 Static Equilibrium Printer Friendly Version
When forces acting on an object which is at rest are balanced, then we say that the object is in a state of static equilibrium.

The resultant of these forces equals zero. That is, the vector sum of the forces adds to zero.

Example #1

Suppose two dogs are struggling for the same shoe as shown in the diagram below.  The left dog's force is shown by the yellow/black arrow while the right dog's force is shown by the teal arrow. Notice below that when the forces are added head-to-tail, the resultant force, shown in grey, acts straight up the y-axis. Forceright dog + Forceleft dog  = Resultant
Fr + Fl = R

To place the shoe into a state of static equilibrium, a third force (shown in red) would have to be added to the diagram. Then the forces exerted on the shoe would equal zero. Forceright dog + Forceleft dog  + "Equilibrium" vector = 0
Fr + Fl + E = 0
Fr + Fl = -E

By comparing the vector equations presented above

Fr + Fl = R
Fr + Fl = -E

we notice that the third force required for equilibrium to be established is a vector that has the same magnitude as the resultant, but points in 180º the opposite direction.

R = -E    Each dog's force has been resolved into its x- and y-components. A vector diagram showing only the components of each dog's force. The addition of a third force would place the shoe into a state of static equilibrium.

Example #2

Suppose you are asked to calculate the tensions in the three ropes (A, B, C) that are supporting the 5-kg mass shown below. Since the system is at rest, we will work the problem using the properties of static equilibrium. Let's begin with a freebody diagram showing the forces acting on the knot. Since these forces belong to three separate ropes, all three tensions can be different. The next step will be to build an x|y chart showing the components of each force. If θ were to equal 37º then Since we do not have any knowledge of any of the three tensions, we must now do a similar analysis using a freebody diagram of the 5-kg mass. The x|y chart for the 5-kg mass would look as follows: Since we know that the 5-kg mass is in static equilibrium, we know that the sum of the forces in each column equals zero. We only need to write the equation for the y-column since there are no non-zero forces in the x-column. y: C + (-mg) = 0 C - 5(9.8) = 0C = 49 N

Now, knowing the value for C, we can solve for the tensions in ropes A and B by setting up the following equations from each column in our x|y chart for the knot:

 x: -A cos(37º) + B = 0 y: A sin(37º) - C = 0 x: -0.8A + B = 0 y: 0.6A - C = 0 Since we know the value for C we will next solve for A and then for B. y: 0.6A - 49 = 0A = 49/0.6A = 81.7 N x: -0.8(81.7) + B = 0B = 0.8(81.7)B = 65.3 N

Example #3

This procedure can also be applied to the following situation in which a mother is just at the instant of releasing her child in a swing.   Refer to the following information for the next four questions.

Suppose the child in the illustration above has a mass of 15 kg and the angle the swing makes with the horizontal is 75º. See if you can model the example with the 5-kg mass and answer each of these questions.
 How much does the child weigh?

 What is the total tension required in all four "chains"?

 How large a restraining force does the parent supply?

 If four chains are actually supporting the swing, what is the tension in each individual chain?

In cases where the rope passes over a massless, frictionless pulley the tension on either side of the pulley is the same. This term really means that we are not considering the pulley to have any rotational inertia; that is, the rope slides over the pulley without causing it to rotate. When pulleys with rotational inertia are used, we have to assign different tensions to the ropes on each side and calculate the torque produced on the pulley.

Example #4

Consider this next system in which both suspended blocks have a mass of 1.5 kg and the pulley has a mass of 1.0 kg. Since all of the forces are vertical, we can easily identify the tensions in each of the three ropes by setting the "sum of the magnitudes of the downward forces" equal to the "sum of the magnitudes of the upward forces."

Isolating each block and then the pulley we can generate the following freebody diagrams and their equations.   T2 = mg T3 = mg T1 = T2 + mg + T3 T2 = (1.5)(9.8) T2 = 14.7 N T3 = (1.5)(9.8) T3 = 14.7 N T1 = 14.7 + 1(9.8) + 14.7 T1 = 39.2 N

If the masses had been unequal, then the system would have accelerated in the direction of the greater mass. Yet, even during that period of acceleration, the tensions T2 and T3 would have remained equal.

Summary Example

Let's use all of the properties learned on this page to now determine the mass of the monkey. In the process, also calculate T1, T2, T3, T4, T5, T6, and W2 if W1 equals 350 N. If you need assistance getting started, reference the information in the hints located to the left of each question. left knot T1

 T3

 T4

right knot
 T5

 T2

 W2 pulley T6

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