Normal, tension, and other examples of forces (Page 5/10)

Physics 105: adventures in Page 5 / 10

Whenever we have two-dimensional vector problems in which no two vectors are parallel, the easiest method of solution is to pick a convenient coordinate system and project the vectors onto its axes. In this case the best coordinate system has one axis horizontal and the other vertical. We call the horizontal the $x$ -axis and the vertical the $y$ -axis.

Solution

First, we need to resolve the tension vectors into their horizontal and vertical components. It helps to draw a new free-body diagram showing all of the horizontal and vertical components of each force acting on the system.

A vector T sub L making an angle of five degrees with the negative x axis is shown. It has two components, one in the vertical direction, T sub L y, and another horizontal, T sub L x. Another vector is shown making an angle of five degrees with the positive x axis, having two components, one along the y direction, T sub R y, and the other along the x direction, T sub R x. In the free-body diagram, vertical component T sub L y is shown by a vector arrow in the upward direction, T sub R y is shown by a vector arrow in the upward direction, and weight W is shown by a vector arrow in the downward direction. The net force F sub y is equal to zero. In the horizontal direction, T sub R x is shown by a vector arrow pointing toward the right and T sub L x is shown by a vector arrow pointing toward the left, both having the same length so that the net force in the horizontal direction, F sub x, is equal to zero. — When the vectors are projected onto vertical and horizontal axes, their components along those axes must add to zero, since the tightrope walker is stationary. The small angle results in $T$ being much greater than $w$ .

Consider the horizontal components of the forces (denoted with a subscript $x$ ):

F_{net x} = T_{L x} - T_{R x} .

The net external horizontal force $F_{net x} = 0$ , since the person is stationary. Thus,

\begin{array}{l} F_{net x} = 0 & = & T_{L x} - T_{R x} \\ T_{L x} & = & T_{R x} . \end{array}

Now, observe [link] . You can use trigonometry to determine the magnitude of $T_{L}$ and $T_{R}$ . Notice that:

\begin{array}{l} cos (5.0º) & = & \frac{T_{L x}}{T_{L}} \\ T_{L x} & = & T_{L} cos (5.0º) \\ cos (5.0º) & = & \frac{T_{R x}}{T_{R}} \\ T_{R x} & = & T_{R} cos (5.0º) . \end{array}

Equating $T_{L x}$ and $T_{R x}$ :

T_{L} cos (5.0º) = T_{R} cos (5.0º) .

Thus,

T_{L} = T_{R} = T,

as predicted. Now, considering the vertical components (denoted by a subscript $y$ ), we can solve for $T$ . Again, since the person is stationary, Newton’s second law implies that net $F_{y} = 0$ . Thus, as illustrated in the free-body diagram in [link] ,

F_{net y} = T_{L y} + T_{R y} - w = 0 .

Observing [link] , we can use trigonometry to determine the relationship between $T_{L y}$ , $T_{R y}$ , and $T$ . As we determined from the analysis in the horizontal direction, $T_{L} = T_{R} = T$ :

\begin{array}{l} sin (5.0º) & = & \frac{T_{L y}}{T_{L}} \\ T_{L y} = T_{L} sin (5.0º) & = & T sin (5.0º) \\ sin (5.0º) & = & \frac{T_{R y}}{T_{R}} \\ T_{R y} = T_{R} sin (5.0º) & = & T sin (5.0º) . \end{array}

Now, we can substitute the values for $T_{L y}$ and $T_{R y}$ , into the net force equation in the vertical direction:

\begin{array}{l} F_{net y} & = & T_{L y} + T_{R y} - w = 0 \\ F_{net y} & = & T sin (5.0º) + T sin (5.0º) - w = 0 \\ 2 T sin (5.0º) - w & = & 0 \\ 2 T sin (5.0º) & = & w \end{array}

and

T = \frac{w}{2 sin (5.0º)} = \frac{mg}{2 sin (5.0º)},

so that

T = \frac{(70 . 0 kg) (9 . {80 m/s}^{2})}{2 (0.0872)},

and the tension is

T = 3900 N .

Discussion

Note that the vertical tension in the wire acts as a normal force that supports the weight of the tightrope walker. The tension is almost six times the 686-N weight of the tightrope walker. Since the wire is nearly horizontal, the vertical component of its tension is only a small fraction of the tension in the wire. The large horizontal components are in opposite directions and cancel, and so most of the tension in the wire is not used to support the weight of the tightrope walker.

If we wish to create a very large tension, all we have to do is exert a force perpendicular to a flexible connector, as illustrated in [link] . As we saw in the last example, the weight of the tightrope walker acted as a force perpendicular to the rope. We saw that the tension in the roped related to the weight of the tightrope walker in the following way:

T = \frac{w}{2 sin (θ)} .

We can extend this expression to describe the tension $T$ created when a perpendicular force ( $F_{⊥}$ ) is exerted at the middle of a flexible connector:

T = \frac{F_{⊥}}{2 sin (θ)} .

<< Chapter < Page Page > Chapter >>

Practice Key Terms 3

Read also:

Get Jobilize Job Search Mobile App in your pocket Now!

100% Free Mobile Applications
Receive real-time job alerts and never miss the right job again

Source: OpenStax, Physics 105: adventures in physics. OpenStax CNX. Dec 02, 2015 Download for free at http://legacy.cnx.org/content/col11916/1.1

Google Play and the Google Play logo are trademarks of Google Inc.

Notification Switch

Would you like to follow the 'Physics 105: adventures in physics' conversation and receive update notifications?

Ask

	Unit 1 Geography Test By Qqq Qqq Start Flashcards
	1 Arts Society: Theater 1 By Jonathan Long Start Quiz
	College algebra By OpenStax Read Online Course
	Anthropology Aesthetics Culture By Richley Crapo Start Assignment
	29 Biology 29 Vertebrates MCQ By OpenStax Start Quiz
©flickr:	Anatomy Physiology By Jemekia Weeden Start Quiz
	2 Timeshare 2 By Jams Kalo Start Quiz
	4 Sociology 04 Society and Social Interaction MCQ By OpenStax Start Quiz
	1 Neuroscience Exam 2004 1 By David Corey Start Exam
	23 AP 23 Digestive System Essay By OpenStax Start Flashcards