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New Techniques of Reliability and their Application to Offshore Wind Farms. European Offshore Wind 2009, Stockholm Technology and Innovation Offshore Wind Turbine Reliability 16 th September 2009. Introduction - Michael Starling. Background
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New Techniques of Reliability and their Application to Offshore Wind Farms European Offshore Wind 2009, Stockholm Technology and Innovation Offshore Wind Turbine Reliability 16th September 2009
Introduction - Michael Starling Background • Chartered Mechanical Engineer, started work in 1979, worked for BMT since 1990 • worked in Renewable Energy since 2004 • specialise in engineering and risk • applied to transport, energy and the built environment Current/recent projects • construction, transportation and installation system for concrete offshore wind turbine foundations (with Gifford) • reliability, maintainability and survivability guide for the European Marine Energy Centre in Orkney • navigation impact assessment of a tidal fence across the Severn
Introduction - BMT British Ship Research Association NMI Ltd British Maritime Technology Ltd established 1985 (now BMT Group Ltd)
Reliability – Some major projects • Air to Air Refuelling Tanker Aircraft
Reliability – Some major projects • Channel Tunnel Trains
Reliability – Some major projects • Ro Ro Ferries
Reliability – Some major projects • Offshore and Subsea Oil & Gas
Reliability – Personal contact with my work • Aircraft Fuel Pumps – Airport Baggage Handling – Airport Trains – Metros - Escalators
Reliability – A current project • Pulse Tidal Generator
Aircraft achieve high reliability • An A330 will typically achieve greater than 98.5% operational availability • and they guaranteed it from day 1
Fundamental economic driver • A complete common purpose between safety, reliability, performance and profitability
International standards driven • Everything is specification, certification and approvals led
Technical drivers • Complete hierarchy of specification and certification from the smallest component to the whole aircraft and from an individual maintainer to the operator • Approvals are technical, organisational and individual • There is international commonality and transferability
Functional drivers • Aircraft design based on equipment functionality and integrity • and on appropriate redundancy
Appropriate redundancy • Redundancy “enhances high integrity” • It does not “compensate for low integrity”
Formal processes of assurance • Defining what the equipment, operation or service has to do • Designing, operating and maintaining it to do it • Finding some assurance that it will “work and keep on working”
Summary • Aircraft Achieve High Reliability By • Reliable Design • demonstrated by • Reliability Assurance • based on • Integrity, Functionality, Appropriate Redundancy and Comprehensive Testing • mandated by • Specification, Certification and Approval • and controlled through life by • Monitoring and Modification
Three topics for rest of this paper • Design for reliability • Maintain for reliability • Success-based reliability
How reliable does a device have to be? • Common measure of reliability is Mean Time Between Failure (MTBF) • Common belief that a 10 year MTBF means that the equipment will last about 10 years • That is a 10 year life not a 10 year MTBF • After 10 years running approximately 63% of “10 year” MTBF equipment will have failed • For 1% failed the MTBF needs to be approximately 1,000 years • Some MTBFs • Offshore Wind Turbine, 1 month • Domestic Boiler, 5 years – Double Glazing, 10 years
Does redundancy help? • Typical solution to poor reliability is redundancy • Works well for repairable systems • Works badly for non repairable systems • It works better for non-repairable systems when the equipment is reliable • It is often better to spend money on increasing integrity rather than fitting redundancy
Design for reliability - conclusion • Design for high integrity • Backup with redundancy only if easy to repair
What type of maintenance can I do? • Preventive Maintenance • The routine activities to prevent failure, i.e. the servicing • Typically done to a planned schedule based on time or usage • Ideal is to do when no wind resource available Corrective Maintenance • The activities required to respond to failure, i.e. the repairs • Typically done to a reactive schedule • Ideal is to avoid • Predictive Maintenance • The activities required to respond to an indicator of future failure, i.e. maintenance triggered by some measurement of condition • Ideal is to be able to defer predictive maintenance to times when preventive maintenance takes place
Classical “Bathtub” • Wear-out • Degradation • Initial Success • Steady • Early Life Failure What type of maintenance should I do? • Depends on the nature of the failure
Classical “Bathtub” • Bit worse • Made better • Wear-out • Bit better • Degradation • Initial Success • Bit better • No difference • Steady • Made worse • Early Life Failure Effect of time scheduled maintenance
Classical “Bathtub” • Bit worse 4% • Made better 2% • Wear-out 5% • Bit better • Degradation 7% • Initial Success • Bit better • No difference 14% • Steady 68% • Made worse • Early Life Failure Example using of aircraft data
Maintain for reliability - conclusion • Define maintenance based on understanding the types of failure
A bit of history • These success-based techniques grew out of failure • failure of reliability techniques to lead to change • failure of techniques to improve reliability • failure of techniques to be value for money Led to questioning the fundamental reliability techniques • techniques are focussed on failure • should they be focussed on success?
Focus on success • For many years those of us in reliability have concentrated on understanding and eliminating failure. • why things fails, when they fail, where they fail and how to stop them failing are questions that are examined in great detail. • However in doing so we may have overlooked the equal importance of understanding and creating success. • why things work, when they work, where they work and how to make them work are equally, or perhaps more important, questions.
How to achieve success? – via assurance • to define what the equipment, operation or service has to do • to design it and operate it to do it • find some evidence that it will work and keep on working. • identify and eliminate threats to success.
Assurance via developing a reliability case • Part Technical Process • that aims to provide the “Evidence of Success” and • identify and eliminate the “Risk of Failure” • and produce a “Reasoned Argument” supporting expected performance • Part Management Process • that aims to provide “Scrutiny” that the evidence and argument is valid
Assessing the quality of the evidence • Proof? Evidence? Faith?
Producing a reasoned argument • The reasoned argument leads to • a claim of expected reliability performance • an assessment of the level of risk associated with the claim There is an obligation to use all evidence, the supporting and the opposing
This philosophy is not new • Rene Descartes • 1596 - 1650 • Knowledge should be based on • “Proof and evidence rather than just faith” • and • “Nothing should be accepted unless subject to scrutiny”
And finally • Some advice on how to achieve high reliability • Specify the reliability you want • and specify it in terms meaningful to your business • Design to achieve it • but beware the false promise of redundancy • Build up a Reliability Case • and expose it to scrutiny (and don’t always believe your experts!) • Maintain for reliability • base your maintenance on understanding failure
Discussion Michael Starling BMT Fleet Technology www.fleetech.com mstarling@fleetech.com +44(0)780 3925110