present the state of the art in fuel cell condition monitoring and maintenance utilizing RCM and RFID technologies. Using an RCM analysis critical components and fault modes are identified. RFID tags are used to store the critical information, possible faults and their cause and effect. The relationship between causes, faults, symptoms and long term implications of fault conditions are summarized. Finally conclusions are drawn regarding suggested maintenance strategies and the optimal structure for an integrated, cost effective condition monitoring and maintenance management system.
doi_str_mv	10.1088/1742-6596/364/1/012006
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RFID technology is used to store and remotely retrieve electronic maintenance data in order to provide instant access to up-to-date, accurate and detailed information. The aim is to support fuel cell maintenance decisions by developing and applying a blend of leading-edge communications and sensor technology including RFID. The purpose of this paper is to review and present the state of the art in fuel cell condition monitoring and maintenance utilizing RCM and RFID technologies. Using an RCM analysis critical components and fault modes are identified. RFID tags are used to store the critical information, possible faults and their cause and effect. The relationship between causes, faults, symptoms and long term implications of fault conditions are summarized. 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subjects	Carbon Condition monitoring Critical components Electric vehicles Faults Fuel cells Hydrogen fuels Low temperature Maintenance Maintenance costs Maintenance management Personal digital assistants Physics Proton exchange membrane fuel cells Radio frequency identification RCM Reliability Road transportation State-of-the-art reviews Strategy
title	Developing RCM Strategy for Hydrogen Fuel Cells Utilizing On Line E-Condition Monitoring
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