EMT simulation of an MTDC system integrating Modular Multilevel DC/DC converter with DC voltage control
Communication avec acte
Date
2024Résumé
The increasing demand to utilize renewable energy necessitates the transmission of power over long distances. HVDC technology has emerged as the optimal solution for this purpose due to fewer losses and good economic factors. Multi-terminal DC (MTDC) systems are being more focused nowadays, as they offer more advantages over Point to Point (P2P) HVDC scheme because the MTDC network adds more reliability and flexibility to the system. DC/DC converters are emerging as an important device for future MTDC transmission systems. They are required to interconnect HVDC links with different system characteristics such as different DC voltage levels, grounding schemes, and technologies. In addition to this, DC/DC converters are capable of providing additional features in the system like grid protection, DC voltage control, and power flow control. The majority of studies in the literature on DC/DC converters are predominantly focused on the context of either exploring different DC/DC converter topologies or their control and operation in constant power mode for interconnecting HVDC links, suitable for future MTDC grids.
This paper presents an MTDC test case integrating a DC/DC converter where the converter is working with a DC voltage controller and participating in the DC voltage management system. The influence of voltage-controlled DC/DC converter is studied by introducing power disturbances in the MTDC system. The system is modeled and simulated in EMTP software. The droop control technique known for the VSC converter for DC voltage control is extended to obtain a dual droop controller which is used with a DC/DC converter for controlling both DC grid voltages simultaneously. However, this control approach involves designing two droop coefficients for their respective DC grids, complicating the examination of their interaction. Another possibility is to use a new technique called “virtual resistance DC voltage control” which requires tuning only one parameter. The objective is to control DC grid voltages and establish a link between the interconnected networks. The control approach is validated through electromagnetic transient (EMT) simulations. Through the virtual resistance DC voltage control, the interconnected DC grids can share the power disturbance in the system and maintain the DC voltages under their specified limits. This makes the MTDC system more reliable and reduces the stress on the DC voltage management system. Modular multilevel converter (MMC) based topologies are used for DC/DC converters, namely F2F-MMC (front-to-front MMC) which can provide galvanic isolation between the two links and MMC-DC (M2DC) which does not provide galvanic isolation. A comparison analysis has also been made to compare their behavior with a virtual resistance controller. All converters are modeled using reduced order modeling methodology and the DC cables are modeled with wideband models.
The observations in this paper indicate that by employing the virtual resistance DC voltage controller, a connection has been established between interconnected networks, enabling HVDC links to actively participate in and share the power disturbances within the MTDC system. Apart from this, the virtual resistance control behavior remains consistent regardless of the topology of the DC/DC converter, thus demonstrating its robustness as a DC voltage controller.
Fichier(s) constituant cette publication
- Nom:
- L2EP_CIGRE Paris session_2024_ ...
- Taille:
- 1.069Mo
- Format:
- Fin d'embargo:
- 2025-03-01
Cette publication figure dans le(s) laboratoire(s) suivant(s)
Documents liés
Visualiser des documents liés par titre, auteur, créateur et sujet.
-
Communication avec acteSHAFIQUE, Ghazala; BOUKHENFOUF, Johan; GRUSON, Francois; SAMIMI, Shabab; DELARUE, Philippe; LE MOIGNE, Philippe; COLAS, Frédéric; MERLIN, Michael; GUILLAUD, Xavier (2023-10)The Modular Multi-Level DC-DC Converter (M2DC) is an attractive non-isolated DC-DC converter topology for HVDC grid. In order to carry out MTDC grid stability studies, the development of reduce order models of converters ...
-
Article dans une revue avec comité de lectureSHAFIQUE, Ghazala; BOUKHENFOUF, Johan; GRUSON, Francois; SAMIMI, Shabab; COLAS, Frédéric; GUILLAUD, Xavier (Institution of Engineering and Technology (IET), 2024-09)AbstractThe future multi‐terminal direct‐current (MTDC) grid will require the interconnection of point‐to‐point high‐voltage (HV) DC links with different specifications such as DC voltage level, system grounding configuration ...
-
Communication avec acteSHAFIQUE, Ghazala; GRUSON, Francois; COLAS, Frédéric; GUILLAUD, Xavier (The Institution of Engineering and Technology (IET), 2024)The development of multi-terminal DC (MTDC) networks has various challenges as interconnecting grids of different voltages and grounding schemes, DC grid protection and power flow. DC/DC converter has emerged as the ...
-
Représentation Energétique Macroscopique et Diagramme PQ des Convertisseurs Modulaires Multi-niveaux Communication avec acteSAMIMI, Shabab; GRUSON, Francois; DELARUE, Philippe; GUILLAUD, Xavier; COLAS, Frederic (2014-10-08)Le système étudié dans cet article est un convertisseur Modulaires Multi-Niveaux. Dans une première partie, l'utilisation de la Représentation Energétique Macroscopique (REM) permet de mettre en évidence les couplages ...
-
Communication avec acteQORIA, Taoufik; COLAS, Frédéric; GUILLAUD, Xavier; DEBRY, Marie-Sophie; PREVOST, Thierry; GRUSON, Francois (IEEE, 2018)From the origin of the grid, energy has been delivered to electrical loads mainly by synchronous machines. All the main rules to manage the grid have been based on the electromechanical behavior of these machines which ...