Decentralized Power Management for Electrical Power Systems in More Electric Aircrafts

Kim, Myungchin; Lee, Sung Gu; Bae, Sungwoo

doi:10.3390/electronics7090187

Cited by 15 publications

(13 citation statements)

References 54 publications

(119 reference statements)

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“…In the paper, a two-stage management strategy was proposed; the total power that is needed to be absorbed/generated is calculated in the first stage, and the power to be stored and to be dissipated are determined in the second stage (by a fuzzy logic approach as a multi objective approach). Decentralized EMS were taken into consideration in [78] and [79]. In [78], a virtual impedance consisted of a resistor and an inductor was utilized to adjust the power sharing ratio both in the transient and steady state.…”

Section: G Management Of Aircraft Electric Power Systemsmentioning

confidence: 99%

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Electric Power Systems in More and All Electric Aircraft: A Review

2020

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Narrow body and wide body aircraft are responsible for more than 75% of aviation greenhouse gas (GHG) emission and aviation, itself, was responsible for about 2.5% of all GHG emissions in the United States in 2018. This situation becomes worse when considering a 4-5% annual growth in air travel. Electrified aircraft is clearly a promising solution to combat the GHG challenge; thus, the trend is to eliminate all but electrical forms of energy in aircraft power distribution systems. However, electrification adds tremendously to the complexity of aircraft electric power systems (EPS), which is dramatically changing in our journey from conventional aircraft to more electric aircraft (MEA) and all electric aircraft (AEA). In this paper, we provide an in-depth discussion on MEA/AEA EPS: electric propulsion, distributed propulsion systems (DPS), EPS voltage levels, power supplies, and EPS architectures are discussed. Publications on power flow (PF) analysis and management of EPS are reviewed, and an initial schematic of a potential aircraft EPS with electric propulsion is proposed. In this regard, we also briefly review the components required for MEA/AEA EPS, including power electronics (PE) converters, electric machines, electrochemical energy units, circuit breakers (CBs), and wiring harness. A comprehensive review of each of the components mentioned above or other topics except for those related to steady state power flow in MEA/AEA EPS is out of this paper's scope and should be found somewhere else. At the close of the paper, some challenges in the path towards AEA are presented. Unless the discussed challenges are satisfactorily addressed and solved, arriving at an AEA that can properly operate over commercial missions will not be possible. INDEX TERMS aircraft electrification, all electric aircraft (AEA), electric power system (EPS), more electric aircraft (MEA), power distribution system, steady state power flow analysis.

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Section: G Management Of Aircraft Electric Power Systemsmentioning

confidence: 99%

“…Decentralized EMS were taken into consideration in [78] and [79]. In [78], a virtual impedance consisted of a resistor and an inductor was utilized to adjust the power sharing ratio both in the transient and steady state. In [79], an EMS was proposed for APU comprised of fuel cells and supercapacitors.…”

Section: G Management Of Aircraft Electric Power Systemsmentioning

confidence: 99%

Electric Power Systems in More and All Electric Aircraft: A Review

2020

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“…whereφ ij and other terms are as given in LMI (8). Similarly, LMI (9) can be obtained by multiplying R S 12 * R ≥ 0 by diag P 2P2 .…”

Section: Appendixes Appendix a A Proof Of Theoremmentioning

confidence: 99%

Robust Centralized Control for DC Islanded Microgrid Considering Communication Network Delay

2020

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In recent years, the application of renewable energy resources (RES) with DC output has increased, and RES integration as DC islanded microgrids (DC ImGs) has attracted the attention of many researchers. However, DC ImGs face many challenges, and voltage stability is extremely critical for efficient power distribution. This challenge becomes more prominent when exogenous disturbances, as well as time-delay, exist in the system mainly because of the communication network. In this study, we develop a mathematical model of the time-delay DC ImG. To compensate for the effect of the time-delay, three control strategies are introduced-stabilizing, robust, and robust-predictor. The controller's stability is guaranteed based on the Lyapunov-Krasovskii theorem, whereas for the exogenous disturbance rejection, the L 2-norm of the system is reduced. Furthermore, to obtain the proposed controllers' gains, linear-matrixinequality constraints are formulated. The performances of the controllers are investigated through numerous simulations, and a detailed analysis is presented.

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“…The pervasive electrification of the transportation sector is also driving up power electronics complexity, for both cars [3] with the introduction of hybrid and electric vehicles, and aircraft [4]. In fact, the More Electric Aircraft (MEA) [5] framework aims to replace the mechanical, hydraulic, and pneumatic systems with electromechanical ones. This will lead to an increase in overall efficiency through the use of a more effective, bleedless turbofan main engine, and to weight reduction due to the elimination of ducting, valving, and other power transmission components.…”

Section: Introductionmentioning

confidence: 99%

Minimization of Network Induced Jitter Impact on FPGA-Based Control Systems for Power Electronics through Forward Error Correction

et al. 2020

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In modular distributed architectures, the adoption of a communication method that is at the same time robust and has a low and predictable latency is of utmost importance in order to support the required system dynamics. The aim of this paper is to evaluate the consequences of the random jitter on machine drives distributed control, caused by the messages’ re-transmission in case of an error in the received data. To achieve this goal, two different Forward Error Correction (FEC) techniques are introduced in the chosen protocol, so that the recipient of the message can correct random errors without the need of any additional round trip delays needed to request and obtain a re-transmission. Experimentally validated simulations are used to evaluate the impact of random network derived jitter on a real world closed loop control system for distributed power electronic converters.

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Decentralized Power Management for Electrical Power Systems in More Electric Aircrafts

Cited by 15 publications

References 54 publications

Electric Power Systems in More and All Electric Aircraft: A Review

Electric Power Systems in More and All Electric Aircraft: A Review

Robust Centralized Control for DC Islanded Microgrid Considering Communication Network Delay

Minimization of Network Induced Jitter Impact on FPGA-Based Control Systems for Power Electronics through Forward Error Correction

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