Details
| Original language | English |
|---|---|
| Pages (from-to) | 41-55 |
| Number of pages | 15 |
| Journal | IEEE Industrial Electronics Magazine |
| Volume | 13 |
| Issue number | 2 |
| Publication status | Published - 1 Jun 2019 |
Abstract
The high implementation of renewable energy systems (RESs) and the need to increase transmission capacity across Europe (e.g., north-south Germany) have resulted in integrated power electronics (PE)-based solutions in electrical grids. PE allows more flexibility and control over power grids. Solutions such as high-voltage (HV) dc systems and flexible alternating current transmission systems (FACTS) increase energy transfer capabilities while preserving the system's safety (e.g., providing reactive power). Additionally, PE-based solutions, which are characterized by fast dynamic control actions, can support the grid during disturbances [e.g., a low-voltage ridethrough (LVRT) during faults]. These solutions are widely integrated into RES applications, where they enable maximized energy extraction from natural resources (e.g., the maximum power point tracker).
Keywords
- ac harmonic stability, ac-dc transient stability, electrical grids, Energy exchange, energy transfer capabilities, FACTS, fast dynamic control actions, flexible AC transmission systems, Flexible AC transmission systems, flexible alternating current transmission systems, frequency control, high-voltage dc systems, HVDC power convertors, HVDC power transmission, integrated power electronics-based solutions, load flow, modeling techniques, PE-based solutions, power electronics, Power electronics, power generation control, power grids, Power grids, power system stability, power transmission control, renewable energy sources, Renewable energy sources, renewable energy systems, RESs, Safety, SSR studies, transmission capacity
ASJC Scopus subject areas
- Engineering(all)
- Electrical and Electronic Engineering
- Engineering(all)
- Industrial and Manufacturing Engineering
Sustainable Development Goals
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In: IEEE Industrial Electronics Magazine, Vol. 13, No. 2, 01.06.2019, p. 41-55.
Research output: Contribution to journal › Article › Research › peer review
}
TY - JOUR
T1 - Which Deepness Class Is Suited for Modeling Power Electronics?
T2 - A Guide for Choosing the Right Model for Grid-Integration Studies
AU - De Carne, Giovanni
AU - Langwasser, Marius
AU - Ndreko, Mario
AU - Bachmann, Ralf
AU - De Doncker, Rik W.
AU - Dimitrovski, Robert
AU - Mortimer, Benedict J.
AU - Neufeld, Alexander
AU - Rojas, Freiber
AU - Liserre, Marco
N1 - Funding information: The research leading to the results giv en in this article was funded by the German Federal Ministry of Education and Research under the Kopernikus Project
PY - 2019/6/1
Y1 - 2019/6/1
N2 - The high implementation of renewable energy systems (RESs) and the need to increase transmission capacity across Europe (e.g., north-south Germany) have resulted in integrated power electronics (PE)-based solutions in electrical grids. PE allows more flexibility and control over power grids. Solutions such as high-voltage (HV) dc systems and flexible alternating current transmission systems (FACTS) increase energy transfer capabilities while preserving the system's safety (e.g., providing reactive power). Additionally, PE-based solutions, which are characterized by fast dynamic control actions, can support the grid during disturbances [e.g., a low-voltage ridethrough (LVRT) during faults]. These solutions are widely integrated into RES applications, where they enable maximized energy extraction from natural resources (e.g., the maximum power point tracker).
AB - The high implementation of renewable energy systems (RESs) and the need to increase transmission capacity across Europe (e.g., north-south Germany) have resulted in integrated power electronics (PE)-based solutions in electrical grids. PE allows more flexibility and control over power grids. Solutions such as high-voltage (HV) dc systems and flexible alternating current transmission systems (FACTS) increase energy transfer capabilities while preserving the system's safety (e.g., providing reactive power). Additionally, PE-based solutions, which are characterized by fast dynamic control actions, can support the grid during disturbances [e.g., a low-voltage ridethrough (LVRT) during faults]. These solutions are widely integrated into RES applications, where they enable maximized energy extraction from natural resources (e.g., the maximum power point tracker).
KW - ac harmonic stability
KW - ac-dc transient stability
KW - electrical grids
KW - Energy exchange
KW - energy transfer capabilities
KW - FACTS
KW - fast dynamic control actions
KW - flexible AC transmission systems
KW - Flexible AC transmission systems
KW - flexible alternating current transmission systems
KW - frequency control
KW - high-voltage dc systems
KW - HVDC power convertors
KW - HVDC power transmission
KW - integrated power electronics-based solutions
KW - load flow
KW - modeling techniques
KW - PE-based solutions
KW - power electronics
KW - Power electronics
KW - power generation control
KW - power grids
KW - Power grids
KW - power system stability
KW - power transmission control
KW - renewable energy sources
KW - Renewable energy sources
KW - renewable energy systems
KW - RESs
KW - Safety
KW - SSR studies
KW - transmission capacity
UR - http://www.scopus.com/inward/record.url?scp=85068135633&partnerID=8YFLogxK
U2 - 10.1109/mie.2019.2909799
DO - 10.1109/mie.2019.2909799
M3 - Article
VL - 13
SP - 41
EP - 55
JO - IEEE Industrial Electronics Magazine
JF - IEEE Industrial Electronics Magazine
SN - 1941-0115
IS - 2
ER -