ACTA AERONAUTICAET ASTRONAUTICA SINICA >
Modeling method and verification for rotor systems integrated with transfer functions of flexible foundation
Received date: 2023-06-30
Revised date: 2023-07-23
Accepted date: 2023-07-30
Online published: 2023-08-24
Supported by
National Natural Science Foundation of China(12272035);The Fundamental Research Funds for the Central Universities(JD2302)
Modern high-end turbomachines, such as aviation engines and rocket turbo pumps, have extremely high demands for performance. The flexible support structure of these machines results in significant coupling of vibration characteristics between the rotor and flexible foundation, making it necessary to include the flexible support structure in the overall dynamic analysis. However, the modeling process of high accuracy flexible support structures needs to take considerable time, and the simplified support model cannot represent the dynamic characteristics of real support structures. Therefore, a simulation method for rotor system dynamic modeling integrated with flexible foundation transfer functions is proposed. The measured transfer functions of the flexible foundation are fitted by the state subspace method to obtain a low-dimensional mathematical model with time-domain and frequency-domain representation. The flexible foundation model is coupled to the rotor finite element model through the support force model to form a hybrid rotor dynamic model based on physical transfer functions. At the same time, a model transformation strategy for flexible foundations from steady-state to transient is proposed, and a fast transient numerical integration method with linear-nonlinear (explicit-implicit) node separation is used to solve the problem. Based on the proposed model and computational method, numerical simulations of steady-state and transient dynamics of the flexible foundation-rotor system are conducted, as well as vibration testing experiments with the sweep frequency excitation at a stable speed and unbalance excitation during shut-down. The results show that the measured vibration characteristics of the flexible foundation can be effectively coupled in the overall dynamic analysis, and the transient dynamic response predicted by the rotor dynamic model, considering the flexible foundation characteristics, is more consistent with the experimental results. The proposed method provides an effective approach for modeling and simulating the overall system with complex flexible foundations.
Shuai LI , Qihang LI , Can CHEN , Zhifa FANG , Weimin WANG . Modeling method and verification for rotor systems integrated with transfer functions of flexible foundation[J]. ACTA AERONAUTICAET ASTRONAUTICA SINICA, 2024 , 45(3) : 229250 -229250 . DOI: 10.7527/S1000-6893.2023.29250
| 1 | 张大义, 刘烨辉, 洪杰, 等. 航空发动机整机动力学模型建立与振动特性分析[J]. 推进技术, 2015, 36(5): 768-773. |
| ZHANG D Y, LIU Y H, HONG J, et al. Investigation on dynamical modeling and vibration characteristics for aero engine[J]. Journal of Propulsion Technology, 2015, 36(5): 768-773 (in Chinese). | |
| 2 | MOORE J J. Rotordynamic analysis of a large industrial turbo-compressor including finite element substructure modeling[C]∥ American Society of Mechanical Engineers. American Society of Mechanical Engineers Digital Collection. 2008: 1233-1243. |
| 3 | JEON S M, KWAK H D, YOON S H, et al. Rotordynamic analysis of a turbopump with the casing structural flexibility[J]. Journal of Propulsion and Power, 2008, 24(3): 433-436. |
| 4 | 高金海, 洪杰. 航空发动机整机动力特性建模技术研究[J]. 战术导弹技术, 2006(3): 29-35. |
| GAO J H, HONG J. Study of modeling technique for dynamic characteristics of engine casing[J]. Tactical Missile Technology, 2006(3): 29-35 (in Chinese). | |
| 5 | 梁小鸥, 臧朝平, 雷新亮, 等. 涡轮后机匣的结构动力学精确建模[J]. 航空发动机, 2022, 48(1): 47-53. |
| LIANG X O, ZANG C P, LEI X L, et al. Accurate structural dynamic modeling of a rear spokes-frame casing of the turbine[J]. Aeroengine, 2022, 48(1): 47-53 (in Chinese). | |
| 6 | AMER M, PAEHR M, SCHEIDT L P, et al. Determining the influence of casing vibrational behavior on rotordynamics[J]. Journal of Engineering for Gas Turbines and Power, 2022, 144(5): 051012-051020. |
| 7 | 张耀涛, 徐可君, 秦海勤. 双转子-支承-机匣耦合系统非线性动力学响应分析[J]. 机电工程, 2019, 36 (2): 168-173. |
| ZHANG Y T, XU K J, QING H Q. Nonlinear dynamic response analysis of dual-rotor-support-casing system[J]. Journal of Mechanical and Electrical Engineering, 2019, 36(2): 168-173 (in Chinese). | |
| 8 | 秦海勤, 张耀涛, 徐可君. 双转子-支承-机匣耦合系统碰摩振动响应分析及试验验证[J]. 机械工程学报, 2019, 55(19): 75-83. |
| QING H Q, ZHANG Y T, XU K J. Rubbing vibration response theoretical analysis and experimental verification for a double rotor support casing system[J]. Journal of Mechanical Engineering, 2019, 55(19): 75-83 (in Chinese). | |
| 9 | WANG N, LIU C, JIANG D, et al. Casing vibration response prediction of dual-rotor-blade-casing system with blade-casing rubbing[J]. Mechanical Systems and Signal Processing, 2019, 118: 61-77. |
| 10 | LI B, ZHOU H, LIU J, et al. Modeling and dynamic characteristic analysis of dual rotor-casing coupling system with rubbing fault[J]. Journal of Low Frequency Noise, Vibration and Active Control, 2022, 41(1): 41-59. |
| 11 | CHEN G. Vibration modelling and verifications for whole aero-engine[J]. Journal of Sound and Vibration, 2015, 349: 163-176. |
| 12 | 陈果. 含复杂滚动轴承建模的航空发动机整机振动耦合动力学模型[J]. 航空动力学报, 2017, 32(9): 2193-2204. |
| CHEN G, Whole aero-engine vibration coupling dynamics model including modeling of complex ball and roller bearings[J]. Journal of Aerospace Power, 2017, 32(9): 2193-2204 (in Chinese). | |
| 13 | YANG Y, YANG W, JIANG D. Simulation and experimental analysis of rolling element bearing fault in rotor-bearing-casing system[J]. Engineering Failure Analysis, 2018, 92: 205-221. |
| 14 | 孙传宗, 杨瑞, 陈予恕, 等. 机匣-双转子高维系统建模与实验验证[J]. 振动与冲击, 2018, 37(18): 152-157. |
| SUN C Z, YANG R, CHEN Y S, et al. Modeling and experiment verification of a casing-dual-rotor high-dimensional system[J]. Journal of Vibration & Shock, 2018, 37(18): 152-157 (in Chinese). | |
| 15 | 边子方. 基于有限元增量传递矩阵法研究转子系统的非线性特性[D]. 沈阳:东北大学,2018. |
| BIAN Z F. The nonlinear characteristic research of rotor systems with the finite element incremental transfer matrix method[D]. Shenyang:Northeast University,2018 (in Chinese). | |
| 16 | 罗忠, 王晋雯, 韩清凯, 等. 组合支承转子系统动力学的研究进展[J]. 机械工程学报, 2021, 57(7): 44-60. |
| LUO Z, WANG J W, HAN Q K, et al. Review on dynamics of the combined support-rotor system[J]. Journal of Mechanical Engineering, 2021, 57(7): 44-60 (in Chinese). | |
| 17 | 陈予恕, 张华彪. 航空发动机整机动力学研究进展与展望[J]. 航空学报, 2011, 32(8): 1371-1391. |
| CHEN Y S, ZHANG H B. Review and prospect on the research of dynamics of complete aero-engine systems[J]. Acta Aeronautica et Astronautica Sinica, 2011, 32(8): 1371-1391 (in Chinese). | |
| 18 | 赵斌. 航空发动机整机振动半实物仿真模型研究[D]. 南京:南京航空航天大学, 2015. |
| ZHAO B. Study on a semi-physical simulation model for the whole aero-engine vibration[D]. Nanjing: Nanjing University of Aeronautics and Astronautics, 2015 (in Chinese). | |
| 19 | KRüGER T D. Consideration of complex support structure dynamics in rotordynamic assessments[C]∥ American Society of Mechanical Engineers. 2013. |
| 20 | 赵斌, 陈果, 冯国全. 航空发动机整机振动半实物建模方法研究[J]. 推进技术, 2016, 37(2): 346-353. |
| ZHAO B, CHEN G, FENG G Q. Study on a semi-physical method for modeling overall vibration of an aeroengine[J]. Journal of Propulsion Technology, 2016, 37(2): 346-353 (in Chinese). | |
| 21 | LI Q, CHEN C, GAO S, et al. The coupled bending-torsional dynamic behavior in the rotating machinery: modeling, simulation and experiment validation[J]. Mechanical Systems and Signal Processing, 2022, 178: 109306. |
| 22 | MCKELVEY T, AKCAY H, LJUNG L. Subspace-based multivariable system identification from frequency response data[J]. IEEE Transactions on Automatic Control, 1996, 41(7): 960-979. |
| 23 | SAUER T. Numerical analysis[M]. Upper Saddle River: Addison-Wesley Publishing Company, 2012. |
| 24 | CLOUD C H. Stability of rotors supported by tilting pad journal bearings[D]. Virginia: University of Virginia, 2007: 120-136. |
/
| 〈 |
|
〉 |
CJA