多源激励下航空发动机L型管路动力学建模与验证

doi:10.7527/S1000-6893.2023.29375

Abstract

Abstract:

From the perspective of analytical analysis， a dynamic model of an L-shaped pipeline in aero-engine with clamp constraints under multi-source excitations is established， with consideration of base random vibration excitation and fluid pressure pulsation excitation loads. Based on the Timoshenko beam theory and the transfer matrix method， the vibration equilibrium equations of such a pipeline system in the axial， transverse， and axial torsion directions are derived， with the inherent properties of the pipeline system filled with the fluid solved. A multiple-frequency energy method in the frequency domain is proposed to construct the excitation force of the fluid pressure pulsation function. Moreover， a virtual excitation method is adopted to simulate the base random vibration load. After the two kinds of excitation loads are added to the equilibrium equations， the vibration response of the pipeline is successfully solved under the above complex multi-source excitation conditions. Finally， a vibration test system of pipeline systems in aero-engines with multi-source excitation is established， and validation tests are performed under different excitation conditions. The effectiveness of the proposed theoretical model and its analysis results is proved， providing important reference for the prediction of dynamic response and anti-vibration design of various pipeline systems in aerospace under complex excitation loads.

Key words: base random vibration excitation, fluid pressure pulsation excitation, aero-engine, L-shaped pipeline, dynamics modeling

CLC Number:

V257

Hui LI, Jianfei GU, Jinan LI, Zhanbin SUN, Kaihua SUN, Xiaochuan LIU, Xin WANG, Bingjie ZHANG, Xiangping WANG, Hui MA. Dynamics modeling and validation of L-shaped pipeline in aero-engine under multi-source excitations[J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(12): 229375-229375.

Figures/Tables 10

Fig.1

Fig.2

Fig.3

Fig.4

Table 1

Material parameters of L-shaped pipeline and clamps

类型	参数值
卡箍和管路材料参数	$E = 1.9 × 105$ MPa， $μ$ = 0.3， $ρ$ =7 960 kg/m³
卡箍刚度参数	$K t r x = 3 × 107$ N/m， $K t r y = 5 × 107$ N/m $K t r z = 1 × 107$ N/m， $K t w x = 30$ N/rad， $K t w y = 50$ N/rad， $K t w z = 10$ N/rad

Table 1

Fig.5

Table 2

Fig.6

Fig.7

Table 3

References 33

1	LI X， WANG S P. Flow field and pressure loss analysis of junction and its structure optimization of aircraft hydraulic pipe system［J］. Chinese Journal of Aeronautics， 2013， 26（4）： 1080-1092.
2	汪博，高培鑫，马辉，等. 航空发动机管路系统动力学特性综述［J］. 航空学报， 2022， 43（5）： 025332.
	WANG B， GAO P X， MA H， et al. Dynamic characteristics of aero-engine pipeline system： Review［J］. Acta Aeronauticaet Astronautica Sinica， 2022， 43（5）： 025332 （in Chinese）.
3	EMADI K， EHSANI M. Aircraft power systems： Technology， state of the art， and future trends［J］. IEEE Aerospace and Electronic Systems Magazine， 2000， 15（1）： 28-32.
4	YAN Y Y， CHAI M J. Sealing failure and fretting fatigue behavior of fittings induced by pipeline vibration［J］. International Journal of Fatigue， 2020， 136： 105602.
5	GAO P X， YU T， ZHANG Y L， et al. Vibration analysis and control technologies of hydraulic pipeline system in aircraft： Review［J］. Chinese Journal of Aeronautics， 2021， 34（4）： 83-114.
6	LI J T， DENG H， JIANG W J. Dynamic response and vibration suppression of a cantilevered pipe conveying fluid under periodic excitation［J］. Journal of Vibration and Control， 2019， 25（11）： 1695-1705.
7	GAO P X， ZHAI J Y， YAN Y Y， et al. A model reduction approach for the vibration analysis of hydraulic pipeline system in aircraft［J］. Aerospace Science and Technology， 2016， 49： 144-153.
8	TIAN J L， YUAN C F， YANG L， et al. The vibration characteristics analysis of pipeline under the action of gas pressure pulsation coupling［J］. Journal of Failure Analysis and Prevention， 2016， 16（3）： 499-505.
9	MEHMOOD Z， HAMEED A， JAVED A， et al. Analysis of premature failure of aircraft hydraulic pipes［J］. Engineering Failure Analysis， 2020， 109： 104356.
10	ZHAI H B， WU Z Y， LIU Y S， et al. Dynamic response of pipeline conveying fluid to random excitation［J］. Nuclear Engineering and Design， 2011， 241（8）： 2744-2749.
11	权凌霄，李东，王鸿鑫，等. 弹支航空液压管路的加速度载荷响应分析［J］. 振动与冲击， 2016， 35（21）： 209-213.
	QUAN L X， LI D， WANG H X， et al. Acceleration load response analysis for elastically supported aviation hydraulic pipe-lines［J］. Journal of Vibration and Shock， 2016， 35（21）： 209-213 （in Chinese）.
12	李占营，王建军，邱明星. 简谐激励下柔性卡箍支承管路系统响应［J］. 航空动力学报， 2017， 32（11）： 2705-2712.
	LI Z Y， WANG J J， QIU M X. Responses of pipe system with flexible clamp under harmonic excitation［J］. Journal of Aerospace Power， 2017， 32（11）： 2705-2712 （in Chinese）.
13	SAZESH S， SHAMS S. Vibration analysis of cantilever pipe conveying fluid under distributed random excitation［J］. Journal of Fluids and Structures， 2019， 87： 84-101.
14	CHAI Q D， ZENG J， MA H， et al. A dynamic modeling approach for nonlinear vibration analysis of the L-type pipeline system with clamps［J］. Chinese Journal of Aeronautics， 2020， 33（12）： 3253-3265.
15	QU W， ZHANG H L， LI W， et al. Dynamic characteristics of a hydraulic curved pipe subjected to random vibration［J］. International Journal of Pressure Vessels and Piping， 2021， 193： 104442.
16	LI W， ZHANG H L， QU W. Stress response of a straight hydraulic pipe under random vibration［J］. International Journal of Pressure Vessels and Piping， 2021， 194： 104502.
17	WIGGERT D C， HATFIELDF J， STUCKENBRUCK S. Analysis of liquid and structural transients in piping by the method of characteristics［J］. Journal of Fluids Engineering， 1987， 109（2）： 161-165.
18	LIN Y H， TSAI Y K. Nonlinear vibrations of Timoshenko pipes conveying fluid［J］. International Journal of Solids and Structures， 1997， 34（23）： 2945-2956.
19	WU J S， SHIH P Y. The dynamic analysis of a multispan fluid-conveying pipe subjected to external load［J］. Journal of Sound and Vibration， 2001， 239（2）： 201-215.
20	OUYANG X P， GAO F， YANG H Y， et al. Modal analysis of the aircraft hydraulic-system pipeline［J］. Journal of Aircraft， 2012， 49（4）： 1168-1174.
21	ŁUCZKO J， CZERWIŃSKI A. Parametric vibrations of flexible hoses excited by a pulsating fluid flow， Part I： Modelling， solution method and simulation［J］. Journal of Fluids and Structures， 2015， 55： 155-173.
22	CZERWIŃSKI A， ŁUCZKO J. Parametric vibrations of flexible hoses excited by a pulsating fluid flow， Part II： Experimental research［J］. Journal of Fluids and Structures， 2015， 55： 174-190.
23	CZERWIŃSKI A， ŁUCZKO J. Nonlinear vibrations of planar curved pipes conveying fluid［J］. Journal of Sound and Vibration， 2021， 501： 116054.
24	GU Z J， BAI C Q， ZHANG H Y. Nonlinear dynamic modeling and fluid-mechanism interaction analysis of reciprocating pump-pipeline system［J］. Proceedings of the Institution of Mechanical Engineers， Part I： Journal of Systems and Control Engineering， 2021， 235（6）： 869-880.
25	GAO P X， QUH Q， ZHANG Y L， et al. Experimental and numerical vibration analysis of hydraulic pipeline system under multiexcitations［J］. Shock and Vibration， 2020， 2020：3598374.
26	杨庆俊，董日治，罗小梅，等. 泵源与机体共同激励下液压管路振动特性［J］. 液压与气动， 2021，45（6）： 163-170.
	YANG Q J， DONG R Z， LUO X M， et al. Vibration characteristics of hydraulic pipe network under multi-source excitation［J］. Chinese Hydraulics & Pneumatics， 2021， 45（6）： 163-170 （in Chinese）.
27	李帅军. 管路系统流固耦合动力学计算及特性分析［D］. 哈尔滨：哈尔滨工程大学， 2015.
	LI S J. Dynamic analysis of fluid-structure interaction of pipe systems conveying fluid［D］. Harbin： Harbin Engineering University， 2015 （in Chinese）.
28	CHEN G H， ZHOU J L， YANG D X. Benchmark solutions of stationary random vibration for rectangular thin plate based on discrete analytical method［J］. Probabilistic Engineering Mechanics， 2017， 50： 17-24.
29	陈庚超. 基于分段函数的随机振动功率谱密度值计算［J］. 载人航天， 2011， 17（1）： 45-46， 57.
	CHEN G C. Study on random vibration power spectrum density（PSD） value calculation based on segmental function［J］. Manned Spaceflight， 2011， 17（1）： 45-46， 57 （in Chinese）.
30	张义民，李鹤. 机械振动学基础［M］. 北京：高等教育出版社， 2010.
	ZHANG Y M， LI H. Fundamentals of mechanical vibration［M］. Beijing： Higher Education Press， 2010 （in Chinese）.
31	祁仁俊. 液压系统压力脉动的机理［J］. 同济大学学报（自然科学版）， 2001， 29（9）： 1017-1022.
	QI R J. Mechanism research of pressure ripple for hydraulic systems［J］. Journal of Tongji University， 2001， 29（9）： 1017-1022 （in Chinese）.
32	LI S J， LIU G M， KONG W T. Vibration analysis of pipes conveying fluid by transfer matrix method［J］. Nuclear Engineering and Design， 2014， 266： 78-88.
33	LI H， XUE P C， RONG W C， et al. Identification of mechanical parameters of fiber-reinforced composites by frequency response function approximation method［J］. Science Progress， 2020， 103（1）： 36850419878033.

阶次	固有频率/Hz		误差/%
阶次	测试	计算	误差/%
1	103.7	104.0	0.3
2	333.3	318.4	4.5
3	719.4	734.8	2.1
4	1 022.7	1 045.6	2.2

压力/MPa	振动加速度响应的均方根值/g		偏差/%
压力/MPa	理论计算	实验测试	偏差/%
3	6.7	7.5	10.8
6	4.68	4.22	10.9
9	4.62	4.18	10.6

[1]	Zeyong YIN, Gaiqi LI, Jiancheng SHI, Yueqian YIN. Concept, method and practice of advanced versatile core engine derivative [J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(7): 29713-029713.
[2]	Weina HUANG, Fangjuan LI, Hongbin QI. Preliminary investigation and thoughts on aero-engine digital engineering development [J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(5): 529693-529693.
[3]	Ruixian MA, Xin WANG, Kaiming WANG, Bin LI, Mingfu LIAO, Siji WANG. Rubbing experimental study on labyrinth and rubber⁃coated case for aero⁃engines [J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(4): 628350-628350.
[4]	Yuan XIAO, Kun FENG, Minghui HU, Zhinong JIANG. Extraction method for unsteady vibration components of aero-engine rotors [J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(3): 228158-228158.
[5]	Yong SHANG, Huijun YANG, Yang FENG, Changzhen ZHANG, Yanling PEI, Shengkai GONG. Research progress of smart thermal barrier coatings based on phosphorescence temperature measurement technology [J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(12): 29341-029341.
[6]	Yingjiao HU, Feng XU, Zhijun YANG. Overview of aero-engine ice testing capability [J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(S2): 729449-729449.
[7]	Neng WAN, Qixin ZHUANG, Yanheng GUO, Zhiyong CHANG, Dao WANG. Sampling strategy for on-machine measurement of aero-engine blade under constraint of fitting accuracy [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2023, 44(7): 427151-427151.
[8]	Miaodong ZHAO, Dianyin HU, Jianxing MAO, Haihe SUN, Shiyong QIN, Yuanxing GU, Rongqiao WANG, Tengyue TIAN, Lin YAN, Zhixing XIAO. Simulating specimen for low cycle fatigue of aero-engine disc: Design and experiment [J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(18): 228320-228320.
[9]	Zhiguang SHI, Yujie YANG, Zongyu ZUO. Multi-element coupled modeling and simulation for multi-capsule near-space airships [J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(16): 228451-228451.
[10]	Xiaofeng SUN, Guangyu ZHANG, Xiaoyu WANG, Lei LI, Xiangyang DENG, Ronghui CHENG. Research progress in aero-engine combustion instability prediction and control [J]. Acta Aeronautica et Astronautica Sinica, 2023, 44(14): 628733-628733.
[11]	Pei PENG, Yongping ZHAO, Yuwei WANG. New method for automatic and rapid mining of aero-engine operating patterns [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2023, 44(11): 327659-327659.
[12]	Wanli ZHAO, Yingqing GUO, Kejie XU, Cansen WANG, Haojie YING, Xinxin TAO. Review of key technologies for fault diagnosis and accommodation for multi⁃electric distributed engine control system [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2023, 44(10): 27519-027519.
[13]	LIU Jiaqi, FENG Yunwen, LU Cheng, XUE Xiaofeng, PAN Weihuang. Safety analysis of aero-engine operation based on intelligent neural network [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2022, 43(9): 625375-625375.
[14]	ZHANG Shuo, LIU Zhiwen. Structured Bayesian sparse representation of aero-engine bearing failures [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2022, 43(9): 625056-625056.
[15]	ZHANG Zhongqiang, ZHANG Xin, WANG Jiaxu, LIU Zhiwen. Reweighted kurtogram for aero-engine fault diagnosis [J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2022, 43(9): 625445-625445.

Dynamics modeling and validation of L-shaped pipeline in aero-engine under multi-source excitations

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 10

References 33

Related Articles 15

Recommended Articles

Metrics

Comments