波阵风中的弹性飞机动力学建模与仿真

doi:10.7527/S1000-6893.2022.28214

Abstract

Abstract:

The blast wind generated by the explosion propagates at supersonic or sonic speed and carries high-energy disturbance energy， and can have a significant disturbance or even destructive effect on the aircraft. The model of the blast wind is described， and the method of action between the blast wind and the aircraft is defined. The effect of blast wind on aircraft is treated as the downwash effect， and the unsteady excitation force calculation formula for aircraft in the blast wind is derived by employing the subsonic doublet lattice method. A dynamics model of elastic aircraft in the blast wind is established， and the dynamic response simulation process for flexible aircraft in the blast wind is proposed. The numerical simulation results show that the calculation method of the excitation force due to the blast wind is effective and can meet the requirements of engineering practice. At the center of gravity， the dynamic response results of elastic aircraft and rigid aircraft have no obvious difference. In the wingtip region， the dynamic response results of elastic aircraft and rigid body aircraft show significant difference due to the aeroelastic effect. Since the excitation energy of the blast wind is mainly concentrated below 1 Hz， the elastic modes with relatively high vibration frequencies can be ignored in establishing dynamics model of the elastic aircraft.

Key words: blast wind, flexible aircraft, unsteady aerodynamics, aeroelasticity, dynamic response

CLC Number:

V215.3

Libo WANG, Zhiwei JING, Chu TANG. Modelling and simulation of flexible aircraft in blast wind[J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(17): 228214.

Figures/Tables 27

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Table 1

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Table 2

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Table 3

Dynamic response extremums of aircraft at different locations

水平距离	U_x 极值/（m·s^-1）	U_z 极值/（m·s^-1）	弹性飞机动响应极值				刚体飞机动响应极值
水平距离	U_x 极值/（m·s^-1）	U_z 极值/（m·s^-1）	$Δ α$ /（°）	$Q d o t$ /（（°）·s^-2）	$B n z$	$a w i n g t i p$ /（m·s^-2）	$Δ α$ /（°）	$Q d o t$ /（（°）·s^-2）	$B n z$	$a w i n g t i p$ /（m·s^-2）
X1	37.56	16.82	4.70	-50.67	1.851	37.48	4.67	-51.91	1.936	13.48
X2	32.90	12.54	3.33	-36.95	1.595	28.67	3.30	-37.89	1.664	9.71
X3	29.28	9.66	2.46	-28.79	1.466	25.05	2.45	-29.30	1.505	7.50

Table 3

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模态阶数	频率/Hz	备注
3	0	刚体沉浮模态
5	0	刚体俯仰模态
7	2.239 6	机翼对称一弯模态
9	5.680 8	机翼面内模态
10	7.349 5	机翼对称二弯模态
14	9.685 3	尾翼对称模态
17	13.589 0	副翼对称偏转模态

参数	数值
计算高度/m	6 000
计算马赫数	0.5
波阵风剖面	1-cos，垂直向上
波阵风强度/（m·s^-1）	12
波阵风激励时长/s	0.5
波阵风包围飞机的速度/（m·s^-1）	150

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Modelling and simulation of flexible aircraft in blast wind

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