| Autor: |
Zegzhda, S. A., Petrova, V. I., Yushkov, M. P. |
| Zdroj: |
Vestnik St. Petersburg University: Mathematics; Jan2020, Vol. 53 Issue 1, p82-90, 9p |
| Abstrakt: |
We study movements of a loaded Stewart platform in this paper. A special form of differential equations is used (motion equations in excess coordinates are derived) to compose the motion equations. In this form, vectorial Lagrange equations of the first kind are compiled using differentiation with respect to the radius-vector of the center of mass of the system and the unit vectors (orts) of the main central axes of inertia of the moving body and with respect to their derivatives. These determine the position of a rigid body in space. The length invariance of the unit vectors and their orthogonality are taken into account as abstract holonomic relations imposed on vectors describing the motion of a rigid body. "Spurious oscillations" are some of the technical effects seen in the behavior of the Stewart platform in the equilibrium position. This reason for the system to leave the unstable equilibrium position is discussed in this paper. Such standard motion of the Stewart platform as vertical oscillations of the platform will be equally unstable. The simplest mechanism of the instability of such vertical movements of the platform is revealed in this work. We propose introducing classical feedbacks to obtain steady movement. The numerical solutions of the derived differential equations completely correspond to the numerical results obtained by solving the motion equations compiled using theorems on the motion of the center of mass and on the change in the kinetic moment when the system moves relative to the center of mass. [ABSTRACT FROM AUTHOR] |
| Databáze: |
Complementary Index |
| Externí odkaz: |
|
Full text from SpringerLink