A student investigated the laws of equilibrium for a set of co-planar forces acting on a metre stick - Leaving Cert Physics - Question 1 - 2007

The diagram should accurately represent the metre stick with the following forces:

• Weight of the stick (1.2 N) acting downward from the 50 cm mark.
• Upward forces: 10 N acting at the 10 cm mark, 4 N acting at the 80 cm mark, and 15 N acting at the 90 cm mark.

To find the total upward force, sum all upward forces: Total Upward Force = 10 N + 4 N + 15 N = 29 N.

The total downward force is equal to the weight of the metre stick: Total Downward Force = 1.2 N.

According to the first law of equilibrium, an object is in equilibrium when the sum of upward forces equals the sum of downward forces. Here, the total upward force (29 N) does not equal the total downward force (1.2 N). This indicates that while the forces may momentarily balance, the object will not stay in equilibrium unless adjustments are made.

To calculate the anticlockwise moments, apply the formula: Moment = Force × Distance

• For 10 N at 10 cm: Moment = 10 N × 10 cm = 100 Ncm
• For 4 N at 80 cm: Moment = 4 N × 80 cm = 320 Ncm
• For 15 N at 90 cm: Moment = 15 N × 90 cm = 1350 Ncm Total Anticlockwise Moment = 100 Ncm + 320 Ncm + 1350 Ncm = 1770 Ncm.

To find the clockwise moments, use the same formula:

• For 1.2 N at 50 cm: Moment = 1.2 N × 50 cm = 60 Ncm Total Clockwise Moment = 60 Ncm.

According to the second law of equilibrium, the sum of clockwise moments must equal the sum of anticlockwise moments. In this case, the total anticlockwise moment is 1770 Ncm, while the total clockwise moment is 60 Ncm, which indicates the metre stick is not in a state of rotational equilibrium. This imbalance will cause the stick to rotate until a new balance is achieved.