含非线性连接的折叠舵全时域多学科耦合分析方法及应用

doi:10.7527/S1000-6893.2023.29461

Abstract

Abstract:

To reduce the storage and transportation space， folding fin configurations are widely used in aircraft. For dynamic systems of folding fin with nonlinear connections， the fin is modeled based on the Mindlin plate theory， and unsteady aerodynamic is simulated by third-order piston theory. The Newmark method and Newton method are used to solve time domain displacement response of the fin with non-linear boundaries. The aeroelastic stability and displacement response of the folding fin of the aircraft are analyzed using the frequency domain and time domain methods. The influence of nonlinear types and parameters of folding mechanisms on aeroelastic behavior is discussed. The results show that the difference of natural frequency and unsteady response results of the established model， and that from the commercial finite element results is less than 2.2%， indicating a good consistency and verifying the correctness of the structural dynamics model. For polynomial nonlinear connection stiffness， it exhibits a convergence trend under critical velocity conditions； for freeplay nonlinearity and bilinear connection stiffness， there is a gradual divergence trend under critical speed conditions. At a 0.5° freeplay condition， the vibration amplitude of bilinear stiffness is significantly smaller than that of freeplay stiffness， indicating that pre-installing torsion springs in freeplay folding mechanisms can significantly reduce vibration response； for asymmetric mixed nonlinear stiffness， this model exhibits a gradually divergent trend under critical velocity conditions. This method has certain guiding significance for the research of fluid structure coupling problems in aircraft and the evaluation of vibration response of folding fin with nonlinear connections under flight conditions.

Key words: folding fin, aeroelasticity, unsteady flow, multi-field coupling, dynamic response

CLC Number:

V414.1

Cheng ZHANG, Haoyuan REN, Tailong SHI, Wendi DAI. Multidisciplinary full-time coupling methods of folding fin containing non-linear connections and their applications[J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(S2): 729461-729461.

Figures/Tables 14

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解类型	弹簧刚度k_spr=100 N∙m/rad			弹簧刚度k_spr=1 000 N∙m/rad
解类型	一阶	二阶	三阶	一阶	二阶	三阶
本文解	0.538 22	10.703	29.093	1.638 1	10.736	29.346
Abaqus解	0.538 05	10.478	29.015	1.633 4	10.518	29.273
相对误差/%	0.031 6	2.147 4	0.268 8	0.287 7	2.072 6	0.249 4

t/s	F=3 N			F=0.5 N
t/s	本文解	Abaqus解	相对误差/%	本文解	Abaqus解	相对误差/%
0.5	0.028 84	0.028 66	0.628 1	0.004 83	0.004 80	0.625 0
1.0	0.090 39	0.090 43	-0.044 2	0.019 05	0.019 08	-0.157 2
1.5	0.052 97	0.052 97	0.000 0	0.039 81	0.039 79	0.050 3
2.0	0.004 00	0.004 02	-0.497 5	0.051 16	0.051 11	0.097 8
2.5	0.011 22	0.011 14	0.718 1	0.038 35	0.038 36	-0.026 1
3.0	0.070 68	0.070 18	0.712 4	0.017 74	0.017 86	-0.671 9

t/s	F_max=3 N			F_max=0.5 N
t/s	本文解	Abaqus解	相对误差/%	本文解	Abaqus解	相对误差/%
1.0	0.036 06	0.035 98	0.222 3	0.006 10	0.006 08	0.328 9
2.0	0.053 92	0.054 17	-0.461 5	0.038 53	0.038 43	0.260 2
5.0	-0.065 11	-0.064 67	0.680 4	-0.053 75	-0.053 89	-0.259 8
8.0	0.093 16	0.093 89	-0.777 5	0.016 83	0.016 82	0.059 5

参数	数值
k/（N∙m∙rad^-1）	10 000
k₁/（N∙m∙rad^-1）	100
k_nl/（N∙m∙rad^-3）	1 000 000
δ/（°）	0.1

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Multidisciplinary full-time coupling methods of folding fin containing non-linear connections and their applications

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