Abstract

  In engineering most movable mechanisms contain rotating components as the disc, cone, sphere, toroid, etc. that manifest the action of inertial torques. The known gyroscope theories do not give a correct explanation of the nature of inertial torques except the action of the torques originated by the change in the angular momentum. The physics of the inertial torques generated by the spinning objects is more complex than represented by the new research. Any rotating objects produce the system of the inertial torques that resulting in their motions. This system of inertial torques forms the fundamental principles of gyroscope theory, which are used for developing the mathematical models for the motions of gyroscopic devices. This work represents formulation of the several inertial torques generated by the spinning circular cone. The obtained mathematical models for inertial torques acting on for the spinning cone enables for computing its motion in space.

Keywords: Gyroscopic Effects; Spinning Cone; Torque; Force

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Citation

Citation: Ryspek Usubamatov and Almazbek Arzybaev. “Inertial Torques Acting on a Spinning Circular Cone”. Acta Scientific Computer Sciences 2.7 (2020): 26-31.

Copyright

Copyright: © 2020 Ryspek Usubamatov and Almazbek Arzybaev. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.