Systems Engineering and Electronics ›› 2024, Vol. 46 ›› Issue (7): 2481-2489.doi: 10.12305/j.issn.1001-506X.2024.07.30
• Guidance, Navigation and Control • Previous Articles
Flight dynamics and manipulation strategy of compound high speed helicopter
Yang YANG1,*, Weining HUANG2, Yongwen YANG1, Liang XU1, Huasong LI2
- 1. Yangzhou Collaborative Innovation Research Institute of Shenyang Aircraft Design and Research Institute Co.Ltd, Yangzhou 225000, China
2. Shenyang Aircraft Design and Research Institute, Shenyang 110000, China
-
Received:2022-06-20Online:2024-06-28Published:2024-07-02 -
Contact:Yang YANG
CLC Number:
Cite this article
Yang YANG, Weining HUANG, Yongwen YANG, Liang XU, Huasong LI. Flight dynamics and manipulation strategy of compound high speed helicopter[J]. Systems Engineering and Electronics, 2024, 46(7): 2481-2489.
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Fig.1
Overall configuration of compound high-speed unmanned helicopter"
Table 1
Parameters of compound high-speed unmanned helicopter"
| 参数 | 数值 | 参数 | 数值 | |
| 总重/kg | 12.5 | 机翼弦长/mm | 125 | |
| 主旋翼直径/mm | 1 340 | 垂尾展长/mm | 210 | |
| 推力桨半径/mm | 155 | 垂尾平均弦长/mm | 100 | |
| 推力桨力臂/mm | 385 | 平尾展长/mm | 340 | |
| 机翼翼展/mm | 770 | 平尾弦长/mm | 100 |
Fig.2
Interaction of rotor aerodynamic force, induced velocity, and blade flapping motion"
Fig.3
Angle of attack at rotor blade profile"
Fig.4
Schematic diagram of tangential and normal airflow velocity"
Fig.5
Blade flapping motion"
Fig.6
Schematic diagram of leaf element aerodynamics"
Fig.7
Blade shafting"
Fig.8
Schematic diagram of angle of attack, lift and drag of propeller micro-segment"
Fig.9
Schematic diagram of angle of wing position"
Fig.10
Schematic diagram of lift and drag of wing profile"
Table 2
Manipulation strategy in hover/low speed mode"
| 操纵通道 | 操纵机构 |
| 油门1 | 控制旋翼的总距, 实现高度控制 |
| 油门2 | 控制螺旋桨的平均螺距, 实现前飞控制 |
| 航向 | 控制两个螺旋桨的差分螺距, 实现偏航运动 |
| 俯仰 | 控制旋翼的纵向周期变距, 实现俯仰角控制 |
| 滚转 | 控制旋翼的横向周期变距, 实现左/右侧飞 |
Table 3
Manipulation strategy in high speed forward mode"
| 操纵通道 | 操纵机构 |
| 油门1 | - |
| 油门2 | 控制螺旋桨的平均螺距, 实现前飞速度控制 |
| 航向 | 控制方向舵和差分螺距, 实现偏航运动 |
| 俯仰 | 控制升降舵, 使得直升机抬/低头, 实现高度控制 |
| 滚转 | 控制副翼, 使得直升机左/右滚转, 左/右侧飞 |
Fig.11
Allocation diagram of lateral control weight coefficient"
Fig.12
Allocation diagram of longitudinal control weight coefficient"
Fig.13
Allocation diagram of directional control weight coefficient"
Fig.14
Angle of pitch varing with forward speed"
Table 4
Travel and amount of each control rod"
| 操纵杆 | 行程/(°) | 杆操纵量/mm |
| 总距杆 | 0~15 | 6 |
| 横向杆 | -3~3 | 6 |
| 纵向杆 | -3~3 | 6 |
| 航向杆 | -10~10 | 6 |
| 平均螺距杆 | 0~50 | 6 |
Fig.15
Graph of collective pitch lever manipulation with speed"
Fig.16
Graph of rotor and wing's lift with speed"
Fig.17
Graph of lateral lever manipulation with speed"
Fig.18
Graph of antitorque of propeller with speed"
Fig.19
Graph of rotor lateral cyclic pitch and aileron manipulation with speed"
Fig.20
Graph of longitudinal lever manipulation with speed"
Fig.21
Graph of rotor longitudinal cyclic pitch and elevator manipulation with speed"
Fig.22
Graph of directional lever manipulation with speed"
Fig.23
Graph of yaw moment of rotor, propeller and rudder with speed"
Fig.24
Graph of differential pitch of propeller and rudder manipulation with speed"
Fig.25
Graph of mean manipulation of pitch of propeller manipulation of with speed"
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