12.2 Examples of static equilibrium (Page 4/9)

University physics volume 1 Page 4 / 9

Figure is a schematic drawing of a forearm rotated around the elbow. A 50 pound ball is held in the palm. The distance between the elbow and the ball is 13 inches. The distance between the elbow and the biceps muscle, which causes a torque around the elbow, is 1.5 inches. Forearm forms a 60 degree angle with the upper arm. — The forearm is rotated around the elbow ( E ) by a contraction of the biceps muscle, which causes tension ${\vec{T}}_{M} .$

Strategy

We identify three forces acting on the forearm: the unknown force

\vec{F}

at the elbow; the unknown tension

{\vec{T}}_{M}

in the muscle; and the weight

\vec{w}

with magnitude

w = 50 lb .

We adopt the frame of reference with the x -axis along the forearm and the pivot at the elbow. The vertical direction is the direction of the weight, which is the same as the direction of the upper arm. The x -axis makes an angle

β = 60 °

with the vertical. The y -axis is perpendicular to the x -axis. Now we set up the free-body diagram for the forearm. First, we draw the axes, the pivot, and the three vectors representing the three identified forces. Then we locate the angle

β

and represent each force by its x - and y -components, remembering to cross out the original force vector to avoid double counting. Finally, we label the forces and their lever arms. The free-body diagram for the forearm is shown in [link] . At this point, we are ready to set up equilibrium conditions for the forearm. Each force has x - and y -components; therefore, we have two equations for the first equilibrium condition, one equation for each component of the net force acting on the forearm.

Figure is a free-body diagram for the forearm. Force F is applied at the point E. Force T is applied at the distance r tau from the point E. Force W is applied at the opposite side separated by r w from the point E. Projections of the forces at the x and y axes are shown. Forces F and T form angle beta with the x axis. Force W forms an angle beta with line connecting it with its projection to the y axis. — Free-body diagram for the forearm: The pivot is located at point E (elbow).

Notice that in our frame of reference, contributions to the second equilibrium condition (for torques) come only from the y -components of the forces because the x -components of the forces are all parallel to their lever arms, so that for any of them we have $sin θ = 0$ in [link] . For the y -components we have $θ = \pm 90 °$ in [link] . Also notice that the torque of the force at the elbow is zero because this force is attached at the pivot. So the contribution to the net torque comes only from the torques of $T_{y}$ and of $w_{y} .$

Solution

We see from the free-body diagram that the x -component of the net force satisfies the equation

+ F_{x} + T_{x} - w_{x} = 0

and the y -component of the net force satisfies

+ F_{y} + T_{y} - w_{y} = 0 .

[link] and [link] are two equations of the first equilibrium condition (for forces). Next, we read from the free-body diagram that the net torque along the axis of rotation is

+ r_{T} T_{y} - r_{w} w_{y} = 0 .

[link] is the second equilibrium condition (for torques) for the forearm. The free-body diagram shows that the lever arms are $r_{T} = 1.5 in .$ and $r_{w} = 13.0 in .$ At this point, we do not need to convert inches into SI units, because as long as these units are consistent in [link] , they cancel out. Using the free-body diagram again, we find the magnitudes of the component forces:

\begin{matrix} F_{x} & = & F cos β = F cos 60 ° = F / 2 \\ T_{x} & = & T cos β = T cos 60 ° = T / 2 \\ w_{x} & = & w cos β = w cos 60 ° = w / 2 \\ F_{y} & = & F sin β = F sin 60 ° = F \sqrt{3} / 2 \\ T_{y} & = & T sin β = T sin 60 ° = T \sqrt{3} / 2 \\ w_{y} & = & w sin β = w sin 60 ° = w \sqrt{3} / 2 . \end{matrix}

We substitute these magnitudes into [link] , [link] , and [link] to obtain, respectively,

\begin{matrix} F / 2 + T / 2 - w / 2 & = & 0 \\ F \sqrt{3} / 2 + T \sqrt{3} / 2 - w \sqrt{3} / 2 & = & 0 \\ r_{T} T \sqrt{3} / 2 - r_{w} w \sqrt{3} / 2 & = & 0 . \end{matrix}

When we simplify these equations, we see that we are left with only two independent equations for the two unknown force magnitudes, F and T , because [link] for the x -component is equivalent to [link] for the y -component. In this way, we obtain the first equilibrium condition for forces

F + T - w = 0

and the second equilibrium condition for torques

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Source: OpenStax, University physics volume 1. OpenStax CNX. Sep 19, 2016 Download for free at http://cnx.org/content/col12031/1.5

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