A Vehicle Design and Optimization Model for On-Demand Aviation

Brown, Arthur; Harris, Wesley L.

doi:10.2514/6.2018-0105

Cited by 39 publications

(42 citation statements)

References 19 publications

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“…This approach, described in more detail by [12], has been shown to be very powerful for large conceptual design space explorations due to it's fast solution times (on the order of a few seconds) and robust optimization capability. Geometric programming has been used to model both electric STOL [3] and VTOL [9] aircraft.…”

Section: Fig 3 a Blown Lift Configuration Based On The Nasa X-57 Wmentioning

confidence: 99%

“…As a consequence, this approach lends itself well to modular subsystem model development; the constraints describing the performance of a motor are the same whether that motor is powering a VTOL lift fan or a STOL blowing motor. The majority of the models can be reused for both configurations, and there are well-developed methods for modeling most major subsystems as GPs, such as those described in [9] for various VTOL configurations.…”

Section: Fig 3 a Blown Lift Configuration Based On The Nasa X-57 Wmentioning

confidence: 99%

“…Preliminary results derived from both STOL and VTOL models will be discussed. As part of this paper, existing literature on STOL aircraft [3][5] [7] [8], VTOL aircraft [9][10] [11], and vehicle design optimization [12] is considered.…”

Section: Introductionmentioning

confidence: 99%

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Model Development for a Comparison of VTOL and STOL Electric Aircraft Using Geometric Programming

Courtin

Hansman

2019

AIAA Aviation 2019 Forum

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There is widespread interest in the use of electric aircraft for short missions in and around urban areas. Most of the vehicle configurations proposed for these missions are electric Vertical Takeo and Landing (VTOL) configurations, due to perceived limitations on the available infrastructure. Several recent studies have proposed electric Short Takeo and Landing (STOL) aircraft with externally blown flaps as viable alternatives for urban operations. One of the claimed benefits of STOL aircraft is increased mission performance (in terms of range, payload, or speed) compared to an VTOL aircraft of the same weight. This study discusses the development of the models necessary to investigates this claim for a variety of possible missions, available infrastructure sizes, and levels of technology. Preliminary mission spaces where STOL or VTOL aircraft are the most weight-e cient choice are identified. The analysis is done using geometric programming, a convex optimization framework that enables rapid design re-optimization over a broad mission space. F Flap deflection Wake circulation µ Wheel friction coe cient ' Velocity potential Horseshoe vortex circulation

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Section: Fig 3 a Blown Lift Configuration Based On The Nasa X-57 Wmentioning

confidence: 99%

Section: Fig 3 a Blown Lift Configuration Based On The Nasa X-57 Wmentioning

confidence: 99%

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Model Development for a Comparison of VTOL and STOL Electric Aircraft Using Geometric Programming

Courtin

Hansman

2019

AIAA Aviation 2019 Forum

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“…Due to the likely use of fixed pitch propellers, low rotor inertia, and the lack of mechanical control linkages these vehicles are not capable of autorotation. The primary benefits of multirotor configurations are low cost due to mechanical simplicity and possible noise benefits relative to helicopters due to additional design freedom to vary disk loading, blade frequency, and tip speed [20].…”

Section: Rotor Liftmentioning

confidence: 99%

Safety Considerations in Emerging Electric Aircraft Architectures

Courtin

Hansman

2018

2018 Aviation Technology, Integration, and Operations Conference

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Safety and certification considerations which impact the design of an emerging new class of small, electric aircraft were investigated. Based on an assessment of the di↵erent emerging aircraft designs, vehicles were grouped based on lifting and propulsive architecture. Likely certification pathways and the associated airworthiness requirements were investigated. Key hazards were identified, and were classified by severity for each architecture group. The key hazards identified were lithium-polymer battery thermal runaway and energy uncertainty, common mode power system failure, and vehicle automation failure. Mitigation strategies for each identified hazard were identified based on current technology and regulatory requirements. These mitigation strategies were assessed for di↵erent vehicle architectures. Aircraft with the ability to controllably glide or autorotate are shown to have lower certification risk.

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“…Brown and Harris [6] applied similar assumptions and expanded on this work by including noise and cost considerations, but considered only one mission profile. This study showed potential noise and efficiency advantages for a compound helicopter configuration over tiltrotor, tiltwing, and lift-and-cruise configurations for UAM applications.…”

Section: Introductionmentioning

confidence: 99%

Configuration Study of Electric Helicopters for Urban Air Mobility

et al. 2021

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There is currently interest in the design of small electric vertical take-off and landing aircraft to alleviate ground traffic and congestion in major urban areas. To support progress in this area, a conceptual design method for single-main-rotor and lift-augmented compound electric helicopters has been developed. The design method was used to investigate the feasible design space for electric helicopters based on varying mission profiles and technology assumptions. Within the feasible design space, it was found that a crossover boundary exists as a function of cruise distance and hover time where the most efficient configuration changes from a single-main-rotor helicopter to a lift-augmented compound helicopter. In general, for longer cruise distances and shorter hover times, the lift-augmented compound helicopter is the more efficient configuration. An additional study was conducted to investigate the potential benefits of decoupling the main rotor from the tail rotor. This study showed that decoupling the main rotor and tail rotor has the potential to reduce the total mission energy required in all cases, allowing for increases in mission distances and hover times on the order of 5% for a given battery size.

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A Vehicle Design and Optimization Model for On-Demand Aviation

Cited by 39 publications

References 19 publications

Model Development for a Comparison of VTOL and STOL Electric Aircraft Using Geometric Programming

Model Development for a Comparison of VTOL and STOL Electric Aircraft Using Geometric Programming

Safety Considerations in Emerging Electric Aircraft Architectures

Configuration Study of Electric Helicopters for Urban Air Mobility

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