A Review of DC Shipboard Microgrids—Part II: Control Architectures, Stability Analysis, and Protection Schemes

Xu, Luona; Guerrero, Josep M.; Lashab, Abderezak; Wei, Baoze; Bazmohammadi, Najmeh; Vasquez, Juan C.; Abusorrah, Abdullah

doi:10.1109/tpel.2021.3128409

Cited by 74 publications

(24 citation statements)

References 137 publications

(151 reference statements)

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“…In maritime applications, onboard DC grids are developed in the form of modular power system platforms that are comprised of modules of power sources; these may include variable-speed > REPLACE THIS LINE WITH YOUR MANUSCRIPT ID NUMBER (DOUBLE-CLICK HERE TO EDIT) < generators, energy-storage units, fuel cells, or auxiliary systems. Currently, a low-voltage DC system architecture is usually adopted for ships that require less than 1 MW; larger ships that demand more than 10 MW need an MVDC architecture [34]. Therefore, the on-board voltage level for small ships, ferries, and short-sea vessels is around 1kV, while a medium voltage is applied (above 3kV) for larger ships (which still need diesel generators or LNG (liquefied natural gas) generators to be the main power sources).…”

Section: Insulation Systems Of Transportation Devicesmentioning

confidence: 99%

Effect of Magnetic Field on Partial Discharge Dynamics in Insulation Systems of Transportation Power Devices

Florkowski

2022

IEEE Trans. Transp. Electrific.

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The globally observed trend toward electrically supplied devices is common in the transportation segment. Traditionally, the performance of electrical insulation has been assessed with respect to electric stresses and endurance. In all current-carrying devices, magnetic fields will also be superimposed on electric ones; therefore, the influence of a magnetic field's exposure on partial discharge (PD) dynamics is an actual research topic. This problem is important in the T This article has been accepted for publication in IEEE Transactions on Transportation Electrification.

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Section: Insulation Systems Of Transportation Devicesmentioning

confidence: 99%

Effect of Magnetic Field on Partial Discharge Dynamics in Insulation Systems of Transportation Power Devices

Florkowski

2022

IEEE Trans. Transp. Electrific.

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“…Most promising are so-called hybrid circuit breaker, which are a combination of solid-state switches for arc-free switching and mechanical switches for providing galvanic isolation [77]. Compared to passive/active resonance DC circuit breaker, hybrid circuit breaker offer faster response times and have less risk of arcing [78]. A hybrid circuit breaker with galvanic sepa-ration and fail-safe functionality is especially suitable for the application between two high voltage DC-buses to avoid Single Point of Failure (SPOF).…”

Section: A Design Considerations For System Architecturementioning

confidence: 99%

“…In order to protect crew or passengers from leakage current, RCD are mandatory in aircraft designs. A type B RCD, which is able to detect the leakage current with DC components is recommended for DC grids in [78]. For future application, advanced RCD solutions with real-time leakage current monitoring function are expected for electric aircraft system architecture [84].…”

Section: A Design Considerations For System Architecturementioning

confidence: 99%

Power Distribution and Propulsion System for an All-Electric Short-Range Commuter Aircraft—A Case Study

et al. 2022

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To participate in the transition towards a sustainable use of energy, the aircraft sector needs to be transformed with respect to the energy carrier and propulsion methods. For smaller aircraft, a battery-electric approach is promising. While this will require extensive research and design as well as the application of advanced components which are partly not available to this date, general design rules and decisive parameters and components can already by deduced. This publication presents the exemplary design of the full propulsion system for a small commuter aircraft. This serves as a case study to highlight the influence of components and parameters on the overall efficiency and weight of the system. By that, future research can be directed towards the areas of high impact on the realization of all electric aircraft.INDEX TERMS Aviation, aerospace electronics, AEA, aircraft propulsion, DC/DC converters, electric power supply systems, high voltage direct current, power semiconductor devices, reliability, safety, wide bandgap semiconductors, wiring harness Nomenclature This article has been accepted for publication in IEEE Access.

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“…Furthermore, adding a capacitor or resistor known as the passive damping method can improve the stability of the DCMG, whereas they are costly and increase the size of the converters [9]. Active damping strategies stabilize the DCMG feeding CPLs utilizing virtual resistor, virtual capacitor, and virtual impedance to improve the stability of the DCMG by modifying the control loops [10]. These methods increase damping by injecting the power into the system.…”

Section: Introductionmentioning

confidence: 99%

An intelligent sliding mode control for stabilization of parallel converters feeding CPLs in DC‐microgrid

Mosayebi

Gheisarnejad

Khooban

2022

IET Power Electronics

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The constant power loads (CPLs) threaten the stability of the DC microgrids (DCMGs) due to the negative impedance characteristic, which leads to voltage oscillations or a blackout in the DCMG. This paper proposes a new droop control for paralleled DC-DC converters feeding CPLs in the DCMG to improve the stability of the whole system. In this approach, an optimization droop gain is conducted for each converter to guarantee current sharing among paralleled converters. Furthermore, an intelligent single input interval type-II fuzzy logic controller (SIT2-FLC) is developed in a model-free framework to further ameliorate the current sharing and voltage regulation in the DCMG when supplying the CPLs. An extended-state observer (ESO) is adopted in the model-free controller to estimate the unmodelled dynamics in the DC-DC converters feeding CPLs. Since an estimation observer error often appears in the presence of uncertainties, a sliding mode control (SMC) technique is proposed to remove the estimation error and enhance the system stability. The studied DCMG is developed in hardware-in-the-loop (HIL) with various levels of CPL's power to verify the applicability of the suggested mode-free intelligent controller.

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A Review of DC Shipboard Microgrids—Part II: Control Architectures, Stability Analysis, and Protection Schemes

Cited by 74 publications

References 137 publications

Effect of Magnetic Field on Partial Discharge Dynamics in Insulation Systems of Transportation Power Devices

Effect of Magnetic Field on Partial Discharge Dynamics in Insulation Systems of Transportation Power Devices

Power Distribution and Propulsion System for an All-Electric Short-Range Commuter Aircraft—A Case Study

An intelligent sliding mode control for stabilization of parallel converters feeding CPLs in DC‐microgrid

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