基于热响应特性的高速飞行器轨迹设计与制导

doi:10.7527/S1000-6893.2023.28553

Abstract

Abstract:

To address the problem of unreasonable representation of traditional thermal constraint， an augmented high speed flight vehicle dynamic model including a thermal response model is established by thermal response equation transformation and thermal environment approximate fitting， so as to realize the thermal constraint by outer and inner wall temperature of high speed flight vehicle thermal insulation layer. To overcome the problem that leaping height attenuates quickly in the flight scheme with constant angle of attack， a trajectory design method is proposed based on Height-Velocity （H-V） feedback control. By adjusting the angle of attack with both height and velocity information， the method can realize reciprocating shuttle and leaping flight in large airspace， and further reduce the inner wall temperature of the thermal insulation layer of high speed flight vehicle. For the uncertainty of the upper boundary of the inner wall temperature under the condition of deviation， a nominal trajectory design method with the characteristics of inner wall temperature boundary is proposed. By using the most severe deviation condition of the extreme value as the input， the upper boundary constraint of the inner wall temperature of the high speed flight vehicle thermal insulation layer is realized.For the problem of large tracking error of reciprocating shuttle and leaping flight trajectory in large airspace under the condition of deviation， an online guidance method is proposed based on H-V feedback tracking. By adjusting the bank angle and the angle of attack respectively with height and velocity deviation information， the method can realize accurate tracking of nominal trajectory and satisfy the inner wall temperature upper boundary constraint. Monte Carlo simulation results show that the guidance method proposed has good robustness.

Key words: high speed flight vehicle, thermal constraint, thermal response, trajectory design, online guidance, leaping flight, height-velocity feedback

CLC Number:

V412

Yu XU, Zhengguang HE, Pengfei XUE, Wanchun CHEN, Feng CHEN. Trajectory design and guidance for high speed flight vehicle based on thermal response characteristics[J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(22): 328553-328553.

Figures/Tables 13

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参数	防热层	隔热层
材料	C/C	高效隔热
密度/（kg·m^-3）	1 200	400
比热容/（J·（m³·K）^-1）	1 200	1 000
导热系数/（W·（m·K）^-1）	2	0.05
壁面黑度	0.85
厚度/mm	5	25

类型	参数	场景1	场景2	场景3
初始条件	高度/km	90	70	48
	速度/（m·s^-1）	6 000	6 000	6 000
	航程角/（°）	0	0	0
	轨迹倾角/（°）	0	0	0
	结构温度/K	防隔热层初始均为300
控制变量	攻角/（°）	最佳升阻比攻角均为10
	倾侧角/（°）	0	0	0
终止条件	航程/km	9 000	9 000	9 000

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Trajectory design and guidance for high speed flight vehicle based on thermal response characteristics

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