Mixing Problem... please help.. work shown

[johnq2k7]

A tank with a 1000 gallon capacity intially contains 500 gallons of water that is polluted with 50 lb of particulate matter. At time (t=0), pure water is added at a rate of 20 gal/min and the mixed solution is drained off at a rate of 10 gal/min. How much particulate matter is in the the tank when it reaches the point of overflowing?

work shown below:

Volume of Tank Capacity= 1000 gal
Intial Volume of Water= 500 gal
Intial Polluted Matter= 50 lb

Pure water Rate IN= 20 gal/min
Mixed Solution Rate OUT= 10 gal/min

Overflowing= excess of 1000 galloons

change in rate= change in rate in - change in rate out
= 20 gal/min - 10 gal/min
= 10 gal/min

change in rate therefore equals 10 gal/min

intial total amount of material in tank is : 500 gallons + 50 lbs
since 1 galloon equals approx. 8.34 lb

therefore, there is intially 917 galloons of material in the tank

how do i use this information that I processed to find the particulate matter once it reaches the point of overflowing which is (>=1000gal)

Please help me with this problem

 

[galactus]

At time t there are \(\displaystyle 500+(20-10)t=500+10t\) gallons of, say, brine in the tank so:

\(\displaystyle \frac{dy}{dt}=0-\frac{y}{500+10t}(10)=\frac{-y}{50+t}, \;\ \frac{dy}{dt}+\frac{1}{50+t}y=0\) and \(\displaystyle y(0)=50\).

\(\displaystyle {\mu}=e^{\int \frac{1}{50+t}dt}=e^{ln(50+t)}=50+t, \;\ (50+t)y=C, \;\ y=\frac{C}{50+t}\)

\(\displaystyle 50=\frac{C}{50}, \;\ C=2500, \;\ y=\frac{2500}{50+t}\)

The tank reaches overflowing when 500+10t=1000, t=50 minutes so \(\displaystyle y=\frac{2500}{50+50}=25 \;\ lbs\)

 

[johnq2k7]

At time t there are \(\displaystyle 500+(20-10)t=500+10t\) gallons of, say, brine in the tank so:

\(\displaystyle \frac{dy}{dt}=0-\frac{y}{500+10t}(10)=\frac{-y}{50+t}, \;\ \frac{dy}{dt}+\frac{1}{50+t}y=0\) and \(\displaystyle y(0)=50\).

\(\displaystyle {\mu}=e^{\int \frac{1}{50+t}dt}=e^{ln(50+t)}=50+t, \;\ (50+t)y=C, \;\ y=\frac{C}{50+t}\)

\(\displaystyle 50=\frac{C}{50}, \;\ C=2500, \;\ y=\frac{2500}{50+t}\)

The tank reaches overflowing when 500+10t=1000, t=50 minutes so \(\displaystyle y=\frac{2500}{50+50}=25 \;\ lbs\)

Thanks for your help and workout process... however... don't I need to convert the pariticulate matter from lbs to galloons.. how come this conversion is not needed?... thanks for your help.. appreciate it

 

[galactus]

You can convert if you want, but it ain't necessary. Different ways to tackle such a problem.

 

[Deleted member 4993]

In general, you cannot convert gallons(volume) to pounds(mass) - without knowing what it is (material - material property).

The number you quote - 1 gallon equals approx. 8.34 lb - is true for water. It will be different for different material.

In this problem there is an "unexpressed" assumption - the addition of particulates create negligible change in the volume of the mixture ( that is the volume of 500 gallons of water with 50 lb. particulate remains 500 gallons - but its mass changes from 4170 pounds to 4220 pounds).

 

[johnq2k7]

thanks.. now I fully understand how the lbs to gallon conversion was neglected...thanks for explaining the details

 

[galactus]

To reiterate, that is a good explanation SK gave. Like he said, this problem just said a particulate. I just used brine as an example of something because that is commonly used. We could have used oil or oreo cookies. Doesn't matter in this case.