Question

Two drainpipes working together can drain a pool in 12 hours. Working​ alone, the smaller pipe would take 18 hours longer than the larger pipe to drain the pool. How long would it take the smaller pipe alone to drain the​ pool?

Answer 1

36hr

Explanation:

Time of both working together `t_b=12`hr

Time of small pipe `t_s` = (time of large pipe) `+ 18`

Let time of large pipe `= x`

`t_s=x + 18`

For pipes in parallel `1/T=1/t_1+1/t_2`

`1/12= 1/ (x +18)+ 1/x`

`x/12= x/ (x +18) + x/ x`

`(x*(x +18))/12= x/ 1 + (x +18)`

`x^2+18x = 12*x + 12*x +216`

`x^2-6x - 216= 0`

`(x+12)(x-18)=0`

`x = -12 or 18`
but time can't be -ve so

`x=18`hr

so `t_s =18 + 18 = 36`hr

Answer 2

`36\ \text{hrs`

Explanation:

Let `x\ \text{hrs}` be the time taken by the smaller pipe alone to drain a pool of volume say `V` . Then the time taken by the larger pipe alone to drain the same pool of volume `V` will be `(x-18)\ text{hrs}`

Now, draining rate of smaller pipe `=V/x`

Similarly, draining rate of larger pipe `=V/{x-18}`

Given that both the pipes working together can drain the same pool of volume `V` in `12` hours hence we have

`\text{total volume drained by both pipes together in 12 hrs}`

`= \text{volume of pool}`

`\therefore 12(V/x+V/{x-18})=V`

`12({x-18+x}/{x(x-18)})=1`

`12(2x-18)=x(x-18)`

`x^2-42x+216=0`

`x^2-36x-6x+216=0`

`x(x-36)-6(x-36)=0`

`(x-36)(x-6)=0`

`x-36=0, x-6=0`

`x=36, 6`

But `x>18` hence

`x=36`

hence, the time taken by the smaller pipe alone to drain the pool is `36\ \text{hrs`