Line of action explained

In physics, the line of action (also called line of application) of a force is a geometric representation of how the force is applied. It is the straight line through the point at which the force is applied in the same direction as the vector .[1]

The concept is essential, for instance, for understanding the net effect of multiple forces applied to a body. For example, if two forces of equal magnitude act upon a rigid body along the same line of action but in opposite directions, they cancel and have no net effect. But if, instead, their lines of action are not identical, but merely parallel, then their effect is to create a moment on the body, which tends to rotate it.

Calculation of torque

For the simple geometry associated with the figure, there are three equivalent equations for the magnitude of the torque associated with a force

\vecF

directed at displacement

\vecr

from the axis whenever the force is perpendicular to the axis:

\begin{align} ||\vec\tau||&=||\vecr x \vecF||\\ &=rF\perp\\ &=r\perpF\\ &=||rF\sin\theta||, \end{align}

where

\vecr x \vecF

is the cross-product,

F\perp

is the component of

\vecF

perpendicular to

\hatr

,

r\perp

is the moment arm, and

\theta

is the angle between

\vecr

and

\vecF

Notes and References

  1. Mungan, Carl E. "Acceleration of a pulled spool." The Physics Teacher 39.8 (2001): 481-485. https://www.usna.edu/Users/physics/mungan/_files/documents/Publications/TPT.pdf