Design Considerations for the Electrical Power Supply of Future Civil Aircraft with Active High-Lift Systems

Mueller, Juergen; Bensmann, Astrid; Bensmann, Boris; Fischer, Tore; Kadyk, Thomas; Narjes, Gerrit; Kauth, Felix; Ponick, Bernd; Seume, Joerg R.; Krewer, Ulrike; Hanke‐Rauschenbach, Richard; Mertens, Axel

doi:10.3390/en11010179

Cited by 14 publications

(8 citation statements)

References 28 publications

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“…For electric airplanes, there is a need to use batteries for power supply, which leads to an efficiency enhancement from 30% to 80% from turboprop engine to a full battery-electric system, according to Mueller et al [84]. They also investigate the efficiency increase of ICE to hydrogen-based FC and obtain a development from 30% to 41.7% overall efficiency.…”

Section: Aviation Specific Energy Demandmentioning

confidence: 99%

“…The phase-in of all-electric flights is visualized in Figure 3, and based on the estimate of 11.7% of all p-km for flights up to 1.5 h and 23.4% of all p-km for flights within 1.5 and 3 h, whereas 80% of these flights should be served by all-electric flights in the longer term, which is projected to be achieved between 2050 and 2060. The assumed progress in aviation technology and respective implementation is based on today's understanding of technological options [84,90,91], first respective policies [52] and the enormous pressure to react on climate emergency [2,69,92,93], while economics may be attractive and first leading technology providers and airlines push the development to introduce all-electric flights by 2030 [94].…”

Section: Capital Expenditures Operational Expenditures and Lifetimementioning

confidence: 99%

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Global Transportation Demand Development with Impacts on the Energy Demand and Greenhouse Gas Emissions in a Climate-Constrained World

et al. 2019

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The pivotal target of the Paris Agreement is to keep temperature rise well below 2 °C above the pre-industrial level and pursue efforts to limit temperature rise to 1.5 °C. To meet this target, all energy-consuming sectors, including the transport sector, need to be restructured. The transport sector accounted for 19% of the global final energy demand in 2015, of which the vast majority was supplied by fossil fuels (around 31,080 TWh). Fossil-fuel consumption leads to greenhouse gas emissions, which accounted for about 8260 MtCO2eq from the transport sector in 2015. This paper examines the transportation demand that can be expected and how alternative transportation technologies along with new sustainable energy sources can impact the energy demand and emissions trend in the transport sector until 2050. Battery-electric vehicles and fuel-cell electric vehicles are the two most promising technologies for the future on roads. Electric ships and airplanes for shorter distances and hydrogen-based synthetic fuels for longer distances may appear around 2030 onwards to reduce the emissions from the marine and aviation transport modes. The rail mode will remain the least energy-demanding, compared to other transport modes. An ambitious scenario for achieving zero greenhouse gas emissions by 2050 is applied, also demonstrating the very high relevance of direct and indirect electrification of the transport sector. Fossil-fuel demand can be reduced to zero by 2050; however, the electricity demand is projected to rise from 125 TWhel in 2015 to about 51,610 TWhel in 2050, substantially driven by indirect electricity demand for the production of synthetic fuels. While the transportation demand roughly triples from 2015 to 2050, substantial efficiency gains enable an almost stable final energy demand for the transport sector, as a consequence of broad electrification. The overall well-to-wheel efficiency in the transport sector increases from 26% in 2015 to 39% in 2050, resulting in a respective reduction of overall losses from primary energy to mechanical energy in vehicles. Power-to-fuels needed mainly for marine and aviation transport is not a significant burden for overall transport sector efficiency. The primary energy base of the transport sector switches in the next decades from fossil resources to renewable electricity, driven by higher efficiency and sustainability.

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Section: Aviation Specific Energy Demandmentioning

confidence: 99%

Section: Capital Expenditures Operational Expenditures and Lifetimementioning

confidence: 99%

Global Transportation Demand Development with Impacts on the Energy Demand and Greenhouse Gas Emissions in a Climate-Constrained World

et al. 2019

View full text Add to dashboard Cite

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“…Based on the current power required the estimated electrical power to properly operate an AEA narrowbody, such as the A320, would be around 20 MW [28]. It is worth noting that distributed propulsion is highly regarded in electrical aircraft to enhance the fuselage aerodynamics [43], [44] However, distributed propulsion negatively impacts power, weight and volumetric requirements for the electric system [45]. The evaluation of this kind of propulsion systems would require the use of Model Based Systems Engineering (MBSE) analysis [46], [47] to correctly identify the benefits in terms of weight at system level.…”

Section: Design Requirementsmentioning

confidence: 99%

Future of Electrical Aircraft Energy Power Systems: An Architecture Review

Cano

Castro²,

Rodríguez

et al. 2021

IEEE Trans. Transp. Electrific.

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This paper presents and in-depth analysis of All-Electric-Aircraft (AEA) architectures. The aim of this work is to provide a global vision of the current AEA state of art, to estimate main technological gaps and drivers and to identify the most promising architecture configuration for future electrical aircraft in the context of a twin propeller 20 MW aircraft. The comparison between architectures is done based on three different figures of merit: reliability, efficiency and specific power density. The methodology presented and the trade studies are applied to a narrowbody aircraft of 20 MW, equivalent to an Airbus A320, and following current efforts of government agencies to achieve cleaner air mobility within the next two decades.

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“…For weight savings, novel fuselage and wing materials have to be considered. For the electrical systems, high efficiency electrical drives as well as high power density energy sources are needed [6]. Interconnecting the sources as well as the loads, which includes beside the motors additionally the Wing Ice Protection System (WIPS), the Environmental Control System (ECS), the control flaps, avionics, hotel and galley loads and more, requires a high efficiency energy distribution system.…”

Section: Emamentioning

confidence: 99%

Discussion on Electric Power Supply Systems for All Electric Aircraft

et al. 2020

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The electric power supply system is one of the most important research areas within sustainable and energy-efficient aviation for more-and especially all electric aircraft. This paper discusses the history in electrification, current trends with a broad overview of research activities, state of the art of electrification and an initial proposal for a short-range aircraft. It gives an overview of the mission profile, electrical sources, approaches for the electrical distribution system and the required electrical loads. Current research aspects and questions are discussed, including voltage levels, semiconductor technology, topologies and reliability. Because of the importance for safety possible circuit breakers for the proposed concept are also presented and compared, leading to a initial proposal. Additionally, a very broad review of literature and a state of the art discussion of the wiring harness is given, showing that this topic comes with a high number of aspects and requirements. Finally, the conclusion sums up the most important results and gives an outlook on important future research topics. INDEX TERMS Aviation, aerospace electronics, MEA, AEA, electric power supply systems, dc-dc power converters, power semiconductor devices, wide bandgap semiconductors, high voltage direct current (HVDC), circuit breaker, hybrid circuit breaker.

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Design Considerations for the Electrical Power Supply of Future Civil Aircraft with Active High-Lift Systems

Cited by 14 publications

References 28 publications

Global Transportation Demand Development with Impacts on the Energy Demand and Greenhouse Gas Emissions in a Climate-Constrained World

Global Transportation Demand Development with Impacts on the Energy Demand and Greenhouse Gas Emissions in a Climate-Constrained World

Future of Electrical Aircraft Energy Power Systems: An Architecture Review

Discussion on Electric Power Supply Systems for All Electric Aircraft

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