Conference article

Equations of State in Fighter Aircraft Oleo-pneumatic Shock Absorber Modelling

Arttu Heininen
Automation Technology and Mechanical Engineering, Tampere University, Tampere, Finland

Jussi Aaltonen
Automation Technology and Mechanical Engineering, Tampere University, Tampere, Finland

Kari T. Koskinen
Automation Technology and Mechanical Engineering, Tampere University, Tampere, Finland

Juha Huitula
Automation Technology and Mechanical Engineering, Tampere University, Tampere, Finland

Download articlehttp://dx.doi.org/10.3384/ecp19162007

Published in: FT2019. Proceedings of the 10th Aerospace Technology Congress, October 8-9, 2019, Stockholm, Sweden

Linköping Electronic Conference Proceedings 162:7, p. 64-70

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Published: 2019-10-23

ISBN: 978-91-7519-006-8

ISSN: 1650-3686 (print), 1650-3740 (online)

Abstract

Most of all modern commercial and military aircraft have oleo-pneumatic shock absorbers in their landing gear. An oleo-pneumatic shock absorber consists of a gas charge and an oil ?ll. During the stroke oil is forced through ori?ces which provides damping, while the gas charge is compressed and acts as a spring by increasing the stiffness of the shock absorber. Typically, when the gas behaviour is modelled, the ideal gas law is used as the equation of state as this provides in most cases adequate ?delity with relatively light computational load. However, in a ?ghter aircraft, especially in naval service, the gas pressure inside a shock absorber raises too high during landing for the ideal gas assumption to be valid. Therefore, other well-established equations of state have been considered. These are Van der Waals, Redlich-Kwong-Soave, and Peng-Robinson equation of state. This paper presents a multi-physics simulation model of a two-chamber oleo-pneumatic shock absorber based on fundamental analytical equations. Using this model, the behaviour of the aforementioned equations of state are studied in two cases: quasi-static and dynamical compression. The simulation results are compared to laboratory measurements. This comparison veri?es that the ideal gas law should not be used when modelling naval ?ghter aircraft shock absorbers.

Keywords

fighter aircraft, shock absorber, modelling, simulation

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