Bar on Roller Spinning and Translating: Force Impact?

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A force applied to one of the free ends of a spinning and translating bar will indeed cause the roller to move in the x-direction, as per the equation F=ma. However, this force also generates a torque due to its distance from the center of rotation, resulting in rotational motion about the bar's center. The combined effect of the applied force will lead to both translational movement and increased rotational speed. The extent of translation and rotation is influenced by the magnitude of the force and the moment of inertia of the bar. Understanding this interplay of forces and moments is essential in dynamics.
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I have kind of a simple concept from Dynamics that I can't really visualize. Assume that there is a bar on a roller that is spinning (both ends are free; it is rotating about a point near the middle) and translating in the x-direction. Will a force applied to one of the free ends in the x-direction cause the roller to move along the x-direction? It should, according to the equation F=ma (x-direction). But won't this simply cause it to spin about it's center? Thank you.
 
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It depends on whether the central axis of the roller is fixed to something else. If it isn't, it will move in the x direction when the force is applied.
 


Yes, a force applied to one of the free ends in the x-direction will cause the roller to move along the x-direction. This is because the force will create a linear acceleration in the x-direction, as described by the equation F=ma. However, this force will also have an impact on the rotational motion of the bar.

The rotational motion of the bar is affected by both the force applied and the moment of inertia of the bar. If the force is applied at a distance from the center of rotation, it will create a torque which will cause the bar to rotate about its center. This is known as the principle of moments.

So, while the bar will move in the x-direction due to the applied force, it will also continue to spin about its center due to the rotational effects of the force. The resulting motion will be a combination of translation and rotation.

It is important to note that the force and moment of inertia will determine the amount of translation and rotation, respectively. For example, if a larger force is applied, the bar will experience a greater linear acceleration in the x-direction, but it will also experience a larger torque and therefore spin faster about its center.

In summary, a force applied in the x-direction will cause the roller to move along the x-direction, but it will also have an impact on the rotational motion of the bar. This is a fundamental concept in dynamics that can be better understood through visualizing and analyzing the forces and moments acting on the system.
 

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