ACTA AERONAUTICAET ASTRONAUTICA SINICA >
A novel high-efficiency and high-precision momentum source method for distributed ducted fans in aero-propulsion coupling configuration
Received date: 2024-12-30
Revised date: 2025-01-16
Accepted date: 2025-02-25
Online published: 2025-03-06
Supported by
Fundamental Research Funds for the Central Universities(G2024KY0604);Shanxi Province Science and Technology Major Project “Unveiling the List and Leading the Team”(202101120401007);Northwestern Polytechnical University Doctoral Dissertation Innovation Fund(CX2023085)
The distributed ducted fan-wing integration configuration presents a challenging aerodynamic problem due to its complex aerodynamic coupling effects, making accurate and efficient aerodynamic performance predictions difficult. Therefore, this paper proposes a novel momentum source method for the distributed ducted fan, based on the Reynolds-Averaged Navier-Stokes (RANS) equations, which fully accounts for the multi-component aerodynamic-propulsion coupling effects. By simplifying the flow field calculation of the fan’s rotor and stator blades, this method significantly improves computational efficiency while accurately capturing the coupling effects of the wing boundary layer viscous effects, intake acceleration effects, and exhaust wake; thereby, providing precise predictions of the aerodynamic performance for the wing, intake, and exhaust. Specifically, in this method, the RANS equations are solved using the Multiple Reference Frame (MRF) approach to obtain a quasi-steady flow field. Then, the three-directional velocity, turbulent kinetic energy, and turbulence eddy dissipation at the fan’s front and rear interfaces are extracted and imposed as boundary conditions to the fan-less configuration to simulate the propulsion effects of the ducted fan. In the single ducted fan-wing section coupling configuration test, the flow field information extracted at a 4° angle of attack can accurately predict the aerodynamic performance of the same configuration within a 16° angle of attack range, as well as the aerodynamic performance of different airfoil configurations. Compared with the MRF method, the proposed method shows a relative error in lift coefficient of less than 2% and in drag coefficient of less than 4.5% in the 2°-16° angle of attack range, demonstrating superior accuracy over traditional momentum source methods while reducing computational cost by more than 90%. In the distributed ducted fan-wing coupling configuration test, this method also demonstrates high accuracy and significant efficiency advantages, providing an efficient and reliable tool for aerodynamic performance prediction of distributed ducted fan configurations.
Kai HAN , Junqiang BAI , Shaodong FENG , Shilong YU , Junwei HUANG , Chu TANG , Yasong QIU . A novel high-efficiency and high-precision momentum source method for distributed ducted fans in aero-propulsion coupling configuration[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2025 , 46(17) : 131728 -131728 . DOI: 10.7527/S1000-6893.2025.31728
| [1] | 邓景辉. 电动垂直起降飞行器的技术现状与发展[J]. 航空学报, 2024, 45(5): 529937. |
| DENG J H. Technical status and development of electric vertical take-off and landing aircraft[J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(5): 529937 (in Chinese). | |
| [2] | 孙侠生, 程文渊, 穆作栋, 等. 电动飞机发展白皮书[J]. 航空科学技术, 2019, 30(11): 1-7. |
| SUN Xiasheng, CHENG W Y, MU Z D, et al. White paper on the development of electric aircraft[J]. Aeronautical Science & Technology, 2019, 30(11): 1-7 (in Chinese). | |
| [3] | AKTURK A, CAMCI C. Tip clearance investigation of a ducted fan used in VTOL unmanned aerial vehicles—Part Ⅰ: Baseline experiments and computational validation[J]. Journal of Turbomachinery, 2014, 136(2): 021004. |
| [4] | KIM H D, PERRY A T, ANSELL P J. A review of distributed electric propulsion concepts for air vehicle technology[C]∥2018 AIAA/IEEE Electric Aircraft Technologies Symposium. Reston: AIAA, 2018. |
| [5] | PERRY A T, ANSELL P J, KERHO M F. Aero-propulsive and propulsor cross-coupling effects on a distributed propulsion system[J]. Journal of Aircraft, 2018, 55(6): 2414-2426. |
| [6] | HIRONO F C, MARTINEZ A T, ELLIOTT A, et al. Aeroacoustic design and optimisation of an all-electric ducted fan propulsion module for low-noise impact[C]∥28th AIAA/CEAS Aeroacoustics 2022 Conference. Reston: AIAA, 2022. |
| [7] | LIOU M F, GRONSTAL D, KIM H J, et al. Aerodynamic design of the hybrid wing body with nacelle: N3-X propulsion-airframe configuration[C]∥34th AIAA Applied Aerodynamics Conference. Reston: AIAA, 2016. |
| [8] | SWAMINATHAN N, REDDY S R P, RAJASHEKARA K, et al. Flying cars and eVTOLs: technology advancements, powertrain architectures, and design[J]. IEEE Transactions on Transportation Electrification, 2022, 8(4): 4105-4117. |
| [9] | SCHMOLLGRUBER P, DONJAT D, RIDEL M, et al. Multidisciplinary design and performance of the ONERA hybrid electric distributed propulsion concept (DRAGON)[C]∥AIAA Scitech 2020 Forum. Reston: AIAA, 2020. |
| [10] | BACCHINI A, CESTINO E. Electric VTOL configurations comparison[J]. Aerospace, 2019, 6(3): 26. |
| [11] | 钱仲焱, 白俊强, 邱亚松, 等. 集成有分布式涵道风扇的机翼和电动飞机: CN115489716A[P]. 2022-12-20. |
| QIAN Z Y, BAI J Q, QIU Y S, et al. Integrated distributed ducted fan wing and electric aircraft: CN115489716A[P]. 2022-12-20. | |
| [12] | 达兴亚, 李永红, 熊能, 等. 翼身融合运输机分布式电推进系统设计及油耗评估[J]. 航空动力学报, 2019, 34(10): 2158-2166. |
| DA X Y, LI Y H, XIONG N, et al. Distributed electrical propulsion system design and fuel consumption evaluation for a blended-wing-body transport[J]. Journal of Aerospace Power, 2019, 34(10): 2158-2166 (in Chinese). | |
| [13] | DE VRIES R. Hybrid-electric aircraft with over-the-wing distributed propulsion: Aerodynamic performance and conceptual design[D]. Delft: Delft University of Technology, 2022. |
| [14] | 王科雷, 周洲, 郭佳豪, 等. 分布式动力翼前飞状态动力/气动耦合特性[J]. 航空学报, 2024, 45(2): 128643. |
| WANG K L, ZHOU Z, GUOJIA H, et al. Propulsive/aerodynamic coupled characteristics of distributed-propulsion-wing during forward flight[J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(2): 128643 (in Chinese). | |
| [15] | UPADHYAY P, ZAMAN K B M Q. Effect of incoming boundary-layer characteristics on performance of a distributed propulsion system[J]. Journal of Propulsion and Power, 2021, 37(5): 701-712. |
| [16] | 王海童, 王掩刚, 周芳, 等. 基于面元法的分布式涵道推进系统进气道优化设计[J]. 推进技术, 2021, 42(11): 2465-2473. |
| WANG H T, WANG Y G, ZHOU F, et al. Optimization design of inlet for distributed ducted fan propulsion system based on panel method[J]. Journal of Propulsion Technology, 2021, 42(11): 2465-2473 (in Chinese). | |
| [17] | 刘乾, 刘汉儒, 尚珣, 等. 电推进涵道风扇气动快速求解方法及性能分析研究[J]. 推进技术, 2024, 45(3): 136-143. |
| LIU Q, LIU H R, SHANG X, et al. Fast aerodynamic prediction method and performance of electrically driven duct fan[J]. Journal of Propulsion Technology, 2024, 45(3): 136-143 (in Chinese). | |
| [18] | KIM H, LIOU M S. Flow simulation and optimal shape design of N3-X hybrid wing body configuration using a body force method[J]. Aerospace Science and Technology, 2017, 71: 661-674. |
| [19] | 张阳, 周洲, 王科雷, 等. 分布式动力系统参数对翼身融合布局无人机气动特性的影响[J]. 西北工业大学学报, 2021, 39(1): 17-26. |
| ZHANG Y, ZHOU Z, WANG K L. Influences of distributed propulsion system parameters on aerodynamic characteristics of a BLI-BWB UAV[J]. Journal of Northwestern Polytechnical University, 2021, 39(1): 17-26. (in Chinese). | |
| [20] | CUI R, LI Q S, PAN T Y, et al. Streamwise-body-force-model for rapid simulation combining internal and external flow fields[J]. Chinese Journal of Aeronautics, 2016, 29(5): 1205-1212. |
| [21] | 邱奥祥, 桑为民, 张桐, 等. 翼身融合布局飞机分布式推进边界层吸入效应影响研究[J]. 力学学报, 2024, 56(8): 2448-2467. |
| QIU A X, SANG W M, ZHANG T, et al. Research on the effect of boundary layer ingestion of blended-wing-body aircraft with distributed propulsion[J]. Chinese Journal of Theoretical and Applied Mechanics, 2024, 56(8): 2448-2467 (in Chinese). | |
| [22] | 徐诸霖, 达兴亚, 范召林, 等. 一种适用于进气道/风扇一体化计算的体积力模型[J]. 推进技术, 2019, 40(4): 732-740. |
| XU Z L, DA X Y, FAN Z L, et al. A body force model for the computation of inlet and fan integration[J]. Journal of Propulsion Technology, 2019, 40(4): 732-740 (in Chinese). | |
| [23] | MENTER F. Zonal two equation k-w turbulence models for aerodynamic flows[C]∥23rd Fluid Dynamics, Plasmadynamics, and Lasers Conference. Reston: AIAA, 1993. |
| [24] | 金奕星. 螺旋桨滑流的转/静交界面数值模拟方法研究[D]. 南京: 南京航空航天大学, 2015: 45-61. |
| JIN Y X. Study on numerical simulation method of rotating/static interface of propeller slipstream[D]. Nanjing: Nanjing University of Aeronautics and Astronautics, 2015: 45-61 (in Chinese). | |
| [25] | DOGRUOZ M B, SHANKARAN G. Computations with the multiple reference frame technique: Flow and temperature fields downstream of an axial fan[J]. Numerical Heat Transfer, Part A: Applications, 2017, 71(5): 488-510. |
| [26] | SILVA P A S F, TSOUTSANIS P, ANTONIADIS A F. Simple multiple reference frame for high-order solution of hovering rotors with and without ground effect[J]. Aerospace Science and Technology, 2021, 111: 106518. |
| [27] | 韩凯, 白俊强, 邱亚松, 等. 涵道螺旋桨设计变量的影响及其流动机理[J]. 航空学报, 2022, 43(7): 125466. |
| HAN K, BAI J Q, QIU Y S, et al. Aerodynamic performance and flow mechanism of ducted propeller with different design variables[J]. Acta Aeronautica et Astronautica Sinica, 2022, 43(7): 125466 (in Chinese). | |
| [28] | 王海童. 分布式升力系统优化设计及试验研究[D]. 西安: 西北工业大学, 2021: 51-53. |
| WANG H T. Optimal design and experimental study of distributed lift system[D]. Xi’an: Northwestern Polytechnical University, 2021: 51-53 (in Chinese). | |
| [29] | LENG Y C, YOO H, JARDIN T, et al. Aerodynamic modeling of propeller forces and moments at high angle of incidence[C]∥AIAA Scitech 2019 Forum. Reston: AIAA, 2019. |
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