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Viscous fluid motion in a spinning and nutating cylinder

Published online by Cambridge University Press:  21 April 2006

Thorwald Herbert
Thorwald Herbert
Affiliation:
Department of Engineering Science and Mechanics, Virginia Polytechnic Institute and State University, Blacksburg, VA 24061, USA
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Abstract

Spin-stabilized projectiles with liquid payloads can experience a severe flight instability characterized by a rapid yaw-angle growth and a simultaneous loss in spin rate. Laboratory experiments and field tests have shown that this instability originates from the internal fluid motion in the range of high viscosity. After evaluation of the experimental data and analysis of the equations for the fluid motion in a spinning and nutating cylinder, we have developed a simple model of this flow. Disregarding the finite length of the cylinder, this model provides the flow field and the viscous contribution to the liquid moments in analytical form. At low Reynolds number, the flow field agrees well with computational results for the centre section of a cylinder of aspect ratio 4.3. The roll moment caused by this flow largely agrees with experimental data for a wide range of Reynolds numbers. Estimates of the temperature variation indicate that discrepancies at very low Reynolds numbers may originate from associated changes of the viscosity during the experiments.

Type
Research Article
Information
Journal of Fluid Mechanics , Volume 167 , June 1986 , pp. 181 - 198
Copyright
© 1986 Cambridge University Press

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References

Abramowitz, M. & Stegun, I. A. 1972 Handbook of Mathematical Functions. Dover Publications.
D'Amico, W. P. 1977 Field tests of the XM761: first diagnostic test. Ballistic Research Laboratory, Mem. Rep. no. 1325.Google Scholar
D'Amico, W. P. 1978 Field tests of the XM761: second diagnostic test. Ballistic Research Laboratory, Mem. Rep. ARBRL-MR-02806.Google Scholar
D'Amico, W. P. & Miller, M. C. 1979 Flight instability produced by a rapidly spinning, highly viscous liquid. J. Spacecraft Rockets, 16, 6264.Google Scholar
Herbert, Th. 1982 Fluid motion in a rotating and nutating cylinder- Part 1. Report prepared under the Scientific Services Program. Rep. CRDC-CR-84087 (1984).Google Scholar
Herbert, TH. 1983 The flow of highly viscous fluid in a spinning and nutating cylinder. Proc. of the 1983 Scientific Conference on Chemical Defense Research. Aberdeen Proving Ground, MD.Google Scholar
Herbert, Th. 1984 Highly viscous fluid flow in a spinning and nutating cylinder. Proc. of the Second Army Conference on Applied Mathematics and Computing. Troy, NY. ARO Report 85–1.Google Scholar
Miller, M. C. 1981 Void characteristics of a liquid filled cylinder undergoing spinning and coning motion, J. Spacecraft Rockets, 18, 286288.Google Scholar
Miller, M. C. 1982 Flight instabilities of spinning projectiles having nonrigid payloads. J. Guidance, Control, Dynamics, 5, 151157.Google Scholar
Murphy, C. M. 1984 A relationship between liquid roll moment and liquid side moment. Ballistic Research Laboratory, Mem. Rep. ARBRL-MR-03347.Google Scholar
Murphy, C. M. 1985 A relation between liquid roll moment and liquid side moment. J. Guidance, Control, Dynamics, 8, 287288.Google Scholar
Pierpont, D. 1985 Design of an experiment for visualization of the flow in a spinning and nutating cylinder. Senior Project Report, VPI & SU.Google Scholar
Stewartson, K. 1959 On the stability of a spinning top containing liquid. J. Fluid Mech. 5, (4), 577592.Google Scholar
Vaughn, H. R., Obbrkampf, W. L. & Wolfe, W. P. 1983 Numerical solution for a spinning nutating fluid-filled cylinder. Sandia Rep. SAND 83–1789.Google Scholar
Vaughn, H. R., Oberkampf, W. L. & Wolfe, W. P. 1985 Fluid motion inside a spinning nutating cylinder. J. Fluid Mech. 150, 121138.Google Scholar
Wedemeyer, E. H. 1966 Viscous corrections to Stewartson's stability criterion. Ballistic Research Laboratory, Rep. 1325.