Advanced Control of AC / DC Power Networks System of Systems Approach Based on Spatio-temporal Scales

The power engineering domain is facing huge challenges, with an increasing interest in intermittent renewable energies which are imposing major technical limitations. Operating ever closer to their limits, the industry-standard AC power grids are subject to instabilities. This book presents an insig...

Full description

Saved in:
Bibliographic Details
Main Author Benchaib, Abdelkrim
Format eBook
LanguageEnglish
Published Newark Wiley 2015
John Wiley & Sons, Incorporated
Wiley-Blackwell
Edition1
Subjects
Control
Electric power systems
Load dispatching
Mathematical models
SCIENCE
Smart power grids
Online AccessGet full text
ISBN111913577X
9781119135777
9781848218024
1848218028

Cover

Abstract The power engineering domain is facing huge challenges, with an increasing interest in intermittent renewable energies which are imposing major technical limitations. Operating ever closer to their limits, the industry-standard AC power grids are subject to instabilities. This book presents an insight into DC grid systems, offering interesting issues to well controlled power grids, in contrast to current AC systems which provide the simplest and most economic connection method for short distances.
AbstractList The concept of Multi-Terminal DC grids (MTDC), where DC cables connect more than two AC/DC converter  stations  is  nowadays  spreading  driven  by  different  criteria,  all  necessaries  for  large-capacity RES grid integration, such as larger flexibility of grid operation, possibility of reversible power flows, increased redundancy, and reduction of maximum power loss in case of a grid disturbance.
The power engineering domain is facing huge challenges, with an increasing interest in intermittent renewable energies which are imposing major technical limitations. Operating ever closer to their limits, the industry-standard AC power grids are subject to instabilities. This book presents an insight into DC grid systems, offering interesting issues to well controlled power grids, in contrast to current AC systems which provide the simplest and most economic connection method for short distances.
The power engineering domain is facing huge challenges, with an increasing interest in intermittent renewable energies which are imposing major technical limitations. Operating ever closer to their limits, the industry-standard AC power grids are subject to instabilities. This book presents an insight into DC grid systems, offering interesting issues to well controlled power grids, in contrast to current AC systems which provide the simplest and most economic connection method for short distances.
Author Benchaib, Abdelkrim
Author_xml – sequence: 1
  fullname: Benchaib, Abdelkrim
BookMark eNqNj8tOwzAQRY14iLb0C9h4h0CKmEmc2rMsoTykClggxC5y4imIRjHEafv7WLQs2LEazejozj1DcdD6lvfEmLRBRMIs10bti-Hvol-PxICQVIYp6WMxDuEDADDPATQMxMXUrW1bs5OFb_vON9Iv5LSQl_K6kE9-w5184H7ju2U4EYcL2wQe7-ZIvNzMnou7ZP54e19M54lFrbVKKLMpO-smDKBYk1GVI1sbC8bmOscKXe20TRcUL0BkDILCiiYEqUpTyEbifBtsw5I34d03fSjXDVfeL0P5xzSyZ1v2s_NfKw59-YPVHGVsU86uChXDo-o_SIxdYt1Inu5I7hp-8-XuMRHkWfYNya9m-A
ContentType eBook
DBID YSPEL
DEWEY 333.7932
DatabaseName Perlego
DatabaseTitleList


DeliveryMethod fulltext_linktorsrc
Discipline Engineering
EISBN 9781119135784
1119135788
111913577X
9781119135777
Edition 1
ExternalDocumentID 9781119135784
EBC4041070
EBC1998798
999053
Genre Electronic books
GroupedDBID 20A
38.
3XM
AABBV
ABARN
ABIAV
ABQPQ
ABQPW
ABYOB
ACLGV
ADVEM
AERYV
AFOJC
AHWGJ
AJFER
AKHYG
ALMA_UNASSIGNED_HOLDINGS
AWAER
AZZ
BBABE
CZZ
FAMPF
GEOUK
JFSCD
JHQRR
JJU
KJBCJ
LQKAK
LWYJN
LYPXV
MEDSZ
MPPRW
MYL
OTAXI
PQQKQ
W1A
WIIVT
YPLAZ
YSPEL
ZEEST
AHCZW
ID FETCH-LOGICAL-a17774-93a2edad6e004e7984bd9ac8a08a5751b1dcd7a2f9a08099881041b9690242203
ISBN 111913577X
9781119135777
9781848218024
1848218028
IngestDate Fri Apr 04 02:11:06 EDT 2025
Wed Oct 29 00:28:31 EDT 2025
Mon Apr 21 07:49:04 EDT 2025
Tue Sep 30 16:19:23 EDT 2025
IsPeerReviewed false
IsScholarly false
LCCallNum_Ident TK447 .B384 2015
Language English
LinkModel OpenURL
MergedId FETCHMERGED-LOGICAL-a17774-93a2edad6e004e7984bd9ac8a08a5751b1dcd7a2f9a08099881041b9690242203
OCLC 919431297
958544948
PQID EBC1998798
PageCount 1 online resource
ParticipantIDs askewsholts_vlebooks_9781119135784
proquest_ebookcentral_EBC4041070
proquest_ebookcentral_EBC1998798
perlego_books_999053
PublicationCentury 2000
PublicationDate 2015
2015-08-26
PublicationDateYYYYMMDD 2015-01-01
2015-08-26
PublicationDate_xml – year: 2015
  text: 2015
PublicationDecade 2010
PublicationPlace Newark
PublicationPlace_xml – name: Newark
PublicationYear 2015
Publisher Wiley
John Wiley & Sons, Incorporated
Wiley-Blackwell
Publisher_xml – name: Wiley
– name: John Wiley & Sons, Incorporated
– name: Wiley-Blackwell
SSID ssj0001550070
Score 1.9537455
Snippet The power engineering domain is facing huge challenges, with an increasing interest in intermittent renewable energies which are imposing major technical...
The concept of Multi-Terminal DC grids (MTDC), where DC cables connect more than two AC/DC converter  stations  is  nowadays  spreading  driven  by  different ...
SourceID askewsholts
proquest
perlego
SourceType Aggregation Database
Publisher
SubjectTerms Control
Electric power systems
Load dispatching
Mathematical models
SCIENCE
Smart power grids
Subtitle System of Systems Approach Based on Spatio-temporal Scales
TableOfContents 2.6.1.2. Jacobean and resolution -- 2.6.2. The second method (for a droop control): generalized approach -- 2.6.2.1. Voltage/power droop -- 2.6.2.2. Voltage/current droop -- 2.6.3. Generalized power flow for multi-terminal DC grids with more than one slack bus -- 2.7. Steady state control of multi-terminal DC grids -- 2.7.1. Normal operation (without fault) -- 2.7.2. Power-step-change with master/slave strategy of control -- 2.7.3. Voltage margin control -- 2.7.4. Power-step-change for a voltage/power droop control -- 2.8. Primary and secondary control strategies -- 2.9. Dynamic control of multi-terminal DC grids -- 2.10. Plug-and-play in interconnected systems: application to MTDC grids -- 2.11. Control of the actuators connected to the power system -- 2.12. Concluding remarks -- 3: From Small Signal to Exact Linearization of Swing Equations -- 3.1. Introduction -- 3.2. Recalling stability analysis tools -- 3.2.1. Small signal analysis - first method of Lyapunov -- 3.2.2. Transient stability -- 3.2.2.1. Equal area concept -- 3.2.3. Global stability -- 3.2.4. Summary of stability approaches -- 3.3. Modeling of AC power network - swing equation -- 3.3.1. Nonlinear swing equation -- 3.3.2. Linearized swing equation -- 3.3.3. Development of the electrical power term -- 3.4. Simulation of AC swing equation -- 3.4.1. Post-fault simulation case (transient response) -- 3.4.1.1. Frequency response -- 3.5. Revisited swing equation for multi-machines power system modeling -- 3.6. Exact linearization of swing equation -- 3.7. Concluding remarks -- 4: Space Scale Properties for AC/DC Power Network Control and Operations: New Aggregation Methods in Power Systems -- 4.1. Introduction -- 4.2. Inter-area oscillation damping: locally intelligent substation -- 4.3. Free of space-scale model for AC systems: model reduction
Cover -- Title Page -- Copyright -- Contents -- Foreword -- Preface -- List of Figures -- List of Tables -- Introduction and Problem Positioning -- I.1. Today's power network conditions -- I.2. AC power network capabilities for more renewable energy penetration -- I.3. The future gird: toward DC grid development -- I.3.1. HVDC for electrical power transmission: integration of offshore wind energy -- I.3.2. MPDC for electrical power distribution: PV integration -- I.3.3. DC grid deployment -- I.4. DC system of systems: time and space scale tools for power network control -- I.5. Book organization -- 1: Modeling Control of VSCs -- 1.1. Introduction -- 1.2. Steady state voltage control systems - multi-terminal direct current (VSC-MTDC) model -- 1.2.1. Convention -- 1.2.2. DC side model -- 1.2.3. DC power flow calculation -- 1.2.4. AC side model -- 1.3. Control system of VSC based on VOC -- 1.3.1. Inner current controller -- 1.3.2. Outer power controller -- 1.3.2.1. Active power controller -- 1.3.2.2. Reactive power controller -- 1.3.3. DC voltage controller -- 1.3.3.1. Master/slave DC voltage control -- 1.3.3.2. DC voltage: active power droop (VD) -- 1.4. Conclusion -- 2: Time Scale Tools: a Control Solution for MTDC Complex Systems with Plug-and-Play Requirements -- 2.1. Introduction -- 2.2. Recalling VSC-HVDC control objectives -- 2.3. DC voltage control strategies for MTDC grids -- 2.3.1. Slack bus control (master/slave control) -- 2.3.2. Voltage margin control -- 2.3.3. Droop control -- 2.3.4. Dead-band-droop control -- 2.3.5. Undead-band-droop-control -- 2.3.6. Priority control -- 2.3.7. Ratio control -- 2.3.8. DC voltage control strategy summary -- 2.4. DC grid steady state modeling -- 2.5. Newton-Raphson technique -- 2.6. DC power flow -- 2.6.1. The first method: for master/slave control strategy -- 2.6.1.1. Mathematical formulation
4.3.1. Average model for N stations multi-terminal systems: aggregated power system -- 4.3.2. Free of space scale model for inter-regions application -- 4.4. Modeling of DC power networks -- 4.4.1. Mathematical approach of two-terminal DC grid modeling -- 4.4.2. Multi-terminal DC (MTDC) grid modeling: generalized MTDC model -- 4.4.3. Toward DC swing equation -- 4.4.4. Development of the electric power term Pe -- 4.4.5. AC and DC "swing equations" equivalence -- 4.5. AC/DC converter control to mimic synchronous generators -- 4.6. Concluding remarks -- Conclusion -- APPENDICES -- Appendix 1: Time Scale Tools: Control Tools Solution for MTDC Complex System with Plug-and-Play Requirements -- Appendix 2: Swing Equation Programming Code -- Inputs -- Outputs -- Swing equation parameters -- Simulation results -- Appendix 3: Kundur's 4-Machines-2-Areas System -- Bibliography -- Index
4.3. Free of space-scale model for AC systems: model reduction -- 4.4. Modeling of DC power networks -- 4.5. AC/DC converter control to mimic synchronous generators -- 4.6. Concluding remarks -- Conclusion -- APPENDICES -- Appendix 1: Time Scale Tools: Control Tools Solution for MTDC Complex System with Plug-and-Play Requirements -- Appendix 2: Swing Equation Programming Code -- Appendix 3: Kundur's 4-Machines-2-Areas System -- Bibliography -- Index -- End User License Agreement
Intro -- Table of Contents -- Title -- Copyright -- Foreword -- Preface -- List of Figures -- List of Tables -- Introduction and Problem Positioning -- I.1. Today's power network conditions -- I.2. AC power network capabilities for more renewable energy penetration -- I.3. The future gird: toward DC grid development -- I.4. DC system of systems: time and space scale tools for power network control -- I.5. Book organization -- 1: Modeling Control of VSCs -- 1.1. Introduction -- 1.2. Steady state voltage control systems - multi-terminal direct current (VSC-MTDC) model -- 1.3. Control system of VSC based on VOC -- 1.4. Conclusion -- 2: Time Scale Tools: a Control Solution for MTDC Complex Systems with Plug-and-Play Requirements -- 2.1. Introduction -- 2.2. Recalling VSC-HVDC control objectives -- 2.3. DC voltage control strategies for MTDC grids -- 2.4. DC grid steady state modeling -- 2.5. Newton-Raphson technique -- 2.6. DC power flow -- 2.7. Steady state control of multi-terminal DC grids -- 2.8. Primary and secondary control strategies -- 2.9. Dynamic control of multi-terminal DC grids -- 2.10. Plug-and-play in interconnected systems: application to MTDC grids -- 2.11. Control of the actuators connected to the power system -- 2.12. Concluding remarks -- 3: From Small Signal to Exact Linearization of Swing Equations -- 3.1. Introduction -- 3.2. Recalling stability analysis tools -- 3.3. Modeling of AC power network - swing equation -- 3.4. Simulation of AC swing equation -- 3.5. Revisited swing equation for multi-machines power system modeling -- 3.6. Exact linearization of swing equation -- 3.7. Concluding remarks -- 4: Space Scale Properties for AC/DC Power Network Control and Operations: New Aggregation Methods in Power Systems -- 4.1. Introduction -- 4.2. Inter-area oscillation damping: locally intelligent substation
Title Advanced Control of AC / DC Power Networks
URI https://www.perlego.com/book/999053/advanced-control-of-ac-dc-power-networks-system-of-systems-approach-based-on-spatiotemporal-scales-pdf
https://ebookcentral.proquest.com/lib/[SITE_ID]/detail.action?docID=1998798
https://ebookcentral.proquest.com/lib/[SITE_ID]/detail.action?docID=4041070
https://www.vlebooks.com/vleweb/product/openreader?id=none&isbn=9781119135784&uid=none
hasFullText 1
inHoldings 1
isFullTextHit
isPrint
link http://utb.summon.serialssolutions.com/2.0.0/link/0/eLvHCXMwnV1LT8JAEN4IXOSkohFfaYwxXqq03dL2iAVDTPCEhluz290qAQGhevDX-21ZKKLR6KVpt-20O9PMzNd5LCFnAlbZEpQCm0gAFCd2TObWEjOxagz2nws7KxLr3NXb9_S25_Zy1J9Vl6T8Mn7_tq7kP1LFGOSqqmT_INklUQxgH_LFFhLGds35XR7q1OJF5D7UmebKnwxBqAmeqnXPVCGvSrnKf4LjvZ9YP4u-NLiQw8G0_7wK-S13DfJn-uITDgRM823Vy43man2ZbNe6DlUhnRf455MXU623peLSevGRAil4HjRDCVaw1cn_TgG4QBnMa-7npH3dIGv5qDIps9kAqhhqOp0BP0zkdCgfx1-sWmaqu1ukJFX9xjbZkKMdUl7pt1ghFwu-GZpvxjgxGuFVMzQyrhkLru2Sh5tWN2ybeqkIk1kePFgzcJgtBRN1ie9DYq6Ui4DFPqv5TIWWuCVi4TE7CTACr9j3gUMtHtQD5aTYNWePFEfjkdwnRgKfjru4yeaYa0AZTRKoQeG4AqQZq5LTlXlHb8MsrD2LFHNUuzzVP4hWSUWzI9JnYfZdp0qMBW-i7DadghvlQvrpEop3hlgOfqdySDbzL-eIFNPpqzyG-5TyEy3rDy6dFxc
linkProvider ProQuest Ebooks
openUrl ctx_ver=Z39.88-2004&ctx_enc=info%3Aofi%2Fenc%3AUTF-8&rfr_id=info%3Asid%2Fsummon.serialssolutions.com&rft_val_fmt=info%3Aofi%2Ffmt%3Akev%3Amtx%3Abook&rft.genre=book&rft.title=Advanced+Control+of+AC%2FDC+Power+Networks&rft.au=Benchaib%2C+Abdelkrim&rft.date=2015-01-01&rft.pub=Wiley&rft.isbn=9781848218024&rft.externalDocID=EBC1998798
thumbnail_l http://utb.summon.serialssolutions.com/2.0.0/image/custom?url=https%3A%2F%2Fwww.perlego.com%2Fbooks%2FRM_Books%2Fwiley_hlvwyirv%2F9781119135777.jpg
thumbnail_m http://utb.summon.serialssolutions.com/2.0.0/image/custom?url=https%3A%2F%2Fvle.dmmserver.com%2Fmedia%2F640%2F97811191%2F9781119135784.jpg