Enabling Technologies and Applications for Power Electronics-Enabled Electric Power Distribution Systems
Editat de Wencong Su, Alex Huangen Limba Engleză Paperback – 31 ian 2024
- Bridges the technology gap between power systems and power electronics, two traditionally disjointed research areas
- Analyzes the architecture of emerging power electronics-enabled electric power distribution systems
- Discusses emerging technologies and applications for power electronics-enabled electric power distribution systems
- Reviews case studies of early-stage R&D and pilot projects to demonstrate key theoretical, technological and economic considerations
- Evaluates how these developments are likely to transform legacy power systems
- Features MATLAB simulation files and source code to help practitioners enable stable and reliable modern microgrids
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Specificații
ISBN-13: 9780323909754
ISBN-10: 0323909752
Pagini: 256
Dimensiuni: 191 x 235 mm
Editura: ELSEVIER SCIENCE
ISBN-10: 0323909752
Pagini: 256
Dimensiuni: 191 x 235 mm
Editura: ELSEVIER SCIENCE
Cuprins
Section 1. Overview and Vision
1.1 The need and challenges of power electronics-enabled electric power distribution systems: From power systems perspectives
UM-Dearborn
1.2 The need and challenges of power electronics-enabled electric power distribution systems: From power electronics perspectives
UT-Austin
Section 2. Stability and Reliability of Modern Microgrid
2.1 Large-signal stability analysis of DC microgrid systems based on potential theory
UM-Dearborn
2.2 Large-signal stability visualization and enhancement of DC grid
UM-Dearborn
2.3 Digital control technologies for DC-DC converters in microgrids
UM-Dearborn
2.4 Machine-Learning-assisted reliability analysis of power systems integrated with high-penetration of power converters
UM-Dearborn
2.5 Stability and control of weak AC systems
UM-Dearborn
2.6 The roles of retail demand response for ancillary services in microgrids
UM-Dearborn
Section 3. Grid Forming Synchronous Generators for Active Distribution Systems with High Penetration of Distributed Renewable Generation
3.1 From grid-following to grid-forming inverters: a paradigm shift
UM-Dearborn & UT-Austin
3.2 Grid-forming photovoltaic inverter
UT-Austin
Section 4. Solid State Technology for Active Distribution Systems with High Penetration of Distributed Renewable Generation
4.1 Overview of solid-state technology in grid-scale applications
UT-Austin
4.2 Solid state transformer (SST)
UT-Austin
4.3 Solid state circuit breaker (SSCB) and fault isolation device (FID)
UT-Austin
1.1 The need and challenges of power electronics-enabled electric power distribution systems: From power systems perspectives
UM-Dearborn
1.2 The need and challenges of power electronics-enabled electric power distribution systems: From power electronics perspectives
UT-Austin
Section 2. Stability and Reliability of Modern Microgrid
2.1 Large-signal stability analysis of DC microgrid systems based on potential theory
UM-Dearborn
2.2 Large-signal stability visualization and enhancement of DC grid
UM-Dearborn
2.3 Digital control technologies for DC-DC converters in microgrids
UM-Dearborn
2.4 Machine-Learning-assisted reliability analysis of power systems integrated with high-penetration of power converters
UM-Dearborn
2.5 Stability and control of weak AC systems
UM-Dearborn
2.6 The roles of retail demand response for ancillary services in microgrids
UM-Dearborn
Section 3. Grid Forming Synchronous Generators for Active Distribution Systems with High Penetration of Distributed Renewable Generation
3.1 From grid-following to grid-forming inverters: a paradigm shift
UM-Dearborn & UT-Austin
3.2 Grid-forming photovoltaic inverter
UT-Austin
Section 4. Solid State Technology for Active Distribution Systems with High Penetration of Distributed Renewable Generation
4.1 Overview of solid-state technology in grid-scale applications
UT-Austin
4.2 Solid state transformer (SST)
UT-Austin
4.3 Solid state circuit breaker (SSCB) and fault isolation device (FID)
UT-Austin