Multi-infeed HVDC In the brazilian interconnected power system
Edson H. Watanabe e Robson F. S. Dias (orgs.)
- 1 Introduction
- 1.1. Scenario and Simulation Model
- 1.2. The Commutation Failure Process
- 1.3. Commutation Failure Assessment Indexes
- 1.4. Synchronous Compensator and STATCOM
- 1.5. Dynamic Extinction Angle Control
- 1.6. Series Voltage Conditioner (SeVC)
- 1.7. Hybrid LCC and MMC HVDC and All MMC HVDC
- References
- 2 The Commutation Failure Process
- 2.1. Understanding the CF Phenomenon
- 2.2. CF Relevance in the BIPS
- 2.3. DC Fault Study
- 3 Commutation Failure Assessment Indexes
- 3.1. MIIF Analysis
- 3.2. CF Fast Assessment Based on Short-Circuit Program
- 3.3. Conclusions
- References
- 4 Synchronous Compensator and STATCOM
- 4.1. Analysis Based on the ANATEM Program:
The Synchronous Compensator as First Line of Defense to Commutation Failures in Multi-Infeed HVDC Systems
- 4.2. Analysis based on the PSCAD program - SC and MMC-STATCOM to Mitigate CF
- References
- 5 Dynamic Extinction Angle Control
- 5.1. Detailing of CFPREV and CFIM Algorithms
- 5.2. Simulation Results
- 5.3. Recommendations on CFPREV and CFIM
- 5.4. Conclusions
- References
- 6 The Series Voltage Conditioner (SeVC)
- 6.1. Principle of Operation of Series Voltage Conditioner (SeVC)
- 6.2. SeVC – Synthesized by an MMC converter
- 6.3. Simulation and Results
- 6.4. Conclusions
- References
- 7 LCC/MMC Hybrid HVDC and All MMC HVDC Systems
- 7.1. Introduction
- 7.2. HVDC with MMC
- 7.3. Simulation Results
- 7.4. BIPS Future Scenario Analysis - Bipole B Expansion
- 7.5. Conclusion
- 7.6. Recommendations
- References
- 8 Conclusions
- 8.1. The Commutation Failure Process
- 8.2. Assessment of Commutation Failure Indexes
- 8.3. Synchronous Compensator and STATCOM
- 8.4. Dynamic Extinction Angle Control
- 8.5. The Series Voltage Conditioner (SeVC)
- 8.6. LCC and MMC Hybrid HVDC and All MMC HVDC
- 8.7. Final Conclusions
- Author’s Biographies
Acknowlegments