A company uses waterproof paper to make disposable conical drinking cups - Leaving Cert Mathematics - Question 8 - 2012

Setting the expression for volume equal to \frac{154\pi}{3}:

\frac{\pi}{3}h(81 - h²) = \frac{154\pi}{3}

We can simplify by canceling \frac{\pi}{3}:

h(81 - h²) = 154.

This expands to:

h² - 81h + 154 = 0.

Using the quadratic formula: h = \frac{81 \pm \sqrt{81² - 4 \cdot 1 \cdot 154}}{2 \cdot 1} h = \frac{81 \pm \sqrt{6561 - 616}}{2} h = \frac{81 \pm \sqrt{5945}}{2}.

The positive solutions will yield two values: an integer and a non-integer. They are h = 2 and h ≈ 7.83.

To find the maximum volume, we take the derivative of V with respect to h:

V(h) = \frac{\pi}{3}h(81 - h²).

Thus, dV/dh = \frac{\pi}{3}(81 - 3h²).

Setting dV/dh = 0 for maximum volume gives:

81 - 3h² = 0 => h² = 27 => h = \sqrt{27} = 3\sqrt{3} ≈ 5.2 cm.

Substituting this value back into the volume formula yields V ≈ 294 cm³.

The middle one, with a radius of 4.43 cm and height of 7.83 cm, is the most reasonable shape for a conical cup. The other cups are either too wide or too shallow to hold comfortably.

The circumference of the rim is given by:

C = 2\pi r, where r = 9.

Thus, C = 27\pi. To find the angle AOB:

\theta = \frac{27}{9} \cdot 360° = 3 \cdot 360° = 1080°, but we convert it to radians: \theta ≈ 177°. Hence, the angle AOB that must be cut is 177°.