Verfügbarkeit: Hydrodynamic control of wave energy devices /

Hydrodynamic control of wave energy devices /:

For researchers and practitioners, an accessible and integrated treatment of hydrodynamic control of wave energy devices.

Gespeichert in:

Bibliographische Detailangaben
1. Verfasser:	Korde, Umesh A.
Weitere Verfasser:	Ringwood, John V.
Format:	Elektronisch E-Book
Sprache:	English
Veröffentlicht:	Cambridge : Cambridge University Press, [2016]
Schlagworte:	Ocean wave power > Research. Hydraulic engineering > Research. Energy conversion > Research. Tidal power-plants > Research. Wave resistance (Hydrodynamics) > Research. Water-power > Research. Renewable energy sources > Research. Énergie des vagues > Recherche. Énergie > Conversion > Recherche. Usines marémotrices > Recherche. Résistance de vagues > Recherche. Énergies renouvelables > Recherche. TECHNOLOGY & ENGINEERING > Mechanical. Hydraulic engineering > Research Renewable energy sources > Research
Online-Zugang:	Volltext
Zusammenfassung:	For researchers and practitioners, an accessible and integrated treatment of hydrodynamic control of wave energy devices.
Beschreibung:	1 online resource
Bibliographie:	Includes bibliographical references and index.
ISBN:	9781139942072 1139942077 9781316726044 1316726045 9781316724248 1316724247

Internformat

MARC


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245	1	0	\|a Hydrodynamic control of wave energy devices / \|c Umesh A. Korde, South Dakota School of Mines and Technology, John V. Ringwood, Maynooth University.
264		1	\|a Cambridge : \|b Cambridge University Press, \|c [2016]
300			\|a 1 online resource
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504			\|a Includes bibliographical references and index.
505	0		\|a Cover; Half-title; Title page; Copyright information; Table of contents; Preface; Acknowledgments; Part I Introduction; 1 Wave Energy Conversion; 1.1 Waves as Energy Carriers; 1.2 Nature of Wave Motion; 1.3 Regular versus Irregular Waves; 1.4 Wave Energy; 1.5 Primary Energy Conversion; 1.6 Secondary Energy Conversion; 1.7 Tail-Tube or Pneumatic Buoy; 1.8 Edinburgh Duck; 1.9 Contouring Rafts; 1.10 Submerged Cylinder; 1.11 Flexible Bag-Type Devices; 1.12 Omnidirectional Buoys; 1.13 Attenuator and Terminator Oscillating Water Column Devices; 1.14 Other Recent Sea-Tested Devices.
505	8		\|a 1.15 Need for Control1.16 Conclusion; 1.17 Commonly Used Wave Energy Terminology; Part II The Basics; 2 Introduction to Control Engineering; 2.1 Techniques and Terminology; 2.2 Benefits and Pitfalls of Feedback; 2.3 Control Design; 2.4 State Space Modeling; 2.5 Challenges for Wave Energy Conversion; 2.6 Control of Wave Energy Devices; 2.7 Conclusion; 3 Bodies Oscillating in Air; 3.1 Power Absorption from an Oscillatory Force; 3.2 Control for Maximum Power Absorption; 3.3 Irregular Forcing; 3.4 Conclusion; 4 Bodies Oscillating in Water; 4.1 Oscillation Near Free Surface; 4.2 Regular Waves.
505	8		\|a 4.3 Irregular Waves4.4 Conclusion; Part III The Hydrodynamics; 5 Nature of the Wave Input; 5.1 Description of a Harmonic Wave; 5.2 Description of Irregular Waves; 5.2.1 Probability Density Functions; 5.2.2 Stationarity and Ergodicity; 5.2.3 Power Spectral Density; 5.3 Group Behavior of Waves; 5.4 Wave Power as Rate of Energy Propagation; 5.5 Device Response in Irregular Waves; 5.6 Conclusion; 6 A Closer Look at Wave Energy Hydrodynamics; 6.1 A Body in Waves; 6.2 Beam-Sea Devices; 6.3 Producing Optimum Velocity; 6.4 Calculating the Average Absorbed Power; 6.5 Favorable Mode Combinations.
505	8		\|a 6.5.1 Non orbital Motion of Body Centroid6.5.2 Orbital Motion of Body Centroid; 6.6 Omni directional Devices; 6.7 Head-Sea Devices; 6.8 Energy Absorption under Displacement/Velocity Constraints; 6.9 Oscillating Water Column Devices; 6.10 Device Arrays; 6.11 Conclusion; Part IV Velocity Control Using a Hydrodynamic Model; 7 Reactive Control in Time Domain; 7.1 Approaching the Hydrodynamic Optimum; 7.2 Control Force Synthesis; 7.2.1 Right-Shifting of Impulse Response Functions; 7.2.2 Wave Propagation and Future Information; 7.2.3 Approximate Evaluation of Control Force.
505	8		\|a 7.3 Wave Prediction from Up-Wave Measurement Time History7.3.1 Propagation Impulse Response Function; 7.3.2 Up Wave Distance and Duration of Measurement; 7.4 Conclusion; 8 A Causal Real-Time Controller for Wave Energy Converters; 8.1 Introduction; 8.1.1 Model Definition; 8.1.2 Model Identification; 8.2 Real-Time Controller; 8.2.1 Maximum Wave Energy Extraction; 8.2.2 A Simple and Effective Realization of Reactive Control; 8.2.3 Constraint Handling; 8.2.4 Velocity-Tracking Control Loop; 8.3 Results; 8.3.1 Wave Data; 8.3.2 Performance in the Unconstrained Case; 8.3.3 Introduction of Constraints.
520			\|a For researchers and practitioners, an accessible and integrated treatment of hydrodynamic control of wave energy devices.
650		0	\|a Ocean wave power \|x Research.
650		0	\|a Hydraulic engineering \|x Research. \|0 http://id.loc.gov/authorities/subjects/sh85063309
650		0	\|a Energy conversion \|x Research.
650		0	\|a Tidal power-plants \|x Research.
650		0	\|a Wave resistance (Hydrodynamics) \|x Research.
650		0	\|a Water-power \|x Research.
650		0	\|a Renewable energy sources \|x Research.
650		6	\|a Énergie des vagues \|x Recherche.
650		6	\|a Énergie \|x Conversion \|x Recherche.
650		6	\|a Usines marémotrices \|x Recherche.
650		6	\|a Résistance de vagues \|x Recherche.
650		6	\|a Énergies renouvelables \|x Recherche.
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650		7	\|a Hydraulic engineering \|x Research \|2 fast
650		7	\|a Renewable energy sources \|x Research \|2 fast
700	1		\|a Ringwood, John V.
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Datensatz im Suchindex

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contents	Cover; Half-title; Title page; Copyright information; Table of contents; Preface; Acknowledgments; Part I Introduction; 1 Wave Energy Conversion; 1.1 Waves as Energy Carriers; 1.2 Nature of Wave Motion; 1.3 Regular versus Irregular Waves; 1.4 Wave Energy; 1.5 Primary Energy Conversion; 1.6 Secondary Energy Conversion; 1.7 Tail-Tube or Pneumatic Buoy; 1.8 Edinburgh Duck; 1.9 Contouring Rafts; 1.10 Submerged Cylinder; 1.11 Flexible Bag-Type Devices; 1.12 Omnidirectional Buoys; 1.13 Attenuator and Terminator Oscillating Water Column Devices; 1.14 Other Recent Sea-Tested Devices. 1.15 Need for Control1.16 Conclusion; 1.17 Commonly Used Wave Energy Terminology; Part II The Basics; 2 Introduction to Control Engineering; 2.1 Techniques and Terminology; 2.2 Benefits and Pitfalls of Feedback; 2.3 Control Design; 2.4 State Space Modeling; 2.5 Challenges for Wave Energy Conversion; 2.6 Control of Wave Energy Devices; 2.7 Conclusion; 3 Bodies Oscillating in Air; 3.1 Power Absorption from an Oscillatory Force; 3.2 Control for Maximum Power Absorption; 3.3 Irregular Forcing; 3.4 Conclusion; 4 Bodies Oscillating in Water; 4.1 Oscillation Near Free Surface; 4.2 Regular Waves. 4.3 Irregular Waves4.4 Conclusion; Part III The Hydrodynamics; 5 Nature of the Wave Input; 5.1 Description of a Harmonic Wave; 5.2 Description of Irregular Waves; 5.2.1 Probability Density Functions; 5.2.2 Stationarity and Ergodicity; 5.2.3 Power Spectral Density; 5.3 Group Behavior of Waves; 5.4 Wave Power as Rate of Energy Propagation; 5.5 Device Response in Irregular Waves; 5.6 Conclusion; 6 A Closer Look at Wave Energy Hydrodynamics; 6.1 A Body in Waves; 6.2 Beam-Sea Devices; 6.3 Producing Optimum Velocity; 6.4 Calculating the Average Absorbed Power; 6.5 Favorable Mode Combinations. 6.5.1 Non orbital Motion of Body Centroid6.5.2 Orbital Motion of Body Centroid; 6.6 Omni directional Devices; 6.7 Head-Sea Devices; 6.8 Energy Absorption under Displacement/Velocity Constraints; 6.9 Oscillating Water Column Devices; 6.10 Device Arrays; 6.11 Conclusion; Part IV Velocity Control Using a Hydrodynamic Model; 7 Reactive Control in Time Domain; 7.1 Approaching the Hydrodynamic Optimum; 7.2 Control Force Synthesis; 7.2.1 Right-Shifting of Impulse Response Functions; 7.2.2 Wave Propagation and Future Information; 7.2.3 Approximate Evaluation of Control Force. 7.3 Wave Prediction from Up-Wave Measurement Time History7.3.1 Propagation Impulse Response Function; 7.3.2 Up Wave Distance and Duration of Measurement; 7.4 Conclusion; 8 A Causal Real-Time Controller for Wave Energy Converters; 8.1 Introduction; 8.1.1 Model Definition; 8.1.2 Model Identification; 8.2 Real-Time Controller; 8.2.1 Maximum Wave Energy Extraction; 8.2.2 A Simple and Effective Realization of Reactive Control; 8.2.3 Constraint Handling; 8.2.4 Velocity-Tracking Control Loop; 8.3 Results; 8.3.1 Wave Data; 8.3.2 Performance in the Unconstrained Case; 8.3.3 Introduction of Constraints.
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id	ZDB-4-EBA-ocn958357272
illustrated	Not Illustrated
indexdate	2024-11-27T13:27:23Z
institution	BVB
isbn	9781139942072 1139942077 9781316726044 1316726045 9781316724248 1316724247
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publisher	Cambridge University Press,
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spelling	Korde, Umesh A. Hydrodynamic control of wave energy devices / Umesh A. Korde, South Dakota School of Mines and Technology, John V. Ringwood, Maynooth University. Cambridge : Cambridge University Press, [2016] 1 online resource text txt rdacontent computer c rdamedia online resource cr rdacarrier Includes bibliographical references and index. Cover; Half-title; Title page; Copyright information; Table of contents; Preface; Acknowledgments; Part I Introduction; 1 Wave Energy Conversion; 1.1 Waves as Energy Carriers; 1.2 Nature of Wave Motion; 1.3 Regular versus Irregular Waves; 1.4 Wave Energy; 1.5 Primary Energy Conversion; 1.6 Secondary Energy Conversion; 1.7 Tail-Tube or Pneumatic Buoy; 1.8 Edinburgh Duck; 1.9 Contouring Rafts; 1.10 Submerged Cylinder; 1.11 Flexible Bag-Type Devices; 1.12 Omnidirectional Buoys; 1.13 Attenuator and Terminator Oscillating Water Column Devices; 1.14 Other Recent Sea-Tested Devices. 1.15 Need for Control1.16 Conclusion; 1.17 Commonly Used Wave Energy Terminology; Part II The Basics; 2 Introduction to Control Engineering; 2.1 Techniques and Terminology; 2.2 Benefits and Pitfalls of Feedback; 2.3 Control Design; 2.4 State Space Modeling; 2.5 Challenges for Wave Energy Conversion; 2.6 Control of Wave Energy Devices; 2.7 Conclusion; 3 Bodies Oscillating in Air; 3.1 Power Absorption from an Oscillatory Force; 3.2 Control for Maximum Power Absorption; 3.3 Irregular Forcing; 3.4 Conclusion; 4 Bodies Oscillating in Water; 4.1 Oscillation Near Free Surface; 4.2 Regular Waves. 4.3 Irregular Waves4.4 Conclusion; Part III The Hydrodynamics; 5 Nature of the Wave Input; 5.1 Description of a Harmonic Wave; 5.2 Description of Irregular Waves; 5.2.1 Probability Density Functions; 5.2.2 Stationarity and Ergodicity; 5.2.3 Power Spectral Density; 5.3 Group Behavior of Waves; 5.4 Wave Power as Rate of Energy Propagation; 5.5 Device Response in Irregular Waves; 5.6 Conclusion; 6 A Closer Look at Wave Energy Hydrodynamics; 6.1 A Body in Waves; 6.2 Beam-Sea Devices; 6.3 Producing Optimum Velocity; 6.4 Calculating the Average Absorbed Power; 6.5 Favorable Mode Combinations. 6.5.1 Non orbital Motion of Body Centroid6.5.2 Orbital Motion of Body Centroid; 6.6 Omni directional Devices; 6.7 Head-Sea Devices; 6.8 Energy Absorption under Displacement/Velocity Constraints; 6.9 Oscillating Water Column Devices; 6.10 Device Arrays; 6.11 Conclusion; Part IV Velocity Control Using a Hydrodynamic Model; 7 Reactive Control in Time Domain; 7.1 Approaching the Hydrodynamic Optimum; 7.2 Control Force Synthesis; 7.2.1 Right-Shifting of Impulse Response Functions; 7.2.2 Wave Propagation and Future Information; 7.2.3 Approximate Evaluation of Control Force. 7.3 Wave Prediction from Up-Wave Measurement Time History7.3.1 Propagation Impulse Response Function; 7.3.2 Up Wave Distance and Duration of Measurement; 7.4 Conclusion; 8 A Causal Real-Time Controller for Wave Energy Converters; 8.1 Introduction; 8.1.1 Model Definition; 8.1.2 Model Identification; 8.2 Real-Time Controller; 8.2.1 Maximum Wave Energy Extraction; 8.2.2 A Simple and Effective Realization of Reactive Control; 8.2.3 Constraint Handling; 8.2.4 Velocity-Tracking Control Loop; 8.3 Results; 8.3.1 Wave Data; 8.3.2 Performance in the Unconstrained Case; 8.3.3 Introduction of Constraints. For researchers and practitioners, an accessible and integrated treatment of hydrodynamic control of wave energy devices. Ocean wave power Research. Hydraulic engineering Research. http://id.loc.gov/authorities/subjects/sh85063309 Energy conversion Research. Tidal power-plants Research. Wave resistance (Hydrodynamics) Research. Water-power Research. Renewable energy sources Research. Énergie des vagues Recherche. Énergie Conversion Recherche. Usines marémotrices Recherche. Résistance de vagues Recherche. Énergies renouvelables Recherche. TECHNOLOGY & ENGINEERING Mechanical. bisacsh Hydraulic engineering Research fast Renewable energy sources Research fast Ringwood, John V. Print version: 9781107079700 1107079705 (DLC) 2016011206 (OCoLC)945549957 FWS01 ZDB-4-EBA FWS_PDA_EBA https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=1343231 Volltext
spellingShingle	Korde, Umesh A. Hydrodynamic control of wave energy devices / Cover; Half-title; Title page; Copyright information; Table of contents; Preface; Acknowledgments; Part I Introduction; 1 Wave Energy Conversion; 1.1 Waves as Energy Carriers; 1.2 Nature of Wave Motion; 1.3 Regular versus Irregular Waves; 1.4 Wave Energy; 1.5 Primary Energy Conversion; 1.6 Secondary Energy Conversion; 1.7 Tail-Tube or Pneumatic Buoy; 1.8 Edinburgh Duck; 1.9 Contouring Rafts; 1.10 Submerged Cylinder; 1.11 Flexible Bag-Type Devices; 1.12 Omnidirectional Buoys; 1.13 Attenuator and Terminator Oscillating Water Column Devices; 1.14 Other Recent Sea-Tested Devices. 1.15 Need for Control1.16 Conclusion; 1.17 Commonly Used Wave Energy Terminology; Part II The Basics; 2 Introduction to Control Engineering; 2.1 Techniques and Terminology; 2.2 Benefits and Pitfalls of Feedback; 2.3 Control Design; 2.4 State Space Modeling; 2.5 Challenges for Wave Energy Conversion; 2.6 Control of Wave Energy Devices; 2.7 Conclusion; 3 Bodies Oscillating in Air; 3.1 Power Absorption from an Oscillatory Force; 3.2 Control for Maximum Power Absorption; 3.3 Irregular Forcing; 3.4 Conclusion; 4 Bodies Oscillating in Water; 4.1 Oscillation Near Free Surface; 4.2 Regular Waves. 4.3 Irregular Waves4.4 Conclusion; Part III The Hydrodynamics; 5 Nature of the Wave Input; 5.1 Description of a Harmonic Wave; 5.2 Description of Irregular Waves; 5.2.1 Probability Density Functions; 5.2.2 Stationarity and Ergodicity; 5.2.3 Power Spectral Density; 5.3 Group Behavior of Waves; 5.4 Wave Power as Rate of Energy Propagation; 5.5 Device Response in Irregular Waves; 5.6 Conclusion; 6 A Closer Look at Wave Energy Hydrodynamics; 6.1 A Body in Waves; 6.2 Beam-Sea Devices; 6.3 Producing Optimum Velocity; 6.4 Calculating the Average Absorbed Power; 6.5 Favorable Mode Combinations. 6.5.1 Non orbital Motion of Body Centroid6.5.2 Orbital Motion of Body Centroid; 6.6 Omni directional Devices; 6.7 Head-Sea Devices; 6.8 Energy Absorption under Displacement/Velocity Constraints; 6.9 Oscillating Water Column Devices; 6.10 Device Arrays; 6.11 Conclusion; Part IV Velocity Control Using a Hydrodynamic Model; 7 Reactive Control in Time Domain; 7.1 Approaching the Hydrodynamic Optimum; 7.2 Control Force Synthesis; 7.2.1 Right-Shifting of Impulse Response Functions; 7.2.2 Wave Propagation and Future Information; 7.2.3 Approximate Evaluation of Control Force. 7.3 Wave Prediction from Up-Wave Measurement Time History7.3.1 Propagation Impulse Response Function; 7.3.2 Up Wave Distance and Duration of Measurement; 7.4 Conclusion; 8 A Causal Real-Time Controller for Wave Energy Converters; 8.1 Introduction; 8.1.1 Model Definition; 8.1.2 Model Identification; 8.2 Real-Time Controller; 8.2.1 Maximum Wave Energy Extraction; 8.2.2 A Simple and Effective Realization of Reactive Control; 8.2.3 Constraint Handling; 8.2.4 Velocity-Tracking Control Loop; 8.3 Results; 8.3.1 Wave Data; 8.3.2 Performance in the Unconstrained Case; 8.3.3 Introduction of Constraints. Ocean wave power Research. Hydraulic engineering Research. http://id.loc.gov/authorities/subjects/sh85063309 Energy conversion Research. Tidal power-plants Research. Wave resistance (Hydrodynamics) Research. Water-power Research. Renewable energy sources Research. Énergie des vagues Recherche. Énergie Conversion Recherche. Usines marémotrices Recherche. Résistance de vagues Recherche. Énergies renouvelables Recherche. TECHNOLOGY & ENGINEERING Mechanical. bisacsh Hydraulic engineering Research fast Renewable energy sources Research fast
subject_GND	http://id.loc.gov/authorities/subjects/sh85063309
title	Hydrodynamic control of wave energy devices /
title_auth	Hydrodynamic control of wave energy devices /
title_exact_search	Hydrodynamic control of wave energy devices /
title_full	Hydrodynamic control of wave energy devices / Umesh A. Korde, South Dakota School of Mines and Technology, John V. Ringwood, Maynooth University.
title_fullStr	Hydrodynamic control of wave energy devices / Umesh A. Korde, South Dakota School of Mines and Technology, John V. Ringwood, Maynooth University.
title_full_unstemmed	Hydrodynamic control of wave energy devices / Umesh A. Korde, South Dakota School of Mines and Technology, John V. Ringwood, Maynooth University.
title_short	Hydrodynamic control of wave energy devices /
title_sort	hydrodynamic control of wave energy devices
topic	Ocean wave power Research. Hydraulic engineering Research. http://id.loc.gov/authorities/subjects/sh85063309 Energy conversion Research. Tidal power-plants Research. Wave resistance (Hydrodynamics) Research. Water-power Research. Renewable energy sources Research. Énergie des vagues Recherche. Énergie Conversion Recherche. Usines marémotrices Recherche. Résistance de vagues Recherche. Énergies renouvelables Recherche. TECHNOLOGY & ENGINEERING Mechanical. bisacsh Hydraulic engineering Research fast Renewable energy sources Research fast
topic_facet	Ocean wave power Research. Hydraulic engineering Research. Energy conversion Research. Tidal power-plants Research. Wave resistance (Hydrodynamics) Research. Water-power Research. Renewable energy sources Research. Énergie des vagues Recherche. Énergie Conversion Recherche. Usines marémotrices Recherche. Résistance de vagues Recherche. Énergies renouvelables Recherche. TECHNOLOGY & ENGINEERING Mechanical. Hydraulic engineering Research Renewable energy sources Research
url	https://search.ebscohost.com/login.aspx?direct=true&scope=site&db=nlebk&AN=1343231
work_keys_str_mv	AT kordeumesha hydrodynamiccontrolofwaveenergydevices AT ringwoodjohnv hydrodynamiccontrolofwaveenergydevices

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