The development of the wavy mode of Taylor vortices in the flow
between a rotating inner cylinder and a stationary outer cylinder has
been investigated by visual observations using a stroboscopic technique
and by inner cylinder torque measurements. Radius ratios of 0.874,
0.911, 0.950 and 0.975 have been tested for the concentric and eccentric
cylinder cases.
The stability of wavy mode flow has been found to decrease with
increasing radius ratio and/or increasing eccentricity. Observations
of the flow suggested that the wavy mode can be classified into three
regimes called, respectively, the primary, transitional and secondary
modes. The three regimes were most easily identified using a radius
ratio of 0.911 and concentric cylinders. In this case, the onset of the
transitional state (so called because of the tendency for the circumferential
wave number to change continually even at particular constant speeds) was
found to be particularly violent, completely destroying the well defined
nature of the primary wavy mode. Rather surprisingly, this quasi-turbulent
regime of wavy mode flow was found to give way to the more
regular secondary wavy mode as the speed of the inner cylinder was
increased. Non-uniqueness is shown to be an important feature of wavy
mode flow.
Results are presented showing that circumferential wave number
changes can often be detected by torque measurements. In particular,
the onset of the transitional state results in a sudden reduction in
the required driving torque, the magnitude of which is considerably
influenced by the stability of the primary wavy mode flow. Friction
coefficient characteristics derived from the torque measurement results
are used to deduce a general relationship incorporating the effects of
the eccentricity and radius ratios.
Date of Award | 1977 |
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Original language | English |
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Awarding Institution | |
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STUDY OF TAYLOR INSTABILITIES AND TURBULENCE IN LUBRICATING FILMS
SHORT, M. G. (Author). 1977
Student thesis: PhD