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Transcript 
Mechanics 2.6.
Forces acting at an angle: Resolving Forces
mc-web-mech2-6-2009
A force that acts at an angle can be split into two perpendicular components.
F
F sin θ
θ
F cos θ
Newton’s Second Law can be applied in each of the resolved directions.
Worked Example 1.
A computer base unit of mass 6 kg is dragged along a smooth desk. If the tension in each arm of
the person dragging it is 20 N and it acts at 25◦ above the horizontal, what is the acceleration of
the base unit and what is its normal reaction?
Solution
Figure 1 shows the forces acting on the base unit. Firstly the acceleration, a, needs to be calculated.
The resultant horizontal force is 40 cos 25◦ .
Using Newton’s Second Law of Motion:
a
2T = 40
R
o
25
F = ma
40 cos 25◦ = 6 × a
⇒ a = 6.0 m s−2 (2 s.f.)
6g
Figure 1
In order to calculate the normal reaction force, resolve vertically:
R + 40 sin 25◦ − 6 × 9.81 = 0
⇒ R = 58.56 − 16.90 = 42 N (2 s.f.)
Worked Example 2.
Two tug boats are towing a large boat, of mass 13750 kg, back to shore. Tug boat 1 is pulling with
a force of T1 = 7500 N at an angle of 30◦ north of the forward motion (see Figure 2) and tug boat
2 is pulling with a force of T2 = 8500 N at an angle θ south of the forward motion. If there is a
resistive motion of 1050 N opposing the eastern motion, what is the acceleration of the large boat?
www.mathcentre.ac.uk
1
Written by T. Graham, M.C. Harrison, S. Lee, C.L.Robinson
c mathcentre 2009
Solution
Firstly, calculate the unknown angle θ.
7500 N
Resolving perpendicular to the direction of
motion gives:
1050 N
Direction of
Motion
13750 kg
T1 sin 30◦ − T2 sin θ = 0
7500( 21 )
= sin θ
8500
⇒ θ = 26◦ (2 s.f.)
30
o
θ
8500 N
Figure 2 (View from above)
In order to calculate the acceleration, resolve in the direction of motion, which gives the resultant
force as 7500 cos 30◦ + 8500 cos 26◦ − 1050.
Applying Newton’s Second Law gives:
7500 cos 30◦ + 8500 cos 26◦ − 1050 = 13750a
⇒ a = 0.95 m s−2 (2 s.f.)
Exercises
1. A computer base unit of mass 4.5 kg is dragged along a smooth desk. If the tension in each
arm of the person dragging it is 16 N and acts at 22◦ above the horizontal, then what is the
normal reaction force?
2. A computer base unit of mass 7.5 kg is dragged along a smooth desk. If the normal contact
force is 23 N and the tension in the arm of the person dragging it acts at 23◦ to the horizontal,
then what is the total tension in the person’s arms?
3. Two tug boats are towing a large boat, of mass 22500 kg, back to shore. Tug boat 1 is pulling
with a force of 5500 N at an angle of 35◦ north of the forward motion (similar to Worked
Example 2) and tug boat 2 is pulling with a force of 4907.8 N at an angle 40◦ south of the
forward motion. If the large boat is being pulled with constant velocity, and there is a resistive
force to the motion, then what size is the resistive force?
4. Two tug boats are towing a large boat, of mass M kg, back to shore. Tug boat 1 is pulling
with a force of T1 N at an angle of 25◦ north of the forward motion (like in Worked Example 2)
and tug boat 2 is pulling with a force of T2 N at an angle of 25◦ south of the forward motion.
If the large boat is being pulled with constant velocity, and there is a resistive force of 4000 N
to the motion, then what are the magnitudes of the two forces T1 and T2 ?
5. A child on a sledge is being pulled along a horizontal path by its parent. The child and sledge
have a combined mass of 20 kg and there is a normal contact force of 124.5 N. Given there
is no resistance to motion and the parent pulls with a force of 125 N at an angle θ to the
horizontal, then what is the angle θ?
6. A child on a sledge is being pulled along a horizontal path by its parent. The child and sledge
have a combined mass of 18 kg and there is a normal contact force of 135 N. Given there
is no resistance to motion and the parent pulls with a force of F N at an angle 25◦ to the
horizontal, then what is F ?
Answers (all to 2 s.f.)
1. 32 N 2. 130 N 3. 8300 N 4. F1 = F2 = 2200 N 5. 35◦
www.mathcentre.ac.uk
2
Written by T. Graham, M.C. Harrison, S. Lee, C.L.Robinson
6. 98 N
c mathcentre 2009
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