Calculating Fill Time for Inflatable Pool Using Garden Hose

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To calculate the fill time for an inflatable pool using a garden hose, the volume of the pool and the flow rate of the water must be determined. The volume of the pool was initially miscalculated by using the diameter instead of the radius, leading to incorrect area calculations for the hose. The volumetric flow rate is essential, and the relationship between mass flow rate and volumetric flow rate requires knowledge of density. After correcting the calculations, the user successfully found both the mass flow rate and volumetric flow rate. The discussion emphasizes the importance of accurate measurements and understanding fluid dynamics in solving the problem.
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Homework Statement



To fill a child's inflatable wading pool you use a garden hose with a diameter of 2.8 cm. Water flows from this hose with a speed of 1.1 m/s. How long will it take to fill the pool to a depth of 32 cm if it is circular and has a diameter of 2.7 m?

Homework Equations


delta m=p1 A1 v1 delta t
(p=density, A=area, v=velocity, t=time)

A1 v1=A2 v2

Q=A v

idk if there is another equation that deals with time, i can't find any.

The Attempt at a Solution


since everything is dealing with water, i didn't really consider density.

the amount of water needed:
V= pi r^2 h=pi (1.35)^2 (.32)= 1.83 m^3

the area of the hose is:
A= pi r^2= pi (.014)^2= 6.16e-4 m^2

Q=A v=6.16e-4 (1.1)=6.78e-4 m^3/s

mass flow rate= .6776 kg/s

i don't really know where to go from here...
 
Last edited:
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first, your volume of pool measurement is a little wrong. You've used the diameter as a radius in your equqtion.
You've also made the sam mistake in calculating the cross sectional area of the hose.
delta m over delta t will give you your mass flow rate. But you need your volumetric flow rate. so how do you turn mass in a volume (hint: pensity is required)

keep trying and le tme know.
 
my typing is terrible this morning, sorry for the spelling mistakes. going to get some more coffee :smile:
 
redargon said:
first, your volume of pool measurement is a little wrong. You've used the diameter as a radius in your equqtion.
You've also made the sam mistake in calculating the cross sectional area of the hose.
delta m over delta t will give you your mass flow rate. But you need your volumetric flow rate. so how do you turn mass in a volume (hint: pensity is required)

keep trying and le tme know.

i fixed the problems and hopefully they are right. i found the mass flow rate and also the volumetric flow rate. we haven't learned about pensity in our class yet...so there has to be a different way.
 
i figured it out. thanks :)
 
pensity was a spelling mistake for density, sorry. Glad you got it, no prob.
 

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