(^428) A Textbook of Engineering Mechanics
We know that the horizontal distance between the point of projection and the mark (R),
(^2) sin2 (72 )sin2
48 72 sin 2
ug
gg
αα
== =α
or
48
sin 2 0.667
72
α= = or 2 α = 41.8°
∴ α = 20.9° Ans.
Example 20.12. A projectile fired from the edge of a 150 m high cliff with an initial velocity
of 180 m/s at an angle of elevation of 30° with the horizontal. Neglecting air resistance find :
- The greatest elevation above the ground reached by the projectile ; and
- Horizontal distance from the gun to the point, where the projectile strikes the ground.
Solution. Given : Height of cliff = 150 m ; Velocity of projection (u) = 180 m/s and angle of
projection with the horizontal (α) = 30°.
Fig. 20.8.- The greatest elevation above the ground reached by the projectile
We know that maximum height to which the projectile will rise above the edge O of the cliff,
(^22) sin (180) sin 30 (^22) (180) (^2) (0.5) 2
413.3 m
2 2 9.8 19.6
u
H
g
α°×
== = =
×
∴^ Greatest elevation above the ground reached by the projectile,
s = 413.3 + 150 = 563.3 m Ans.
- The horizontal distance from the gun to the point, where the projectile strikes the ground.
First of all, consider motion of the projectile from the edge of the cliff to the maximum
height. We know that the time taken by the projectile to reach maximum height from the edge of the
cliff,
1sin 180 sin 30 180 0.5
9.2 s
9.8 9.8u
t
gα°×
== = =Now consider vertical motion of the projectile from the maximum height to the ground
due to gravitational acceleration only. In this case, u = 0 and s = 563.3 m.
Let t 2 = Time taken by the projectile to reach the ground from the
maximum height.
We know that the vertical distance (s),
222
22 2211
563.3 0 9.8 4.9
22=+ =+× =ut gt t tor^2 563.3 115
4.9t == or t 2 =10.7 s ...(ii)