A large spherical balloon is deflating. At time t seconds the balloon has radius r cm and volume V cm³ The volume of the balloon is modelled as decreasing at a constant rate. (a) Using this model, show that $$ \frac{dr}{dt} = -\frac{k}{r^{2}} $$ where k is a positive constant. Given that - the initial radius of the balloon is 40 cm - after 5 seconds the radius of the balloon is 20 cm - the volume of the balloon continues to decrease at a constant rate until the balloon is empty (b) solve the differential equation to find a complete equation linking r and t. (c) Find the limitation on the values of t for which the equation in part (b) is valid.

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A large spherical balloon is deflating - Edexcel - A-Level Maths Pure - Question 16 - 2020 - Paper 1

Question 16

A large spherical balloon is deflating. At time t seconds the balloon has radius r cm and volume V cm³ The volume of the balloon is modelled as decreasing at a con... show full transcript

Worked Solution & Example Answer:A large spherical balloon is deflating - Edexcel - A-Level Maths Pure - Question 16 - 2020 - Paper 1

Step 1

Using this model, show that $$ \frac{dr}{dt} = -\frac{k}{r^{2}} $$ where k is a positive constant.

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Answer

To find the relationship between the radius and the volume of the balloon, we start with the volume formula for a sphere:

$V = \frac{4}{3} \pi r^{3}$

Differentiating both sides with respect to time t gives:

$\frac{dV}{dt} = 4\pi r^{2} \frac{dr}{dt}$

Since the volume decreases at a constant rate, we can express this as:

$\frac{dV}{dt} = -k$

Equating the two expressions, we have:

$-k = 4\pi r^{2} \frac{dr}{dt}$

Rearranging, we find:

$\frac{dr}{dt} = -\frac{k}{4\pi r^{2}}$

Setting (c=4\pi) gives the required result:

$\frac{dr}{dt} = -\frac{k}{r^{2}}$

Step 2

solve the differential equation to find a complete equation linking r and t.

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Answer

We start with the rearranged differential equation:

$\frac{dr}{dt} = -\frac{k}{r^{2}}$

Separating variables leads to:

$r^{2} dr = -k dt$

Integrating both sides:

$\int r^{2} dr = -k \int dt$

This results in:

$\frac{r^{3}}{3} = -kt + C$

Where C is the constant of integration. We find C using the initial condition:

When (t = 0), (r = 40 \text{ cm}). Thus:

$\frac{(40)^{3}}{3} = C \Rightarrow C = \frac{64000}{3}$

Now substituting C back in gives:

$\frac{r^{3}}{3} = -kt + \frac{64000}{3}$

By multiplying through by 3, we arrive at:

$r^{3} = -3kt + 64000$

From this, we can express the equation linking r and t as:

$r^{3} + 3kt - 64000 = 0$

Step 3

Find the limitation on the values of t for which the equation in part (b) is valid.

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Answer

To find the limits on t, we note that at t = 5 seconds, the radius reduces to 20 cm. Plugging (r = 20\text{ cm}) into the derived equation:

$20^{3} = -3k \cdot 5 + \frac{64000}{3}$

Calculating (20^{3}) gives 8000, thus:

$8000 = -15k + \frac{64000}{3}$

To find k, we can express it in terms of t, ensuring that the balloon remains inflated. The expression must be positive, leading to a condition on t:

The balloon continuously deflates until:

$t \leq \frac{40}{7} \text{ seconds}$

Therefore, the limitation on t must satisfy:

$t < 40/7 ext{ seconds}$

A large spherical balloon is deflating - Edexcel - A-Level Maths Pure - Question 16 - 2020 - Paper 1

Worked Solution & Example Answer:A large spherical balloon is deflating - Edexcel - A-Level Maths Pure - Question 16 - 2020 - Paper 1

Using this model, show that $$ \frac{dr}{dt} = -\frac{k}{r^{2}} $$ where k is a positive constant.

solve the differential equation to find a complete equation linking r and t.

Find the limitation on the values of t for which the equation in part (b) is valid.

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