论文信息 - Influence of the added mass effect and boundary conditions on the dynamic response of submerged and confined structures

Influence of the added mass effect and boundary conditions on the dynamic response of submerged and confined structures

The dynamic response of submerged and confined disk-like structures is of interest in the flied of hydraulic machinery, especially in hydraulic turbine runners. This response is difficult to be estimated with accuracy due to the strong influence of the boundary conditions. Small radial gaps as well as short axial distances to rigid surfaces greatly modify the dynamic response because the fact of the added mass and damping effects. Moreover, the effect of the shaft coupling is also important for certain mode-shapes of the structure. In the present study, the influence of the added mass effect and boundary conditions on the dynamic behavior of a submerged disk attached to a shaft is evaluated through experimental tests and structural- acoustic coupling numerical simulations. For the experimentation, a test rig has been developed. It consists of a confined disk attached to a shaft inside a cylindrical container full of water. The disk can be fixed at different axial positions along the shaft. Piezoelectric patches are used to excite the disk and the response is measured with submersible accelerometers. For each configuration tested, the natural frequencies of the disk and the shaft are studied. Numerical results have been compared with experimental results.

[1] F. Avellan,et al. Numerical simulation of fluid added mass effect on a francis turbine runner , 2007 .

[2] Eduard Egusquiza,et al. Capability of structural-acoustical FSI numerical model to predict natural frequencies of submerged structures with nearby rigid surfaces , 2012 .

[3] Eduard Egusquiza,et al. Failure investigation of a large pump-turbine runner , 2012 .

[4] Hideo Ohashi,et al. Case Study of Pump Failure Due to Rotor-Stator Interaction , 1994 .

[5] Kyeong-Hoon Jeong,et al. Hydroelastic vibration of circular plates immersed in a liquid-filled container with free surface , 2013 .

[6] R. Blevins,et al. Formulas for natural frequency and mode shape , 1984 .

[7] Eduard Egusquiza,et al. Experimental investigation of added mass effects on a Francis turbine runner in still water , 2006 .

[8] Jaromír Horáček,et al. Analysis of the free vibration of a coupled plate/fluid interacting system and interpretation using sub-system modal energy , 2007 .

[9] Marco Amabili,et al. FREE VIBRATIONS OF CIRCULAR PLATES COUPLED WITH LIQUIDS: REVISING THE LAMB PROBLEM , 1996 .

[10] Yuji Kubota,et al. Added Mass Effect on Disc Vibrating in Fluid , 1984 .

[11] J. Ginsberg,et al. Asymmetric vibration of a heavily fluid‐loaded circular plate using variational principles , 1992 .

[12] U Seidel,et al. Application of fluid-structure coupling to predict the dynamic behavior of turbine components , 2010 .