Doc Al said:- it produces an angular acceleration about the center of mass
Combine those two accelerations to find the instantaneous axis of rotation, which will generally not be about its center of mass.
Doc Al said:Combine those two accelerations to find the instantaneous axis of rotation, which will generally not be about its center of mass.
Doc Al said:That force does two things:
- it produces an acceleration of the center of mass
- it produces an angular acceleration about the center of mass
You can treat the effect of the force as being the combination of a rotation about the center of mass plus a translation of the center of mass.Red_CCF said:Why would the angular acceleration be about the center of mass?
To find the translational acceleration of each portion of the body, add the acceleration due to rotation to the acceleration of the center of mass. You'll find a point where the total acceleration is zero. That's the axis of rotation.How does the acceleration of the center of mass shift the axis of rotation?
Doc Al said:You can treat the effect of the force as being the combination of a rotation about the center of mass plus a translation of the center of mass.
To find the translational acceleration of each portion of the body, add the acceleration due to rotation to the acceleration of the center of mass. You'll find a point where the total acceleration is zero. That's the axis of rotation.
Petr Mugver said:It depends on what you mean by "axe o rotation". If you mean the points that are left fixed by the rotation/translation, then, as Doc Al said, you can find this line by intersecting the planes orthogonal to the velocities of two points of the body. In general, not only it's not true that this line goes through the center of mass, but it can even lie outside the body.
For instance, the instantaneous axe of rotation of a wheel af a car is the point the wheel touches the ground, and the instantaneous axe for the moon is the center of the earth.
Moreover the IA of rotation depends on the reference frame you are in, so it has no real physical significance.
What has relevance is the direction of this axe, not it's origin. So, don't really bother on finding such axe: you can say that the body rotates about a direction, and you can put the origin of the axe wherever you like, the rotation doesn't change.
Curl said:You can logically prove why the center of mass is always the "axle of rotation".
When an object spins on ice, all the forces on the object must balance. If the object rotates about any point other than CM then there will be an acceleration of the CM which is not possible because the net force on the object is zero.
p.s. we're not talking about rotation, we're talking about an instant where the accelerations due to the forces add up to zero at a point.
the reason that objects spin only around their CoM is because any attempt to spin around somewhere other than the CoM is inherently unstable. If an object tried to rotate about an axis other than one passing through its CoM, it would get so out of equilibrium that it would rapidly adjust its rotation to one passing through its CoM.
I can't go into more detail about WHY such an attempted spin (ie, outside the CoM) is unstable, without introducing the concept of pseudo-forces within a rotating frame. But the above experiment should show you that attempting to spin around an axis outside the CoM is unstable.
The axle of rotation is determined by the line of action of the force. This is the imaginary line along which the force is applied and causes the object to rotate.
Yes, the axle of rotation can change if there are external forces acting on the rocket. For example, if the rocket is affected by gravitational forces or air resistance, the axle of rotation may shift.
The location of the axle of rotation determines the direction and speed of the rotation of the rocket. If the axle of rotation is closer to the center of mass, the rotation will be slower and if it is further away, the rotation will be faster.
The axle of rotation can be calculated using the principles of torque and moment of force. The distance from the force to the center of mass and the magnitude of the force are used to determine the location of the axle of rotation.
No, the axle of rotation and the axis of rotation are two different concepts. The axle of rotation is an imaginary line along which the force is applied, while the axis of rotation is the line around which the object rotates.