Takeoff and Performance Trade-Offs of Retrofit Distributed Electric Propulsion for Urban Transport

Moore, Kevin R.; Ning, Andrew

doi:10.2514/1.c035321

Cited by 38 publications

(14 citation statements)

References 43 publications

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“…However, when the noise was constrained, the 8 propeller configuration showed the optimum takeoff distance with a reduction of 43% compared to conventional two prop case. Furthermore, according to the results presented in the work of Moore and Ning (2019), the following conclusion can be drawn: the 2 propeller configuration will always be noisier than the 4 or 8 propeller for a given thrust to weight ratio. However, results are questionable since the work focused more on aerodynamics for takeoff distance reduction and only a low fidelity semiempirical model was used for noise assessment.…”

Section: Distributed Propulsionmentioning

confidence: 85%

“…When noise constraints are imposed, multiple smaller propellers allow for smaller tip speeds, still being able to comply with thrust requirements (Moore and Ning, 2019). Reducing tip speed has a beneficial effect on noise, as already mentioned.…”

Section: Distributed Propulsionmentioning

confidence: 90%

“…However, thrust-to-weight ratio must be taken into consideration when choosing the number of propellers, because a large amount of propellers rotating at lower speeds will have a significant amount of weight penalty. Moore and Ning (2019) in their study, found that the optimum propeller number is 8, for an aircraft of the size similar to Tecnam p2006t. Another ben efit of multiple small propellers, is that they have higher BPF, which have larger sound power dissipation in the atmosphere (Synodinos et al, 2018a).…”

Section: Distributed Propulsionmentioning

confidence: 94%

See 2 more Smart Citations

Noise of Future Aircraft Propulsion: Sources and Design Considerations

Protopapadakis¹,

Gkoutzamanis²,

Vouros³

et al. 2022

Proceedings of Global Power &Amp; Propulsion Society

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This paper attempts to reduce the gap, when it comes to future aircraft concepts noise and aeroacoustics, and at the same time introduce basic noise aspects for people unfamiliar to it. This is performed by taking into account the following four stages: Identification of conventional aircraft noise sources, overview of the aeroacoustics of future aircraft configurations, derivation of conceptual design considerations for noise issues, and finally, insight on the impact of technology advancements on certification. More specifically, a holistic overview of the aeroacoustics of aircraft was performed. The noise sources were described and made available for those unacquainted with the subject. Aeroacoustic behavior of ContraRotating Open Rotors, Boundary Layer Ingestion and Distributed Propulsion concepts was studied trough the most recent and relevant literature. The phenomena causing noise were highlighted, and the differences between conventional and future designs detected. It was found that generally noise sources are similar, but the intensity of some can be significantly altered. Early design phase guidelines were extracted for each of the concepts. The design considerations are grouped into a matrix showing the relative effect of each on noise emissions. With these guidelines, it is possible to perform design choices in the conceptual level of fidelity for future aircraft concepts. Furthermore, certification aspects and observations considering its future development are presented. Noise emissions are expected to change, and thus certification must be adapted to it. Furthermore, in this quick advancing technology field, virtual certification is advised to be used.

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Section: Distributed Propulsionmentioning

confidence: 85%

Section: Distributed Propulsionmentioning

confidence: 90%

Section: Distributed Propulsionmentioning

confidence: 94%

See 1 more Smart Citation

Noise of Future Aircraft Propulsion: Sources and Design Considerations

Protopapadakis¹,

Gkoutzamanis²,

Vouros³

et al. 2022

Proceedings of Global Power &Amp; Propulsion Society

View full text Add to dashboard Cite

show abstract

“…Interest in a better understanding of field performance uncertainty is likely to increase in the coming years, carried by the rising tide of the quest for the most effective urban mobility solution. Discussions around this topic are often dominated by multirotor vertical takeoff and landing (VTOL) concepts, but there is a school of thought that advocates fixed-wing solutions with distributed electric propulsion as a faster, more viable route to effective urban mobility [11], which can be built on an existing airworthiness framework (such as 14 CFR Part 23) and may suffer less from the noise issues and technological risks of VTOL ideas. Such concepts hinge, however, on their feasibility in tight, cluttered, complex environments, often featuring "tabletop" runways on the roofs of buildings, and complicated failure and abort scenarios.…”

Section: Uncertainty In Field Performance Predictionmentioning

confidence: 99%

Flight-Test Validation of a Takeoff Performance Uncertainty Model

Sóbester

2021

Journal of Aircraft

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“…Some studies retrofit an existing aircraft with hybridelectric propulsion (HEP) to analyze a specific aspect of the technology, maintaining takeoff mass constant (e.g., Refs. [7][8][9]). Others actively resize the aircraft to allow a fair comparison with a conventional reference aircraft (e.g., Refs.…”

mentioning

confidence: 99%

Cross-Validation of Hybrid-Electric Aircraft Sizing Methods

Finger

Vries

Vos

et al. 2022

Journal of Aircraft

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The number of studies on hybrid-electric aircraft is steadily increasing because these configurations can lead to lower operating costs and environmental impact than traditional aircraft. However, due to the lack of reference data of actual hybrid-electric aircraft, the design tools and results are difficult to validate. This paper analyzes the key points that must be validated when developing or implementing a hybrid-electric aircraft design tool by contrasting the assumptions and results of two independently developed sizing methods. An existing 19-seat commuter aircraft is selected as the baseline test case, and both design tools are used to size that aircraft. The aircraft is then resized under consideration of hybrid-electric propulsion technology. This is performed for parallel, serial, and fully electric powertrain architectures. Finally, sensitivity studies are conducted to assess the validity of the basic assumptions and approaches regarding the design of hybrid-electric aircraft. Both methods are found to predict the maximum takeoff mass (MTOM) of the reference aircraft with less than 4% error. The MTOM and payload-range energy efficiency of various (hybrid-) electric configurations are predicted with a maximum difference of approximately 2 and 5%, respectively. The results of this study confirm a correct formulation and implementation of the two methods and provide a reference data set that can be used to benchmark design tools.

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Takeoff and Performance Trade-Offs of Retrofit Distributed Electric Propulsion for Urban Transport

Cited by 38 publications

References 43 publications

Noise of Future Aircraft Propulsion: Sources and Design Considerations

Noise of Future Aircraft Propulsion: Sources and Design Considerations

Flight-Test Validation of a Takeoff Performance Uncertainty Model

Cross-Validation of Hybrid-Electric Aircraft Sizing Methods

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