Acta Aeronautica et Astronautica Sinica ›› 2024, Vol. 45 ›› Issue (4): 628353-628353.doi: 10.7527/S1000-6893.2023.28353
• Special Topic: Vibration Identification and Suppression Technology of Aeroengine • Previous Articles
Xiangdong GE, Fayong WU(
), Yongquan LIU, Zhongyan AN, Baodong QIAO, Qiang GAO, Tianlong QIN, Xiaoyang ZHOU
CJA
Received:2022-12-05
Revised:2023-02-13
Accepted:2023-02-21
Online:2023-03-07
Published:2023-03-03
Contact:
Fayong WU
E-mail:Fayongwu@sina.com
Supported by:CLC Number:
Xiangdong GE, Fayong WU, Yongquan LIU, Zhongyan AN, Baodong QIAO, Qiang GAO, Tianlong QIN, Xiaoyang ZHOU. Research methods for whole aeroengine vibration and their engineering application[J]. Acta Aeronautica et Astronautica Sinica, 2024, 45(4): 628353-628353.
Fig.1
Vibration source and influence of whole aeroengine
Fig.2
Structure diagram of aeroengine
Fig.3
Variation trend of typical vibration of aeroengine
Fig.4
Bode diagram of vibration response from aeroengine
Fig.5
Waterfall diagram of vibration response of aeroengine
Fig.6
Arrangement diagram of vibration monitoring points
Fig.7
Structure modification diagram of aeroengine
Fig.8
Test schematic diagram of low-pressure rotor key-phase signal
Fig.9
Test schematic diagram of high-pressure rotor key-phase signal
Fig.10
Response comparison before and after vibration mutation
Fig.11
Wavelet analysis result during vibration
Fig.12
Response curves of 2 vibration state of bearing block
Fig.13
Variation characteristics of working vibration models of rotor pivot before and after vibration mutation (N2=14 400 r/min)
Fig.14
Motion tracks and characteristics of primary phase points of pivot during vibration mutation
Fig.15
Calculation results of critical speed and Campbell of aeroengine
Fig.16
Synchronous circular motion model of rotor
Fig.17
Arrangement diagram of monitoring points
Fig.18
Time-domain waveform diagram before and after vibration mutation-compressor level 3
Fig.19
Frequency spectrum of abnormal vibration-compressor level 3
Fig.20
Orbit of shaft center of compressor level 3
Fig.21
Time-domain waveform diagram before and after vibration mutation-compressor level 8
Fig.22
Frequency spectrum diagram of abnormal vibration mode-compressor level 8
Fig. 23
Orbit of shaft center of compressor level 8
Fig.24
Time-domain waveform diagram before and after vibration mutation-high-pressure turbine
Fig.25
Frequency spectrum diagram of abnormal vibration mode-high-pressure turbine
Fig.26
Orbit of shaft center of high-pressure turbine
Fig.27
Rotor elastic line changing rule during vibration mutation
Fig.28
Dynamic properties test diagram of core engine rotor at full speed
Fig. 29
Modeling diagram during modal test of core engine rotor
Fig.30
Core engine elastic line changing rule at high and low speed
Fig.31
Mathematical description methods for rotor angle deformation of core engine
Fig.32
Mathematical description methods for included angle of core engine rotor and rotation axis
Fig.33
Changing rule of included angle of core engine rotor and rotation axis
Fig.34
Changing rule of rotor angle deformation of core engine
Fig.35
Frequency response function from modal test of core engine rotor
Fig. 36
Vibration model diagram from modal test of core engine rotor
Table 1
Inherent frequency test results for core engine rotor with different torques
| 阶次 | 频率/Hz | |
|---|---|---|
| 力矩=52 N·m | 力矩=13 N·m | |
| 1 | 63.7 | 62.7 |
| 2 | 116.4 | 116.2 |
| 3 | 394.7 | 393.9 |
| 4 | 676.6 | 675.1 |
| 5 | 750.8 | 750.5 |
| 6 | 997.7 | 996.5 |
Fig.37
Test schematic diagram of dynamic characteristics of whole stator casing
Fig.38
Modal test diagram of whole engine including full stator casing
Fig.39
Excitation force test result of rotating excitation device
Fig.40
Measuring result of vibration response
Fig.41
Dynamic compliance test and research result of full stator casing
Fig.42
Two-bending vibration model diagram of full stator casing in whole engine modal test
Fig.43
Three-bending vibration model diagram of full stator casing in whole engine modal test
Fig.44
Waterfall of normal vibration response
Fig.45
Matching diagram of theoretical and experimental characteristics of rotor unbalance excitation mutation
Fig.46
Vibration response change diagram before and after core engine balancing
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