The water from one outlet, flowing at a constant rate, can fill a swimming pool in 9 hours. The water from a second outlet, flowing at a constant rate, can fill the same pool in 5 hours. If both outlets are used at the same time, approximately what is the number of hours required to fill the pool?
A) 0.22
B) 0.31
C) 2.50
D) 3.21
E) 4.56
time to fill a pool
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One approach is to assign a NICE NUMBER to the volume of the swimming pool. This number will work well with the two pieces of information (fill pool in 9 hours and fill pool in 5 hours).BlueDragon2010 wrote:The water from one outlet, flowing at a constant rate, can fill a swimming pool in 9 hours. The water from a second outlet, flowing at a constant rate, can fill the same pool in 5 hours. If both outlets are used at the same time, approximately what is the number of hours required to fill the pool?
A) 0.22
B) 0.31
C) 2.50
D) 3.21
E) 4.56
So, let's say that the volume of the pool is 45 gallons.
The water from one outlet, flowing at a constant rate, can fill a swimming pool in 9 hours
So, this outlet pumps at a rate of 5 gallons per hour
The water from a second outlet, flowing at a constant rate, can fill the same pool in 5 hours.
So, this outlet pumps at a rate of 9 gallons per hour
If both outlets are used at the same time. . .
The combined rate of both pumps = (5 gallons per hour) + (9 gallons per hour)
= 14 gallons per hour
Time = output/rate
At 14 gallons per hour, the time to pump 45 gallons = 45/14
= 3 3/14
= 3.something
= D
Cheers,
Brent
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A different approach relies on the fact that rate and time are inverses of one another. If it takes 5hrs to fill a pool (time), the rate is 1/5 pool per hour. This rule along with the fact that the sum of rates is the combined rates when machines work together simultaneously can lead to a very fast solution.
the rates (inverse of time) are 1/5 and 1/9 pool per hour. The combined rate is 1/5 + 1/9 = 14/45 pool per hour. The combined time (inverse of rate) is 45/14 hours, or a little bit more than 3 hours (45/15 = 3). The answer is D. The full solution below is taken from the GMATFix App.
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the rates (inverse of time) are 1/5 and 1/9 pool per hour. The combined rate is 1/5 + 1/9 = 14/45 pool per hour. The combined time (inverse of rate) is 45/14 hours, or a little bit more than 3 hours (45/15 = 3). The answer is D. The full solution below is taken from the GMATFix App.
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Solution:BlueDragon2010 wrote:The water from one outlet, flowing at a constant rate, can fill a swimming pool in 9 hours. The water from a second outlet, flowing at a constant rate, can fill the same pool in 5 hours. If both outlets are used at the same time, approximately what is the number of hours required to fill the pool?
A) 0.22
B) 0.31
C) 2.50
D) 3.21
E) 4.56
This problem is called a combined work problem. In this type of problem we use the formula:
Work (of machine 1) + Work (of machine 2) = Total Work Done
In this particular problem we can define "machine" as "outlet". We are given that the water from one outlet, flowing at a constant rate, can fill a swimming pool in 9 hours and that the water from a second outlet, flowing at a constant rate, can fill the same pool in 5 hours. It follows that the hourly rate for one outlet is 1/9 of the pool per hour and the rate of the other outlet is 1/5 of the pool per hour. Let's let T be the number of hours during which both outlets work together to fill the pool. We'll use the formula Work = Rate x Time to calculate the work accomplished by each outlet individually in filling the pool. We can enter these values into a simple table.
We can plug in the two work values for outlet one and outlet two into the combined worker formula. Note that the Total Work Done is "1" because the pool was filled, thus completing the job of filling the entire pool.
Work (of outlet 1) + Work (of outlet 2) = Total Work Done
T/9 + T/5 = 1
To eliminate the need for working with fractions, let's multiply the entire equation by 45.
45(T/9 + T/5 = 1)
5T + 9T = 45
14T = 45
T = 45/14 = 3 3/14 ≈ 3.21 hours
Answer: D
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Two of the slow outlets would fill the pool in 4.5 hours, and two of the fast outlets would fill the pool in 2.5 hours. Since we have one slow outlet and one fast outlet, the answer must be strictly between 2.5 and 4.5, and D is the only possible answer.
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