Acta Aeronautica et Astronautica Sinica ›› 2025, Vol. 46 ›› Issue (S1): 732183.doi: 10.7527/S1000-6893.2025.32183
• Excellent Papers of the 2nd Aerospace Frontiers Conference/the 27th Annual Meeting of the China Association for Science and Technology • Previous Articles
Xiayang ZHANG(
), Bin LUO, Xi CHEN, Tao YANG
CJA
Received:2025-02-14
Revised:2025-02-28
Accepted:2025-05-15
Online:2025-05-28
Published:2025-05-27
Contact:
Xiayang ZHANG
E-mail:zhangxiayang@nuaa.edu.cn
Supported by:CLC Number:
Xiayang ZHANG, Bin LUO, Xi CHEN, Tao YANG. Optimization design of high-efficiency and low-noise rotor layout for quad-tiltrotor aircraft[J]. Acta Aeronautica et Astronautica Sinica, 2025, 46(S1): 732183.
Fig.1
XV-15 tiltrotor aircraft and rotor parameters
Fig.2
Comparison of calculated and experimental values of hover and cruise efficiency for XV-15
Fig.3
Comparison of experimental and calculated values of UH-1H rotor noise
Fig.4
Hover efficiency and surface pressure coefficient contours of forward/rear rotor with different back sweep angles in hover state
Fig.5
Pressure coefficient distribution of forward/rear rotor profile at different back sweep angles of blade tip
Table 1
Effects of different blade tip parameters on aerodynamic characteristics of forward/rear rotors
| 状态 | 前/后掠角/(°) | 前/后掠位置 | 下反角/(°) | 下反位置 | 前/后旋翼前飞效率 |
|---|---|---|---|---|---|
| 1 | 0.451 5/0.570 2 | ||||
| 2 | /15 | /0.9R | 0.458 4/0.572 9 | ||
| 3 | /25 | /0.9R | 0.459 6/0.571 0 | ||
| 4 | /35 | /0.9R | 0.454 1/0.569 4 | ||
| 5 | 5/25 | 0.8R/0.9R | 0.459 8/0.577 3 | ||
| 6 | 10/25 | 0.8R/0.9R | 0.503 2/0.589 1 | ||
| 7 | 15/25 | 0.8R/0.9R | 0.469 0/0.573 5 | ||
| 8 | 10/25 | 0.7R/ | 0.473 0/0.574 4 | ||
| 9 | 10/25 | 0.8R/ | 0.503 2/0.589 1 | ||
| 10 | 10/25 | 0.8R/0.9R | 0.503 2/0.589 1 | ||
| 11 | 10/25 | 0.8R/0.9R | -10 | 0.9R | 0.438 5/0.548 3 |
| 12 | 10/25 | 0.8R/0.9R | 10 | 0.9R | 0.510 8/0.591 3 |
| 13 | 10/25 | 0.8R/0.9R | 20 | 0.9R | 0.489 2/0.576 6 |
| 14 | 10/25 | 0.8R/0.9R | 30 | 0.9R | 0.453 1/0.555 9 |
| 15 | 10/25 | 0.8R/0.9R | 0.503 2/0.589 1 | ||
| 16 | 10/25 | 0.8R/0.9R | 10 | 0.8R | 0.489 0/0.583 0 |
| 17 | 10/25 | 0.8R/0.9R | 10 | 0.9R | 0.510 8/0.591 3 |
Fig.6
Blade surface pressure coefficient contours with different back sweep angles in forward flight state
Fig.7
Hover efficiency and blade surface pressure coefficient contours of forward/rear rotor with different back sweep starting positions
Fig.8
Pressure coefficient distribution of forward/rear rotor profiles (r/R=0.9) and blade upper surface pressure coefficient contours with different forward sweep angles
Fig.9
Blade surface pressure coefficient contours with different forward sweep positions
Fig.10
Hover efficiency of forward/rear rotors and blade surface pressure coefficient contours with different down reverse angles
Fig.11
Hover efficiency of forward/rear rotors and blade surface pressure coefficient contours with different down reverse starting positions
Table 2
Parameters and numbers of different design blades
| 状态 | 编号命名 | 前/后掠位置 | 前/后 掠角/(°) | 下反 位置 | 下反 角/(°) |
|---|---|---|---|---|---|
| 1 | TS01 | /0.9R | /15 | ||
| 2 | TS02 | /0.9R | /25 | ||
| 3 | TS03 | /0.95R | /25 | ||
| 4 | TS04 | /0.85R | /25 | ||
| 5 | QS01 | /0.9R | /25 | ||
| 6 | QS02 | 0.8R /0.9R | 5/25 | ||
| 7 | QS03 | 0.8R /0.9R | 10/25 | ||
| 8 | QS04 | 0.7R /0.9R | 10/25 | ||
| 9 | LS01 | 0.90R | 5 | ||
| 10 | LS02 | 0.90R | 10 | ||
| 11 | LS03 | 0.95R | 10 | ||
| 12 | LS04 | 0.85R | 10 |
Fig.12
Sound pressure time history at blade tip observation points with different back sweep, forward sweep, and down reverse
Fig.13
Blade tip plane shape parameterization and design variable diagram
Fig.14
Optimization results of forward/rear rotor blade tip plane shape
Fig.15
Upper surface pressure coefficient contours and hover efficiency of forward/rear rotors before and after optimization in hover state
Fig.16
Comparison of sound pressure level and noise horizontal plane propagation characteristics at observation points for optimized and original blades in hover state
Table 3
Comparison of cruise efficiency between initial blade and optimized blade
| 桨叶 | 前旋翼巡航效率 | 后旋翼巡航效率 |
|---|---|---|
| 初始桨叶 | 0.453 5 | 0.570 2 |
| 优化桨叶 | 0.499 2 | 0.621 3 |
Fig.17
Upper surface pressure coefficient contours of forward/rear rotors before and after optimization in forward flight state
Fig.18
Comparison of sound pressure level and noise horizontal plane propagation characteristics at observation points for optimized and original blades in forward flight state
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