Euromech Colloquium 573 “VIBRATION ANALYSIS OF ROTATING SHAFT ON TEXTURED HYDRODYNAMIC JOURNAL BEARINGS” J. Rebufa 1,2 , E. Le Guyadec 2 , D. Mazuyer 1 , and F. Thouverez 1 1 LTDS, UMR 5513, 69130 Ecully, France E-mail: jocelyn.rebufa@doctorant.ec-lyon.fr denis.mazuyer@ec-lyon.fr fabrice.thouverez@ec-lyon.fr 2 CEA, DTEC, 30207 Bagnols-sur-Cèze, France E-mail: erick.leguyadec@cea.fr Abstract: The aim of this study is to analyse the influence of surface texturing on the dynamic behavior of a shaft on two hydrodynamic bearings. A prediction algorithm is presented with Fluid Structure Interaction (FSI) between the rotating shaft and the lubricant based on finite element method. Cavitation in bearings is taken into account. The hydrodynamic flow in the texturing pattern is modeled by two multi-scale algorithms. Static, modal and transient analyses are performed in order to predict the impact of several texturing patterns on the system vibrations. Keywords: Hydrodynamic journal bearings, monolithic FSI coupling, cavitation, surface texturing, multi-scale homogeniza- tion 1 Introduction Advanced rotating machinery, using small rotors or working at high rotating speeds, require a complete control of the vibration components. Lubrication systems, such as hydrodynamic journal bearings play a crucial role in the dynamic behavior of the whole machinery and have a significant influence on structures vibrations. Fluid Structure Interaction between the lubricant and the rotating shaft has to be taken into account. Predictions of the shaft vibrations are difficult because of the nonlinear behavior of the hydrodynamic bearing. Moreover, cavitation in the lubricant appears and changes drastically the pressure distribution. Several cavitation models could be retained leading, in most cases to different behaviors. Besides, recent improvements in surface texturing have shown several enhancements in hydrodynamic lubrication such as friction reduction or improvement of drag force. However, effects of the texture pattern on the dynamic behavior of the system are not well known and need to be properly analyzed. 2 Hydrodynamic bearing with cavitation The pressure in hydrodynamic bearings can be low enough for the lubricant to vaporized in the low pressure zone. In this work, the cavitation phenomenon in the lubricant is modeled by a free surface problem between two fluid domains, with Reynolds equations and the Jakobsson-Floberg-Olsson / Elrod-Adams (Elrod (1981)) mass flow conservation model in a finite element formulation. The problem is written as a Linear Complementary Problem (LCP), and the Lemke algorithm is used to compute the pressure profile and the cavitation boundaries in the fluid film. 3 Monolithic algorithm for vibrations analysis The pressure profile is projected on the structure, modeled by a Timoshenko beam. The finite element method is used to discretize the conservation of momentum of the system (Lalanne and Ferraris (1990)) : M ¨ δ +[D + G] ˙ δ +[K + C]δ = Hp(δ, ˙ δ, ˙ φ)+ ˙ φ 2 F (φ) (1) where δ is the displacement vector of the structure, p the pressure vector of the fluid degrees of freedom, φ the angular position of the mass unbalance, M the mass matrix, D the dissipation matrix, G the gyroscopic matrix, K the stiffness matrix, C the circulatory matrix, H the projection matrix of the pressure degrees of freedom of the fluid elements on structure elements, F the unbalance force excitation. The dependance of the pressure p in δ and ˙ δ is highly nonlinear. Newton’s method is used to compute the static equilibrium of the system. Modal analysis can give information on linearized vibrations around equilibrium positions taking into account shaft misalignment in bearings. An implicit algorithm realizes time integration in order to find limit cycles for the shaft orbits.