The water behind a dam is normally released at a rate of 250000 litres per second. (i) Find how long it takes to release 1 million cubic metres (1 000 000 m³) of water. Note 1 m³ = 1000 litres. Give your answer correct to the nearest minute. (ii) Due to heavy rainfall, the operators of the dam decide to increase the flow by 10% for 24 hours. Find how many m³ of water were released in that 24 hour period. Give your answer in the form a × 10^n, where 1 ≤ a < 10, and n ∈ N. Give the value correct to 3 significant figures. John walks around a circular trail of radius 0.5 km at a steady speed of 6 km/h. (i) How long will it take him to complete 3 full circuits of the trail? Give your answer correct to the nearest minute. (ii) Mary decides to walk every day over a 5 day period. She walks a distance of 3 km on day one. She increases the length of her walk by 15% each day for the next four days. Her average speed on day 5 is 4 km/h. Find how long it will take her to complete her walk on day 5. Give your answer in minutes, correct to the nearest minute. (iii) One day, during John's walk he meets Mary at point P on the trail. Mary is walking in the opposite direction at a steady speed of 4 km/h. John continues walking at 6 km/h. How far will he travel until he meets Mary again? Give your answer correct to the nearest metre.

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The water behind a dam is normally released at a rate of 250000 litres per second - Leaving Cert Mathematics - Question 10 - 2021

Question 10

The water behind a dam is normally released at a rate of 250000 litres per second. (i) Find how long it takes to release 1 million cubic metres (1 000 000 m³) of wa... show full transcript

Worked Solution & Example Answer:The water behind a dam is normally released at a rate of 250000 litres per second - Leaving Cert Mathematics - Question 10 - 2021

Step 1

(a) (i) Find how long it takes to release 1 million cubic metres of water.

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Answer

To determine the time taken to release 1 million cubic metres of water, we start with the following calculations:

1 million cubic metres = 1,000,000 m³.

The flow rate of water is 250,000 litres per second, which converts to cubic metres as follows:

250,000 \text{ litres/second} = \frac{250,000}{1000} = 250 \text{ m³/second}.

Next, we calculate the time needed to release 1,000,000 m³:

\text{Time} = \frac{\text{Volume}}{\text{Flow Rate}} = \frac{1,000,000 \text{ m³}}{250 \text{ m³/second}} = 4000 \text{ seconds}.

To convert seconds to minutes:

\text{Time in minutes} = \frac{4000 \text{ seconds}}{60} \approx 66.67 \text{ minutes} \approx 67 \text{ minutes (to the nearest minute)}.

Step 2

(a) (ii) Find how many m³ of water were released in that 24 hour period.

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Answer

With the increased flow rate, we have:

\text{Increased Flow Rate} = 250,000 \text{ litres/second} \times 1.1 = 275,000 \text{ litres/second}.

Converting this to cubic metres:

275,000 \text{ litres/second} = \frac{275,000}{1000} = 275 \text{ m³/second}.

Now, calculating the volume of water released in 24 hours:

\text{Volume} = 275 \text{ m³/second} \times 60 \text{ seconds/min} \times 60 \text{ min/hour} \times 24 \text{ hours} = 2376000 \text{ m³}.

This can be written in the required form as:

2.376 \times 10^6 \text{ m³ (to 3 significant figures)}.

Step 3

(b) (i) How long will it take him to complete 3 full circuits of the trail?

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Answer

First, calculate the circumference of the circular trail:

D = 2\pi r = 2\pi(0.5) \approx 3.14 \text{ km}.

Now, for 3 circuits:

\text{Total Distance} = 3 \times 3.14 = 9.42 \text{ km}.

Time taken at a speed of 6 km/h:

T = \frac{D}{S} = \frac{9.42 \text{ km}}{6 \text{ km/h}} \approx 1.57 \text{ hours} \approx 94 \text{ minutes (to the nearest minute)}.

Step 4

(b) (ii) Find how long it will take her to complete her walk on day 5.

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Answer

Mary's walking distances over the 5 day period are:

Day 1: 3 km
Day 2: 3 km × 1.15 = 3.45 km
Day 3: 3.45 km × 1.15 = 3.97 km
Day 4: 3.97 km × 1.15 ≈ 4.56 km
Day 5: 4 km/h is her speed.

Now calculate the time taken on Day 5:

T = \frac{D}{S} = \frac{4.56 \text{ km}}{4 \text{ km/h}} = 1.14 \text{ hours} = 68.4 \text{ minutes} \approx 69 \text{ minutes (to the nearest minute)}.

Step 5

(b) (iii) How far will he travel until he meets Mary again?

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Answer

When John meets Mary, they continue walking at their respective speeds. Let’s denote the time taken for them to meet again as 't'.

In that time:

John travels at 6 km/h.
Mary travels at 4 km/h.

They are walking in opposite directions, so their relative speed is:

\text{Relative Speed} = 6 + 4 = 10 \text{ km/h}.

The total distance before they meet is equal to the circle's circumference (3.14 km):

\text{Time to meet again} = \frac{3.14 \text{ km}}{10 \text{ km/h}} \approx 0.314 \text{ hours} \approx 18.84 \text{ minutes}.

In this time, John travels:

\text{Distance} = D = 6 \text{ km/h} \times t \approx 6 \text{ km/h} \times 0.314 \text{ h} \\ = 1.884 \text{ km} \approx 1885 ext{ m (to the nearest metre)}.

The water behind a dam is normally released at a rate of 250000 litres per second - Leaving Cert Mathematics - Question 10 - 2021

Worked Solution & Example Answer:The water behind a dam is normally released at a rate of 250000 litres per second - Leaving Cert Mathematics - Question 10 - 2021

(a) (i) Find how long it takes to release 1 million cubic metres of water.

(a) (ii) Find how many m³ of water were released in that 24 hour period.

(b) (i) How long will it take him to complete 3 full circuits of the trail?

(b) (ii) Find how long it will take her to complete her walk on day 5.

(b) (iii) How far will he travel until he meets Mary again?

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