基于缩比模型的薄壁结构声振响应等效研究

doi:10.7527/S1000-6893.2021.25146

固体力学与飞行器总体设计

本期目录 | 过刊浏览 | 高级检索

前一篇 | 后一篇

基于缩比模型的薄壁结构声振响应等效研究

赵小见¹, 邵晓¹, 杨明绥²

1. 北京理工大学宇航学院, 北京 100081;
2. 中国航发沈阳发动机研究所, 沈阳 110015

收稿日期:2020-12-23 修回日期:2021-01-12 出版日期:2022-03-15 发布日期:2021-02-02
通讯作者: 赵小见 E-mail:zhaox0714@126.com
基金资助:
国家自然科学基金（52076014，91952302）

Equivalence of vibro-acoustic response based on scaled thin-walled structures

ZHAO Xiaojian¹, SHAO Xiao¹, YANG Mingsui²

1. School of Aerospace Engineering, Beijing Institute of Technology, Beijing 100081, China;
2. Shengyang Engine Research Institute, AECC, Shenyang 110015, China

Received:2020-12-23 Revised:2021-01-12 Online:2022-03-15 Published:2021-02-02
Supported by:
National Natural Science Foundation of China (52076014,91952302)

摘要/Abstract

摘要： 声振试验是研究强噪声作用下结构动力学响应的一种有效方法。然而，高声强、宽频率噪声环境的试验室模拟是声振试验面临的挑战之一。为了降低声振动试验对严酷噪声环境的依赖性，本文提出了一种等效方法。根据该等效方法，缩比模型在等效外力作用下，可获得和全尺寸结构完全一致的结构响应。提出的等效方法可以评估不同类型的噪声激励，包括集中力、点声源、面声源和混响声场等激发的结构振动，而不需要模拟更宽频率的外激励。为了验证该等效方法的可靠性，研究对不同方法，包括数值计算、地面试验和等效方法等获得的结构频域响应结果进行对比，对比结果表明基于缩比模型的等效方法能准确地预测全尺寸结构的动载荷响应。此外，本研究还讨论了不同支撑边界和材料效应对等效方法的影响，进一步扩展了等效方法的适用范围。

关键词: 等效方法, 声振, 薄壁结构, 动响应, 宽频

Abstract: Vibro-acoustic testing is an effective approach to the investigation of structural dynamics subject to high-intensity acoustic environments.However, creating a high-intensity and broad frequency acoustic environment remains a challenge in the laboratory.To reduce the dependence on a severe environment during a vibro-acoustic test, we propose an equivalence technique to obtain a completely consistent dynamic response using a scaled model subject to equivalent external forces.This technique can assess the structural vibration caused by different external forces, including concentrated forces, monopole surface sound sources and reverberation field.To validate the equivalence method, we compare the results achieved by different methods, including numerical computations, ground measurements and the equivalence method, proving that the equivalence method based on a scale model can better predict the dynamic response of the prototype.In addition, the effects of the supporting boundary and material effect on the equivalence method are also discussed and the application scope of the equivalence method further extended.

Key words: equivalence method, vibro-acoustic, thin-walled structure, dynamic response, broadband

中图分类号:

赵小见, 邵晓, 杨明绥. 基于缩比模型的薄壁结构声振响应等效研究[J]. 航空学报, 2022, 43(3): 225146-225146.

ZHAO Xiaojian, SHAO Xiao, YANG Mingsui. Equivalence of vibro-acoustic response based on scaled thin-walled structures[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2022, 43(3): 225146-225146.

参考文献

[1] 张颖哲, 倪大明, Incheol LEE, 等.缩比发动机喷嘴热喷流噪声试验[J].航空学报, 2018, 39(12):122446. ZHANG Y Z, NI D M, LEE I, et al.Test on hot jet noise of scaled engine nozzle[J].Acta Aeronautica et Astronautica Sinica, 2018, 39(12):122446(in Chinese).
[2] 童福林, 周桂宇, 孙东, 等.膨胀效应对激波/湍流边界层干扰的影响[J].航空学报, 2020, 41(9):123731. TONG F L, ZHOU G Y, SUN D, et al.Expansion effect on shock wave and turbulent boundary layerinteractions[J].Acta Aeronautica et Astronautica Sinica, 2020, 41(9):123731(in Chinese).
[3] WALLACE C E.Structural response and acoustic fatigue for random progressive waves and diffuse fields[J].Journal of Spacecraft and Rockets, 1985, 22(3):340-344.
[4] STEINWOLF A, WHITE R G, WOLFE H F.Simulation of jet-noise excitation in an acoustic progressive wave tube facility[J].The Journal of the Acoustical Society of America, 2001, 109(3):1043-1052.
[5] HOLLKAMP J, GORDON R.The importance of structural-acoustic coupling in progressive wavetesting[C]//52nd AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics and Materials Conference.Reston:AIAA, 2011.
[6] PITT D M, LIGUORE S L, THOMAS M J, et al.Thermal acoustic test and analysis model updating and correlation[C]//54th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference.Reston:AIAA, 2013.
[7] POLITO T, MARULO F.Probabilistic finite elements for vibroacoustic applications[C]//12th AIAA/CEAS Aeroacoustics Conference (27th AIAA Aeroacoustics Conference).Reston:AIAA, 2006.
[8] SESTIERI A, CARCATERRA A.Vibroacoustic:The challenges of a mission impossible?[J].Mechanical Systems and Signal Processing, 2013, 34(1-2):1-18.
[9] SAITO A, NISHIKAWA Y, YAMASAKI S, et al.Equivalent orthotropic elastic moduli identification method for laminated electrical steel sheets[J].Mechanical Systems and Signal Processing, 2016, 72-73:607-628.
[10] LIU Y, CATALAN J C.External mean flow influence on sound transmission through finite clamped double-wall sandwich panels[J].Journal of Sound and Vibration, 2017, 405:269-286.
[11] ALLEN M J, VLAHOPOULOS N.Integration of finite element and boundary element methods for calculating the radiated sound from a randomly excited structure[J].Computers & Structures, 2000, 77(2):155-169.
[12] CHUNG Y, FOIST B.Evaluation of acoustic component coupling to the vibroacoustic response predictions[C]//48th AIAA/ASME/ASCE/AHS/ASC Structures, Structural Dynamics, and Materials Conference.Reston:AIAA, 2007.
[13] XIE G, THOMPSON D J, JONES C J C.A modelling approach for the vibroacousticbehaviour of aluminium extrusions used in railway vehicles[J].Journal of Sound and Vibration, 2006, 293(3-5):921-932.
[14] CULLA A, D'AMBROGIO W, FREGOLENT A, et al.Vibroacoustic optimization using a statistical energy analysis model[J].Journal of Sound and Vibration, 2016, 375:102-114.
[15] HAN F, BERNHARD R J, MONGEAU L G.Predictionof flow-induced structural vibration and sound radiation using energy flow analysis[J].Journal of Sound and Vibration, 1999, 227(4):685-709.
[16] DURANT C, ROBERT G, FILIPPI P J T, et al.Vibroacoustic response of a thin cylindrical shell excited by a turbulent internal flow:Comparison between numerical prediction and experimentation[J].Journal of Sound and Vibration, 2000, 229(5):1115-1155.
[17] MEYER V, MAXIT L, RENOU Y, et al.Experimental investigation of the influence of internal frames on the vibroacoustic behavior of a stiffened cylindrical shell using wavenumber analysis[J].Mechanical Systems and Signal Processing, 2017, 93:104-117.
[18] SOEDEL W.Similitude approximations for vibrating thin shells[J].The Journal of the Acoustical Society of America, 1971, 49(5B):1535-1541.
[19] REZAEEPAZHAND J, SIMITSES G J.Design of scaled down models for predicting shell vibrationrepsonse[J].Journal of Sound and Vibration, 1996, 195(2):301-311.
[20] ROSA S D, FRANCO F, RICCI F, et al.First assessment of the scaling procedure for the evaluation of the damped structural response[J].Journal of Sound and Vibration, 1997, 204(3):540-548.
[21] HANSON D, RANDALL R B, ANTONI J, et al.Cyclostationarity and the cepstrum for operational modal analysis of MIMO systems-Part II:obtaining scaled mode shapes through finite element model updating[J].Mechanical Systems and Signal Processing, 2007, 21(6):2459-2473.
[22] SINGHATANADGID P, NA SONGKHLA A.An experimental investigation into the use of scaling laws for predicting vibration responses of rectangular thinplates[J].Journal of Sound and Vibration, 2008, 311(1-2):314-327.
[23] ADAMS C, BÖS J, SLOMSKI E M, et al.Scaling laws obtained from a sensitivity analysis and applied to thin vibrating structures[J].Mechanical Systems and Signal Processing, 2018, 110:590-610.
[24] FRANCO F, ROBIN O, CIAPPI E, et al.Similitude laws for the structural response of flat plates under a turbulent boundary layer excitation[J].Mechanical Systems and Signal Processing, 2019, 129:590-613.
[25] ZHAO X J, AI B C.Predicting the structural response induced by turbulent boundary layer in wind tunnel[J].AIAA Journal, 2016, 55(4):1221-1229.
[26] ZHAO X J, CHEN H B, LEI J M, et al.A scaling procedure for measuring thermal structural vibration generated by wall pressure fluctuation[J].Chinese Journal of Aeronautics, 2019, 32(4):815-825.
[27] ROSA S D, FRANCO F.Exact and numerical responses of a plate under a turbulent boundary layer excitation[J].Journal of Fluids and Structures, 2008, 24(2):212-230.
[28] JOSHI P, MULANI S B, SLEMP W C H, et al.Vibro-acoustic optimization of turbulent boundary layer excited panel with curvilinear stiffeners[J].Journal of Aircraft, 2012, 49(1):52-65.
[29] GENG Q, LI H, LI Y M.Dynamic and acoustic response of a clamped rectangular plate in thermal environments:Experiment and numerical simulation[J].The Journal of the Acoustical Society of America, 2014, 135(5):2674-2682.

E-mail：hkxb@buaa.edu.cn

关于我们

期刊社服务

专业学科

封面文章

友情链接

主管单位：中国科学技术协会主办单位：中国航空学会北京航空航天大学

基于缩比模型的薄壁结构声振响应等效研究

Equivalence of vibro-acoustic response based on scaled thin-walled structures

RichHTML

PDF (PC)

可视化

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

编辑推荐

Metrics

本文评价

[1]	郑锋, 黄薇, 季宏丽, 裘进浩. 复合材料薄板结构中的声学黑洞效应探究[J]. 航空学报, 2023, 44(1): 426453-426453.
[2]	彭振龙, 张翔宇, 张德远. 航空航天难加工材料高速超声波动式切削方法[J]. 航空学报, 2022, 43(4): 525587-525587.
[3]	段佳桐, 隋福成, 刘汉海, 解放, 欧阳天, 鲍蕊. 弯曲载荷下薄壁结构疲劳裂纹扩展性能[J]. 航空学报, 2021, 42(5): 524326-524326.
[4]	李远霄, 焦锋, 张世杰, 张顺, 王雪, 童景琳. 高低频复合振动钻削CFRP/钛合金叠层结构试验[J]. 航空学报, 2021, 42(10): 524802-524802.
[5]	孙丹, 王平, 赵欢, 张国臣, 肖忠会, 孟继纲. 新型浮动式收敛袋型密封自适应同心性能数值与实验研究[J]. 航空学报, 2020, 41(3): 423270-423270.
[6]	沙云东, 艾思泽, 赵奉同, 姜卓群, 张家铭. 高速热流下薄壁结构声振响应分析及寿命预估[J]. 航空学报, 2020, 41(2): 223327-223327.
[7]	王小东, 秦一凡, 季宏丽, 陆洋, 裘进浩. 基于声学黑洞效应的直升机驾驶舱宽带降噪[J]. 航空学报, 2020, 41(10): 223831-223831.
[8]	赵波, 别文博, 王晓博, 常宝琪. 纵-扭复合超声钻削TC4钛合金振动系统设计与试验[J]. 航空学报, 2020, 41(1): 423207-423207.
[9]	沙云东, 张墨涵, 赵奉同, 朱付磊. 热声载荷作用下薄壁结构非线性响应分析和试验验证[J]. 航空学报, 2019, 40(4): 222544-222544.
[10]	马皓晔, 李琳, 范雨, 吴亚光. 基于加速动态拉格朗日法的摩擦片阻尼分析[J]. 航空学报, 2019, 40(12): 223283-223283.
[11]	陆维爽, 刘沛清, 郭昊. 前缘下垂远场低频宽频噪声特性[J]. 航空学报, 2019, 40(10): 123152-123152.
[12]	黄淼, 褚林塘, 李成华, 蒋荣, 唐彬彬, 吴彬. 大型水陆两栖飞机抗浪能力研究[J]. 航空学报, 2019, 40(1): 522335-522335.
[13]	张翔宇, 张德远, 隋翯, 姜兴刚. 切深对椭圆超声振动切削机理的影响[J]. 航空学报, 2017, 38(4): 420567-420567.
[14]	许坤波, 乔渭阳, 常心悦, 银涛, 霍施宇. 基于组合传声器阵列方法的风扇宽频噪声[J]. 航空学报, 2017, 38(12): 121324-121324.
[15]	许坤波, 乔渭阳, 霍施宇, 程颢颐, 仝帆. 基于旋转轴向阵列的风扇宽频噪声实验[J]. 航空学报, 2017, 38(11): 121132-121132.