The Detection of Journal Bearing Cavitation with Use of Ultrasound Technology

Miranda, Gregorio do Couto

31 May 2016

No description available.

Mechanical Engineering

Fluid Dynamics

Simulace rozběhu Lavalova rotoru uloženého v nelineárních vazbách / Simulation of the Laval rotor supported by nonlinear bearings

Krček, Aleš

January 2021

The presented diploma thesis deals with simulation of Laval rotor supported by nonlinear bearings. The first part of thesis deals with research, which is focused on description of Laval rotor and motion equations for case of rigid and flexible rotor, also on description and modeling of hydrodynamic and magnetic bearing, which is considered in thesis. The second part of thesis deals with simulation of rotor for different approaches to modeling hydrodynamic and magnetic bearings. Using simulations performer in time domain, the dynamic behavior of Laval rotor is evaluated and compared. Simulations are performer in MATLAB.

High Pressure Performance of Foil Journal Bearings in Various Gases

Briggs, Maxwell H.

January 2008

No description available.

Aerospace Engineering

Mechanical Engineering

High Pressure

Super Critical, Foil Bearing

Air Bearing

Tribology

Hydrodynamic Bearing

Bearing

Brayton Cycle

Closed Brayton Cycle

Air Bearing

Gas Bearing

Journal Bearing

Foil Journal Bearing

Výpočtové modelování radiálních hydrodynamických ložisek pro vodní stroje / Computational modeling of radial hydrodynamic bearings for water machines

Pokorný, Jan

January 2018

The aim of this thesis is to calculate the stiffness and damping coefficients for radial hydrodynamic bearings. Cylindrical and lemon hydrodynamic bearings are considered. The solution to this problem mainly depends on the hydrodynamic pressure in the bearing. The numerical solution of the Reynolds equation is used to calculate the pressure. The effect of variable viscosity and density of the lubricant due to temperature changes is considered. The static equilibrium position of the journal centre is also solved. The stiffness and damping coefficients are determined using small amplitude journal motions about the equilibrium position. Three methods for determining these coefficients are presented. The outcome of this thesis is an algorithm for the calculation of stiffness and damping coefficients for cylindrical and lemon bearings. Results for lemon bearings are presented and comparison with the commercial software DynRot BR is made. The benefit of this thesis is the creation of an algorithm for the calculation of journal centre equilibrium position, a new way of incorporating the temperature changes in the viscosity and the density of the lubricant, and the modification of a method for calculating stiffness and damping coefficients based on experimental analogy.