Modeling and Faults Simulation of Aircraft Landing Gear System

Wei Gang Guo; Wei Han

doi:10.4028/www.scientific.net/AMM.333-335.2021

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 333-335Modeling and Faults Simulation of Aircraft Landing...

Modeling and Faults Simulation of Aircraft Landing Gear System

Abstract:

The model of aircraft landing gear hydraulic system is build by software of AMESim. Under the AMESim environment, a hydraulic simulation of the nose landing gear of aircraft is constructed. The simulation model of the component is built by graphical modeling method. Setting two case faults parameters of landing gear actuating cylinder leakage and air into oil, it obtains faults symptom of hydraulic system. The Internal characteristics, Interrelation and motion Law is shown for landing gear system various components. Combining hydraulic system simulation with fault diagnosis effectively, it can provide reference for fault analysis and design improvement of landing gear hydraulic system.

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Periodical:

Applied Mechanics and Materials (Volumes 333-335)

Pages:

2021-2024

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.333-335.2021

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Online since:

July 2013

Authors:

Wei Gang Guo, Wei Han

Keywords:

AMEsim, Modeling, Simulation, Undercarriage

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References

[1] Hongzhi Bao, Yongguang Liu. Design and reasearch of testing machine of open and withdraw hydraulic system of plane undercarriage . Chinese Hydraulic & Pneumatics (2002), p.18.

Google Scholar

[2] Peizi Li, Zhanlin WANG. Hydraulic transmission and servo control of the aircraft. Beijing: National Defense Industry Press (1979).

Google Scholar

[3] Yongtang Li, Bufang LEI. Modeling and simulation of hydraulic system. Beijing: Metallurgy Industry Press (2003).

Google Scholar

[4] Xinyu Ren, Yingqing Guo, Hua ting Yao. A simulation of the antisurging regulator performance for the aeroengine using AMESim. Journal of Aerospace Power (2004), p.572.

Google Scholar

[5] Jin Li, hua Wei. United simulation technique with AMESim and MATLAB/ simulink. Information Command Control System & Simulation Technology (2004), p.61.

Google Scholar

[6] Wilfrid Marquis-Favre, Eric Bideaux, Serge Scavarda. A planar mechanical library in the AMESim simulation software. Part I: Formulation of dynamics equations. Simulation Modeling Practice and Theory. 17 March (2005).

DOI: 10.1016/j.simpat.2005.02.006

Google Scholar

[7] Wilfrid Marquis-Favre, Eric Bideaux, Serge Scavarda. A planar mechanical library in the AMESim simulation software. Part II: Library composition and illustrative example. Simulation Modeling Practice and Theory. 17 March (2005).

DOI: 10.1016/j.simpat.2005.02.007

Google Scholar

[8] Bideaux E, Scavarda S. Pneumatic library for AMESim[J]. Fluid power system and technology, (1998), p.185.

DOI: 10.1115/imece1998-0489

Google Scholar

[9] Jiasheng Qin, Shanlan You. Characteristic and appplication of AMESim. Construction Machinery and Equipment (2004) , p.6.

Google Scholar

[10] M. Vugdelija, Z. Stojanovic. Determination of a time step interval in hydraulic systems transients' simulation. Advances in Engineering Software (2000).

DOI: 10.1016/s0965-9978(99)00043-5

Google Scholar

[11] Liming Peng, Yun Wang, Guohua Zhao. Modeling smooth rate through orifice in ADAMS/ Hydraulics . Chinese Hydraulics & Pneumatics (2004) , p.11.

Google Scholar