Rate of change (cone problem)

R.C. · 2011-08-09 05:32:03

Water is leaking out of a conical tank (Vertex of the cone pointing down) at a rate of 10,000 cm^3/min at the same time that water is being pumped into the tank at a constant rate. The tank has a height of 6m and the diameter at the top is 4m. If the water level is rising at a rate of 20cm/min when the height of the water is 2m, find the rate at which water is being pumped into the tank.

V=1/3(pi)r^2h

Once I replace r in terms of h and then differentiate both sides I get:

dV/dt=(pi)h^2/9*dh/dt.

Then I plug in the converted height of 200cm and 20cm for dh/dt. Is that correct?

And lastly I add the 10,000cm^3/min to the result of the previous equation?

bobbym · 2011-08-09 06:34:20

Hi;

Then I plug in the converted height of 200cm and 20cm for dh/dt. Is that correct?

Your equation for this step is? Need to see it to check it.

R.C. · 2011-08-09 08:22:49

dV/dt= (pi)200^2/9*20.

The answer I got from that equation is 279252 cm^3/min. Then I added the 10,000 cm^3/min to get a rate of
289252 cm^3/min.

bobbym · 2011-08-09 08:47:46

Hi;

That answer is correct and so is your dV / dt

Actually though when the answer is rounded it is closer to 289 253 cm^3/ min

gnitsuk · 2011-08-10 23:19:30

*THIS LINE IS INCORRECT - SEE MY POST BELOW*

Radius a top of cone = 200cm, cone is 600cm high so radius at 200cm high is 200/3 cm. so

so we have

So my answer is

I appreciate I differ in the above expression for dv/dh by a factor of 3. Is it my mistake somewhere?

Last edited by gnitsuk (2011-08-11 01:33:51)

bobbym · 2011-08-10 23:36:17

Hi gnitsuk;

I am getting a 9 there. Let me check my notes and see if what I have is okay.

I can not find if you made a mistake, here is what I did back then.

R is the rate that the water is coming in.

Boxed area looks like a chain rule.

Forgot units!

gnitsuk · 2011-08-11 01:29:39

Quite right. Good fun. The problem is mine.

I write:

And that is true, at any given instant in time for the cone of water.

I next need to calculate

BUT, for the water cone, r is a function of h, in fact r = h/3.

However, I differentiated as if r were a constant wrt h.

I should have substituted in r = h/3 to give:

And THEN differentiated wrt h. Then we of course agree.

Lesson learned (again!).

bobbym · 2011-08-11 01:30:53

Hi gnitsuk;

Thanks for pointing that out. I did not see that either.

TMorgan · 2011-08-11 03:22:39

I got the same answer but there did not need to be any calculus involved. At 2m the level is rising at 20cm/min. So at that instant the amount of volume increase per minute is a cylinder with a radius of 2/3m and height of 0.2m. That volume is (pi)*(2/3)^2*0.2 and throw in a factor of 10^6 to turn m^3 into cm^3. Add the 10,000cc/min that is going out and that's it. Same answer.

This is an algebra/geometry problem all dressed up to look like a calculus problem. Watch out for these, especially when taking a timed test.

Math Is Fun Forum

#1 2011-08-09 05:32:03

Rate of change (cone problem)

#2 2011-08-09 06:34:20

Re: Rate of change (cone problem)

#3 2011-08-09 08:22:49

Re: Rate of change (cone problem)

#4 2011-08-09 08:47:46

Re: Rate of change (cone problem)

#5 2011-08-10 23:19:30

Re: Rate of change (cone problem)

#6 2011-08-10 23:36:17

Re: Rate of change (cone problem)

#7 2011-08-11 01:29:39

Re: Rate of change (cone problem)

#8 2011-08-11 01:30:53

Re: Rate of change (cone problem)

#9 2011-08-11 03:22:39

Re: Rate of change (cone problem)

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