Research on Stiffness and Damping of Sandwich Damping Metal Bellows Considering Fluid-solid Interaction

The stiffness and damping of sandwich damping metal bellows are researched by theory analysis, numerical simulation and experiment. Modal strain energy is induced. Finite element method (FEM) software ANSYS is chosen to analyze the loss factor and axis stiffness of bellows. The application of bellow...

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Veröffentlicht in:	Ji xie gong cheng xue bao 2014-03, Vol.50 (5), p.74-81
1. Verfasser:	LIU, Yonggang
Format:	Artikel
Sprache:	chi ; eng
Schlagworte:	Bellows Computer simulation Damping Finite element method Mathematical models Pipelining (computers) Stiffness Walls
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creator	LIU, Yonggang
description	The stiffness and damping of sandwich damping metal bellows are researched by theory analysis, numerical simulation and experiment. Modal strain energy is induced. Finite element method (FEM) software ANSYS is chosen to analyze the loss factor and axis stiffness of bellows. The application of bellows in piping system is introduced. The mechanical performance of bellows considering fluid-solid interaction is simulated. A piping system simulation platform is put forward. The stiffness and damping of bellows in piping system are studied. Numerical analysis and simulation show the distributing of loss factor with wrinkle, layer and wall. It is usually practical for noise reduction to choose the bellows with more wrinkles, more layers, fewer wall of damping and metal. And the effects of wrinkle, elasticity module and wall on the compressed stiffness of bellows are studied. The results show that more wrinkles, fewer elastic modulus metal and fewer wall of bellows can improve the displacement compensation. The axis displacement with rates and pressure of flow are obtained too. The effect of pressure on stiffness and damping ratio is carried out by experimental method. All results give a theory base of optimizing design for sandwich damping metal bellows.
doi_str_mv	10.3901/JME.2014.05.074
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Modal strain energy is induced. Finite element method (FEM) software ANSYS is chosen to analyze the loss factor and axis stiffness of bellows. The application of bellows in piping system is introduced. The mechanical performance of bellows considering fluid-solid interaction is simulated. A piping system simulation platform is put forward. The stiffness and damping of bellows in piping system are studied. Numerical analysis and simulation show the distributing of loss factor with wrinkle, layer and wall. It is usually practical for noise reduction to choose the bellows with more wrinkles, more layers, fewer wall of damping and metal. And the effects of wrinkle, elasticity module and wall on the compressed stiffness of bellows are studied. The results show that more wrinkles, fewer elastic modulus metal and fewer wall of bellows can improve the displacement compensation. The axis displacement with rates and pressure of flow are obtained too. The effect of pressure on stiffness and damping ratio is carried out by experimental method. 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The effect of pressure on stiffness and damping ratio is carried out by experimental method. 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Modal strain energy is induced. Finite element method (FEM) software ANSYS is chosen to analyze the loss factor and axis stiffness of bellows. The application of bellows in piping system is introduced. The mechanical performance of bellows considering fluid-solid interaction is simulated. A piping system simulation platform is put forward. The stiffness and damping of bellows in piping system are studied. Numerical analysis and simulation show the distributing of loss factor with wrinkle, layer and wall. It is usually practical for noise reduction to choose the bellows with more wrinkles, more layers, fewer wall of damping and metal. And the effects of wrinkle, elasticity module and wall on the compressed stiffness of bellows are studied. The results show that more wrinkles, fewer elastic modulus metal and fewer wall of bellows can improve the displacement compensation. The axis displacement with rates and pressure of flow are obtained too. 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subjects	Bellows Computer simulation Damping Finite element method Mathematical models Pipelining (computers) Stiffness Walls
title	Research on Stiffness and Damping of Sandwich Damping Metal Bellows Considering Fluid-solid Interaction
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