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Introduction: Pipes & Cisterns

  • Pipes and Cisterns problems are almost the same as those of Time and Work problems. 
  • Thus, if a pipe fills a tank in 6 hrs, then the pipe fills 1/6th of the tank in 1 hour. 
  • The only difference with Pipes and Cisterns problems is that there are outlets as well as inlets. 
  • Thus, there are agents (the outlets) which perform negative work too. 
  • The rest of the process is almost similar.
    Solved Examples: Time & Work | Quantitative for GMAT

Inlet

  • A pipe connected with a tank (or a cistern or a reservoir) is called an inlet, if it fills the tank. The work done by this is taken as Positive work.

Outlet

  • A pipe connected with a tank is called an outlet if it empties the tank and the work done by this is taken as the Negative work.

Basic Concept

  • The basic concept of Time and Work is similar to that across all arithmetic topics, i.e. the concept of proportionality. 
  • Efficiency is inversely proportional to the Time taken when the amount of work done is constant.Solved Examples: Time & Work | Quantitative for GMAT
  • This can be used to compare efficiencies and time taken across different groups in Time-Speed-Distance, efficiency is replaced by Speed, i.e. Speed is inversely proportional to Time when the Distance is constant. 
  • Pipes and Cisterns are just an application of Time and Work. Concept wise, it is one and the same.
  • In the above proportionality, Efficiency is replaced by Rate of filling.
    The equation, in this case, becomes:Solved Examples: Time & Work | Quantitative for GMAT

Question for Solved Examples: Time & Work
Try yourself:Three pipe P, Q and R can fill a tank In 12 minutes, 18 minutes and 24 minutes respectively. The pipe R is closed 12 minutes before the tank Is filled. In what time the tank is full?
View Solution

Introduction: Negative Work

  • Negative work increases the time in which work is to be completed. This application can be extended to cases involving Pipes and cisterns. 
  • Suppose there are two pipes in a Cistern. Pipe A is used to fill the Cistern and Pipe B is used to empty the Cistern. Here we say that Pipe B and Pipe A are working against each other. When a leak is developed in the Cistern, the leak forms the component of negative work, which slows down the completion of the task (in this case, the filling of the Cistern).

Example 1. A Cistern has three pipes A, B, and C. Pipe A can fill a Cistern in 10 hrs, Pipe B can fill a Cistern in 5 hrs while Pipe C can empty the Cistern in 20 hrs. If they are switched on at the same time; in how many hours will the Cistern be filled?

Solution:

  • In one hour, Pipe A can fill 100/10 = 10% of the Cistern.
  • In one hour, Pipe B can fill 100/5 = 20 % of the Cistern.
  • In one hour, Pipe C can empty 100/20 = 5 % of the Cistern.
  • If all three are working together, (10 + 20 – 5) = 25% of the Cistern will get filled in one hour, so it will take 4 hrs for the Cistern to fill.

Example 2. A tank can be filled by tap A in 6 hrs and by tap B in 3 hrs. But when they are open simultaneously to fill an empty tank, they take 3 hrs more than their normal Time. A hole is later discovered as the reason for the delay. Find the Time taken by the hole to empty the tank if it is completely filled.

Solution:

  • Tap A takes 6 hrs to fill, so in one hour it will fill 16.67 % of the tank.
  • Tap B takes 3 hrs to fill, so in one hour it will fill 33.33% of the tank.
  • Together they will fill 16.67% + 33.33% = 50 % of the tank.
  • They should take 100/50= 2 hrs to fill the tank. But they take 3 hrs more, because of the hole; they totally take 5 hrs to fill, i.e. they fill 20% in an hour.
  • This is possible if the hole empties 50-20 = 30% of the tank in an hour.
  • So, to completely empty the full tank, the hole will take 100/30 hrs = 3.33 hrs = 3 hrs and 20 mins.

Example 3. Two pipes A and B can fill a tank in 36 hours and 45 hours respectively. If both the pipes are opened simultaneously, how much time will be taken to fill the tank?

Solution:

  • Part filled by A alone in 1 hour = 1/36  
  • Part filled by B alone in 1 hour = 1/45  
    ∴ Part filled by (A + B) in 1 hour =
    Solved Examples: Time & Work | Quantitative for GMAT
  • Hence, both the pipes together will fill the tank in 20 hours.


Question for Solved Examples: Time & Work
Try yourself:Pipe A can fill a tank in ‘an’ hours. On account of a leak at the bottom of the tank, it takes thrice as long to fill the tank. How long will the leak at the bottom of the tank take to empty a full tank, when pipe A is kept closed?
View Solution

Question for Solved Examples: Time & Work
Try yourself:Three pipes A, B and C can fill a tank from empty to full in 30 minutes, 20 minutes and 10 minutes respectively. When the tank is empty, all the three pipes are opened. A, B and C discharge chemical solutions P, Q and R respectively. What is the proportion of solution R in the liquid in the tank after 3 minutes?
View Solution

Question for Solved Examples: Time & Work
Try yourself:Pipe A can fill a tank in 36 hours and pipe B can empty it in 45 hours. If both the pipes are opened simultaneously, how much time will be taken to fill the tank?
Solution. 
View Solution

The document Solved Examples: Time & Work | Quantitative for GMAT is a part of the GMAT Course Quantitative for GMAT.
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FAQs on Solved Examples: Time & Work - Quantitative for GMAT

1. What is the concept of Pipes & Cisterns in time and work problems?
Ans. Pipes and cisterns refer to a type of problem in time and work where the focus is on filling or emptying tanks or reservoirs. It involves calculating the time taken to fill or empty the tanks when different pipes or cisterns are working together or individually.
2. How can I determine the efficiency of a pipe or cistern in a time and work problem?
Ans. The efficiency of a pipe or cistern can be determined by calculating the work done by that particular pipe or cistern in a given time. Efficiency is often expressed as a fraction or percentage, representing the amount of work done per unit time.
3. What is negative work in time and work problems?
Ans. Negative work in time and work problems occurs when a pipe or cistern is emptying a tank or reservoir instead of filling it. It means that the pipe or cistern is removing water from the system, resulting in a decrease in the overall water level.
4. Can you provide an example of a time and work problem involving pipes and cisterns?
Ans. Sure! For example, if Pipe A can fill a tank in 6 hours and Pipe B can fill the same tank in 8 hours, how long will it take for both pipes to fill the tank when working together? The solution involves calculating the combined efficiency of both pipes and determining the time taken to fill the tank.
5. What are some key tips to solve time and work problems involving pipes and cisterns efficiently?
Ans. Some key tips to solve such problems efficiently include: - Identify the individual efficiencies of each pipe or cistern. - Determine whether the pipes are filling or emptying the tank. - Use the concept of combined efficiency when pipes work together. - Pay attention to units of time and make necessary conversions. - Solve step by step, keeping track of the work done by each pipe or cistern.
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