Stability Analysis of the Morton Effect of Rigid and Flexible Rotors

Volume 10B: Structures and Dynamics ◽

10.1115/gt2020-14999 ◽

2020 ◽

Author(s):

Silun Zhang ◽

Mohamed Amine Hassini ◽

Mihai Arghir

Keyword(s):

Stability Analysis ◽

Three Dimensional ◽

Flexible Rotor ◽

Experimental Conditions ◽

Modified Method ◽

Flexible Rotors ◽

Influence Coefficients ◽

Morton Effect ◽

Isothermal Analysis ◽

Large Amplitude Vibrations

Abstract This paper presents a stability analysis of the Morton effect. The analysis is an extension of the Murphy and Lorenz method [11] and is based on better estimates of three influence coefficients linking the phenomena contributing to the Morton effect: the total response to the rotor unbalance, the temperature difference on the rotor surface induced by synchronous vibrations and the thermomechanical deformation of the rotor. The models used in the present work are more complex and accurate because they are based on the non-linear unbalance response (large amplitude vibrations) of the rotor, on the non-isothermal analysis of the journal bearing flow and on a three-dimensional thermos-elastic analysis of the rotor. The results obtained with the original stability analysis of Murphy and Lorenz and with the modified one are compared with original experimental data obtained for a short (rigid) and long (flexible) rotor guided by a ball bearing and by a cylindrical bearing and presented in a previous work [20]. Both methods confirm the experimental results obtained for a short (rigid) rotor. They show that this rotor is not subject to instabilities generated by the Morton effect. However, the results obtained for a long (flexible) rotor are different. The simplified method of Murphy and Lorenz shows a stable behavior while the modified method presented in this work confirms the findings of [20] and indicates that the rotor could be subject to a Morton effect at rotational speeds close to the experimental conditions. The improvements obtained by using the modified stability analysis are therefore clearly underlined, as well as its inherent limitations.

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A Simple Stability Analysis for Flexible Rotors in Tilting Pad Bearings

Journal of Mechanical Design ◽

10.1115/1.3453881 ◽

1978 ◽

Vol 100 (1) ◽

pp. 165-172 ◽

Cited By ~ 1

Author(s):

E. A. Bulanowski

Keyword(s):

Stability Analysis ◽

Free Vibrations ◽

Damping Factor ◽

Quick Method ◽

Flexible Rotors ◽

Tilting Pad ◽

Rotor Bearing ◽

Single Mass ◽

Tilting Pad Bearings ◽

Nonsynchronous Vibrations

A simplified stability analysis for flexible rotors in tilting pad bearings is developed which provides a convenient and practical approach for the consideration of nonsynchronous vibrations during the design phase of rotor bearing systems. It is known that the synchronous unbalance response of a single mass Jeffcott rotor in linear isotropic bearings is identical in form to the response of a simple spring-mass-damper system excited by a rotating unbalance. This paper demonstrates that the free vibrations, and hence the system damping factor, of a distributed mass flexible rotor in tilting pad bearings may be analyzed using a single mass, two tier spring-damper model. The relationship between the system damping factor and rotor stability is discussed. Non-synchronous tilting pad bearing characteristics are incorporated into the expression for the damping factor, and nondimensional curves are presented which establish values of the damping factor as a function of operating speed, critical speed, bearing clearance and Sommerfeld number. The subject curves provide a quick method for establishing stability guidelines during rotor design and for comparing existing rotor bearing systems.

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