Dynamics of an axisymmetric body spinning on a horizontal surface. I. Stability and the gyroscopic approximation

H. K. Moffatt, Y. Shimomura, M. Branicki
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引用次数: 44

Abstract

The general spinning motion of an axisymmetric rigid body on a horizontal table is analysed, allowing for slip and friction at the point of contact P. Attention is focused on the case of spheroids (prolate or oblate), and particularly on spheroids whose density distribution is such that the centre–of–mass and centre–of–volume coincide. Four classes of fixed points (i.e. steady states) are identified, and the linear stability properties in each case are determined, assuming viscous friction at P. The governing dynamical system is six–dimensional. Trajectories of the system are computed, and are shown in projection in a three–dimensional subspace; these start near unstable fixed points and (in the case of viscous friction) end at stable fixed points. It is shown inter alia that a uniform prolate spheroid set in sufficiently rapid spinning motion with its axis horizontal is unstable, and its axis rises to a stable steady state, at either an intermediate angle or the vertical, depending on the initial angular velocity. These computations allow an assessment of the circumstances under which the condition described as ‘gyroscopic balance’ is realized. Under this condition, the evolution from an unstable to a stable state is greatly simplified, being described by a first–order differential equation. Oscillatory modes which are stable on linear analysis may be destabilized during this evolution, with consequential oscillations in the normal reaction R at the point of support. The computations presented here are restricted to circumstances in which R remains positive.
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轴对称体在水平面上旋转的动力学。稳定性和陀螺仪近似
分析了轴对称刚体在水平桌面上的一般旋转运动,考虑了接触点p处的滑移和摩擦。重点讨论了椭球体(长形或扁形)的情况,特别是密度分布使质心和体积中心重合的椭球体。确定了四类不动点(即稳态),并确定了每种情况下的线性稳定性特性,假设p点处有粘性摩擦。计算了系统的轨迹,并在三维子空间中以投影形式表示;它们在不稳定的固定点附近开始,(在粘性摩擦的情况下)在稳定的固定点结束。除其他外,它表明,在足够快的旋转运动中,一个均匀的长条形球体,其轴水平是不稳定的,它的轴上升到一个稳定的稳定状态,在一个中间角度或垂直,取决于初始角速度。这些计算允许对实现“陀螺仪平衡”条件的情况进行评估。在这种情况下,从不稳定状态到稳定状态的演化被大大简化,用一阶微分方程来描述。在线性分析中稳定的振荡模式可能在此演变过程中不稳定,在支撑点的正常反应R中产生相应的振荡。这里给出的计算仅限于R为正的情况。
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