Description |
1 online resource (xviii, 251 pages) : illustrations |
Series |
IET Energy Engineering Series ; 190 |
|
IET energy engineering series ; 190.
|
Contents |
Intro -- Title -- Copyright -- Contents -- About the editors -- Introduction -- 1 Synchrophasor data for oscillation source location -- 1.1 Review of OSL methods -- 1.1.1 Traveling wave-based methods -- 1.1.2 Mode shape-based methods -- 1.1.3 Energy-based methods -- 1.1.4 Artificial intelligence-based methods -- 1.1.5 Model inference-based methods -- 1.1.6 Purely data-driven methods -- 1.1.7 Other methods -- 1.1.8 OSL methods for inverter-based resources -- 1.2 Practical considerations for implementing OSL methods -- 1.3 Studies on dissipating energy flow method |
|
1.3.1 A brief introduction of DEF -- 1.3.2 Study of idealized longitudinal power systems -- 1.3.3 Study of multiple cases from IEEE-NASPI OSL contest -- 1.4 Conclusion and future work -- References -- 2 Real-time testing of smart-WAMS for the monitoring of power oscillation -- 2.1 Introduction -- 2.2 State-of-the-art -- 2.3 Brief on smart-WAMS -- 2.4 Executed tests and experiments -- 2.4.1 NSGL Opal-RT computer platform: subtask 1 -- 2.4.2 Non-Opal-RT laptop platform: subtask 2 -- 2.5 Data communication and storage -- 2.6 Results -- 2.6.1 PMU signal from Nordic grid: test case 1 |
|
2.6.2 Simulated signal from IEEE-39 bus system: test case 2 -- 2.6.3 Offline PMU signal from NASPI: test case 3 -- 2.7 Conclusions -- References -- 3 Wide-area control design in different aspects of oscillations -- 3.1 Introduction -- 3.1.1 WAC applications in renewable integrated power system -- 3.1.2 WAC challenges -- 3.2 WAC methodology -- 3.2.1 Resilient WAC design -- 3.2.2 Wide-area-time-delayed system model -- 3.3 Wide-area-predictive-control approach -- 3.3.1 Reordering of data frames and data loss compensation at the PDC -- 3.3.2 Computational method at the predictive controller |
|
3.3.3 Control horizon setting at WAPC -- 3.3.4 Case study -- 3.4 Sub-synchronous oscillation damping in transmission network using synchrophasor technology -- 3.4.1 Challenges of SSO in WF-integrated transmission networks -- 3.4.2 Application of synchrophasor technology for SSO damping in WF-integrated transmission networks -- 3.4.3 Case study -- 3.5 SDC methodology to improve PFR in WF-integrated transmission systems -- 3.5.1 Synchronized P-f droop control of grid-integrated WFs using synchrophasor technology -- 3.5.2 Case study |
|
3.6 Voltage oscillation damping in WF-integrated transmission network using synchrophasor technology -- 3.6.1 Synchronized Q-V droop control of grid-integrated WFs using synchrophasor technology -- 3.6.2 Case study -- 3.7 Conclusions -- References -- 4 Power oscillation damping control for inter-area mode in reduced order model -- 4.1 Introduction -- 4.2 Small signal stability: eigenvalue analysis of NRPG system -- 4.3 Review on residue approach, conventional PSS and compensation associated with PSS design -- 4.3.1 Residue approach for location of PSS -- 4.3.2 Conventional PSS: basics |
Summary |
This work conveys the use of time synchronized measurements of voltages or currents for planning and operation of electricity grids. Such so-called synchrophasors are key to managing complex grids with rising shares of intermittent renewables and varying loads from EV |
Bibliography |
Includes bibliographical references and index |
Notes |
4.3.3 Compensation using PVr characteristics |
|
Online resource; title from online title page (IET Digital Library, viewed on October 31, 2023) |
Subject |
Electric power distribution.
|
|
Synchronization.
|
|
Electric power distribution
|
|
Synchronization
|
Form |
Electronic book
|
Author |
Kishor, Nand, editor.
|
|
Mohanty, Soumya R., editor.
|
ISBN |
1839532858 |
|
9781839532856 |
|