| Description |
1 online resource (313 p.) |
| Series |
Energy Engineering Series |
|
Energy Engineering Series
|
| Contents |
Intro -- Title -- Copyright -- Contents -- About the editor -- Introduction -- 1 Tidal stream turbine generator and drivetrain design options -- 1.1 Possible TST drivetrain options -- 1.1.1 Behavior of a tidal turbine in terms of torque/speed -- 1.1.2 Drivetrain options and generator configurations -- 1.1.3 Power harnessing general strategy -- 1.1.4 Turbine control options -- 1.2 TST generator design -- 1.2.1 Design criteria -- 1.2.2 Possible generator type depending of the drivetrain options -- 1.2.3 Generator and drive flux weakening specifications for fixed pitch turbine |
|
1.2.4 Focus on direct-drive PM generators dedicated to TST -- 1.3 Summary and conclusion -- References -- 2 Tidal stream turbine control -- 2.1 Overview of control system -- 2.1.1 PID control -- 2.1.2 Sliding mode control -- 2.2 Mathematical modelling -- 2.2.1 Tidal resource model -- 2.2.2 Tidal turbine model -- 2.2.3 Modeling of the generator -- 2.2.4 Modeling of DFIG -- 2.2.5 Modeling of PMSG -- 2.3 Controller development for TST -- 2.3.1 HOSMC for DFIG-based TST -- 2.3.2 HOSMC for PMSG-based TST -- 2.3.3 HOSMC for DSPMG-based TST -- 2.4 Conclusion -- References |
|
3 Tidal stream turbine fault-tolerant control -- 3.1 Introduction -- 3.2 Fundamentals on faults resilience -- 3.2.1 Basic concepts on fault tolerance -- 3.2.2 Marine current turbines failures -- 3.2.3 Diagnosis and fault tolerance property -- 3.3 Fault-tolerant systems at design stage -- 3.3.1 Redundancy -- 3.3.2 Intrinsic resilient systems -- 3.4 Fault-tolerant control -- 3.4.1 Active fault-tolerant control system -- 3.4.2 Passive fault-tolerant control system -- 3.4.3 Hybrid fault-tolerant control system -- 3.5 Tidal stream turbines magnets fault-tolerant control case study |
|
3.5.1 Tidal turbine overview -- 3.5.2 Magnetic equivalent circuit model for magnets failure modeling -- 3.5.3 Sliding mode-based magnet failure-resilient control -- 3.5.4 Simulation results -- 3.6 Tidal stream turbines sensors fault-tolerant control case study -- 3.6.1 Flow-meter FTC -- 3.6.2 Rotor speed/position sensor FTC -- 3.6.3 Comparison criteria -- 3.6.4 Main simulation results -- 3.7 Conclusions and perspectives -- References -- 4 Tidal stream turbine monitoring and fault diagnosis -- 4.1 Introduction -- 4.1.1 Tidal stream turbine challenges |
|
4.2 Condition monitoring and fault diagnosis in TST -- 4.2.1 Failure modes -- 4.2.2 Condition monitoring -- 4.3 Fault detection and diagnosis in TST -- 4.4 Tidal stream turbine faults -- 4.4.1 Impact of imbalance fault -- 4.4.2 Current signal model -- 4.4.3 MSCA-based imbalance fault detection -- 4.4.4 Image processing-based imbalance fault detection -- 4.5 Summary and conclusion -- References -- 5 Biofouling issue in tidal stream turbines -- 5.1 Introduction -- 5.2 Biofouling development -- 5.2.1 Characterization -- 5.2.2 Development -- 5.3 Biofouling characterization and estimation |
| Summary |
An authoritative overview of the technology for tidal energy generation as reliable clean power source, this book presents the principles, conversion drivetrain design options, control, resilience and fault-tolerant control, monitoring as well as the specific issue of biofouling |
| Notes |
Description based upon print version of record |
|
5.3.1 Some hydrodynamic aspects to understand the effect of biofouling on tidal turbines power |
| Form |
Electronic book
|
| ISBN |
9781839534218 |
|
1839534214 |
|
