A seventh-order model for dynamic response of an electro-hydraulic servo valve

In this paper, taking two degrees of freedom on the armature–flapper assembly into account, a seventh-order model is deduced and proposed for the dynamic response of a two-stage electro-hydraulic servo valve from nonlinear equations. These deductions are based on fundamental laws of electromagnetism...

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Bibliographic Details
Published in:Chinese journal of aeronautics 2014-12, Vol.27 (6), p.1605-1611
Main Authors: Liu, Changhai, Jiang, Hongzhou
Format: Article
Language:English
Subjects:
AMESim
Computational fluid dynamics
Computer simulation
Dynamic response
Fluid flow
Fluids
Hydraulic control systems
Mathematical models
Nozzle–flapper
Servo valve
Servomechanisms
Torque motor
Transfer function
Valves
仿真模型
低阶模型
动态响应
模型推导
流体性质
物理参数
电液伺服阀
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Summary:In this paper, taking two degrees of freedom on the armature–flapper assembly into account, a seventh-order model is deduced and proposed for the dynamic response of a two-stage electro-hydraulic servo valve from nonlinear equations. These deductions are based on fundamental laws of electromagnetism, fluid, and general mechanics. The coefficients of the proposed seventhorder model are derived in terms of servo valve physical parameters and fluid properties explicitly.For validating the results of the proposed model, an AMESim simulation model based on physical laws and the existing low-order models validated by other researchers through experiments are used to compare with the seventh-order model. The results show that the seventh-order model can reflect the physical behavior of the servo valve more explicitly than the existing low-order models and it could provide guidance more easily for a linear control design approach and sensitivity analysis than the AMESim simulation model.
ISSN:1000-9361
DOI:10.1016/j.cja.2014.10.029