A Conceptual Design and Optimization Approach for Distributed Electric Propulsion eVTOL Aircraft Based on Ducted-Fan Wing Unit

Ma, Tielin; Wang, Xiangsheng; Qiao, Nanxuan; Zhang, Zilun; Fu, Jingcheng; Bao, Mingmin

doi:10.3390/aerospace9110690

Cited by 8 publications

(9 citation statements)

References 18 publications

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“…As introduced in Section 1, eVTOLs have been the key drivers for starting the concept of UAM services. Such flying vehicles do not produce CO 2 emissions directly during operations; in fact, eVTOLs are equipped with Distributed Electric Propulsion (DEP) engines [61]. However, operational and disposal phases may release CO 2 gas into the atmosphere [62].…”

Section: A Preliminary Analysis Of Co 2 Emissions and Comparison With...mentioning

confidence: 99%

Three-Dimensional Urban Air Networks for Future Urban Air Transport Systems

Ditta,

Postorino

2023

Sustainability

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Advances in new electric aerial vehicles have encouraged research on pioneering Urban Air Mobility (UAM) solutions, which would provide fast service for passengers, goods, and emergencies. From this perspective, some air service scenarios have been identified, such as air taxis, airport shuttles, and intercity services. Such air services should be supported by a suitable urban air network, which should comply with several boundary conditions linked to the specific features of this new type of aerial mobility. This paper proposes an Urban Air Network (UAN) model that includes a third (vertical) dimension and whose aim is to satisfy the basic principle of linking origin/destination pairs, as in usual ground transportation networks, by guaranteeing at the same time safe aerial paths between origin/destination pairs with suitable vehicle separations. The proposed UAN consists of multiple 2D graphs on different layers, which allows for the transfer of aerial vehicles in lower airspace. A suitable cost function has been associated with each UAN link in order to compute the shortest paths connecting the origin/destination pairs. The links in a UAN have a dynamic nature and can be enabled or disabled in consideration of capacity issues. In addition, indirect CO2 emissions linked to aerial vehicles (such as operational and disposal phase charges) have been computed to foresee the potential environmental impacts based on the proposed UAN model. The preliminary results of a test case show encouraging results and provide interesting findings for further advancements.

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Section: A Preliminary Analysis Of Co 2 Emissions and Comparison With...mentioning

confidence: 99%

Three-Dimensional Urban Air Networks for Future Urban Air Transport Systems

Ditta,

Postorino

2023

Sustainability

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“…It is well-known that the mesh structure of solid walls makes it possible to solve many essential technical problems. Thus, the peculiarities of gas-dynamic processes in developing lattice wings [8,9] and aircraft [10][11][12] have been studied.…”

Section: Literature Surveymentioning

confidence: 99%

“…The variants of aircraft jet systems for performing thrust reverse [43] and thrust enhancement [44,45] are considered separately. Work on creating hybrid aircraft engines and jet vehicles is intensifying [9,11,46]. Analyzing the published data, one can notice that different methods for controlling the velocity vector (thrust vector) have been developed and patented today.…”

Section: Literature Surveymentioning

confidence: 99%

Computational Fluid Dynamics (CFD) Simulation of Mesh Jet Devices for Promising Energy-Saving Technologies

et al. 2022

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This paper discusses the development of mesh jet devices for hybrid turbines, including developing Euler's ideas, and considers a new patented version of a mesh jet device designed to create guiding devices for turbines. The research methods are based on simulations using CFD and additive technologies. An intermediate conclusion is that a new scientific direction for the study and creation of mesh jet control systems has been formed as part of developing Euler's ideas. Calculation methods showed possible improvements in the performance of jet devices, including the use of curved tubes proposed by Euler to create turbines. This study shows that at the nozzle or mixing chamber outlet, the jet can deflect by an angle from +180° to -180° within the geometric sphere. This study also shows that the scientific groundwork prepared by Euler is not yet fully understood. The ongoing research mainly focuses on creating multi-mode jet devices designed for control systems for mesh turbomachines. Here, power consumption from an external source can be reduced to save energy. Some results of ongoing studies can also be applied in other industries (for example, when creating hybrid propulsion systems or propulsors). The scientific novelty of this work consists of improving the design methodology of jet machinery and turbomachines. Doi: 10.28991/CEJ-2022-08-12-06 Full Text: PDF

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“…However, compared to wings, propellers suffer from a low weight-power ratio and high noise levels as lift components, and they lack the ability to achieve vertical takeoff and landing as propulsive components [7]. In recent years, researchers have explored integrating lift and thrust into a single system, with one prominent approach being the integration of propulsive systems into the wings or fuselage [8]. This approach allows for coupling wing aerodynamics with the propeller slipstream, reducing induced drag and reducing structural weight, further improving the aircraft's lift-to-drag ratio and flight performance.…”

Section: Introductionmentioning

confidence: 99%

Numerical Simulation and Experimental Study on the Aerodynamics of Propulsive Wing for a Novel Electric Vertical Take-Off and Landing Aircraft

Wang,

Zhang,

et al. 2024

Aerospace

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The electric vertical take-off and landing (eVTOL) aircraft offers the advantages of vertical take-off and landing, environmental cleanliness, and automated control, making it a crucial component of future urban air traffic. As competition intensifies, demands for aircraft performance are escalating, including forward flight speed and payload capacity. The article presents a novel eVTOL design with propulsive wings and establishes methodologies for propulsive wing unsteady numerical simulation and wind tunnel experiments, analyzing its aerodynamic characteristics and lift enhancement mechanism. The results indicate that the cross-flow fan (CFF) provides unique airflow control capabilities, enabling the propulsive wing to achieve remarkably high lift coefficients (exceeding 7.6 in experiments) and propulsion coefficients (exceeding 7.1 in experiments) at extreme angles of attack (30°~40°) and low airspeeds. On the one hand, the CFF effectively controls boundary layer flow, delaying airflow separation at high angles of attack; on the other hand, the rotation of the CFF induces two eccentric vortices, generating vortex-induced lift and propulsion. The aerodynamic performance of the propulsive wing depends on the advance ratio and angle of attack. Typically, both lift and propulsion coefficients increase with the advance ratio, while lift and drag coefficients increase with the angle of attack. The propulsive wing shows significant advantages and prospects for eVTOL aircrafts in the low flight velocity range (0–30 m/s).

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A Conceptual Design and Optimization Approach for Distributed Electric Propulsion eVTOL Aircraft Based on Ducted-Fan Wing Unit

Cited by 8 publications

References 18 publications

Three-Dimensional Urban Air Networks for Future Urban Air Transport Systems

Three-Dimensional Urban Air Networks for Future Urban Air Transport Systems

Computational Fluid Dynamics (CFD) Simulation of Mesh Jet Devices for Promising Energy-Saving Technologies

Numerical Simulation and Experimental Study on the Aerodynamics of Propulsive Wing for a Novel Electric Vertical Take-Off and Landing Aircraft

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