The diagram shows a solid cone which has a slant height of \(15\) cm and a vertical
height of \(h\) cm.
(i) Show that the volume, \(V \,\text{cm}^3\), of the cone is given by
\[
V = \frac{1}{3}\pi(225h - h^3).
\]
[The volume of a cone of radius \(r\) and vertical height \(h\) is
\(\dfrac{1}{3}\pi r^2 h\).]
(ii) Given that \(h\) can vary, find the value of \(h\) for which \(V\) has a stationary
value. Determine, showing all necessary working, the nature of this stationary value.
Part (i): Expressing the Volume in Terms of \(h\)
Let the radius of the base be \(r\) cm.
We know:
- slant height \(= 15\) cm
- vertical height \(= h\) cm
- radius \(= r\) cm
These form a right-angled triangle, so by Pythagoras:
\[
r^2 + h^2 = 15^2 = 225
\quad\Rightarrow\quad
r^2 = 225 - h^2.
\]
Volume of the cone:
\[
V = \frac{1}{3}\pi r^2 h
= \frac{1}{3}\pi(225 - h^2)h
= \frac{1}{3}\pi(225h - h^3).
\]
Hence the required expression is shown.
Part (ii): Stationary Value of the Volume
Step 1: Differentiate \(V\) with respect to \(h\).
\[
V = \frac{1}{3}\pi(225h - h^3)
\]
\[
\frac{dV}{dh}
= \frac{1}{3}\pi(225 - 3h^2)
= \pi(75 - h^2).
\]
Step 2: Find stationary points by setting \(\dfrac{dV}{dh}=0\).
\[
\pi(75 - h^2) = 0
\quad\Rightarrow\quad 75 - h^2 = 0
\quad\Rightarrow\quad h^2 = 75
\quad\Rightarrow\quad h = \sqrt{75} = 5\sqrt{3}\ \text{cm}
\]
(We take the positive value because \(h\) is a length.)
Step 3: Determine the nature of the stationary value (max / min).
Find the second derivative:
\[
\frac{dV}{dh} = \pi(75 - h^2)
\quad\Rightarrow\quad
\frac{d^2V}{dh^2} = -2\pi h.
\]
At \(h = 5\sqrt{3}\):
\[
\frac{d^2V}{dh^2} = -2\pi (5\sqrt{3}) = -10\pi\sqrt{3} < 0.
\]
Since the second derivative is negative, the stationary point is a
maximum.
Conclusion:
The volume is maximised when \(h = 5\sqrt{3}\,\text{cm}\), and this stationary value is a maximum.