Goodday . i wonder if anyone can help with this .
I looking for the formula to the below problem inorder to use same to transpose in case i shoild need the pipe size in another case
Two tanks , tank A and tank B.
How much time in hours to fill tank B. Where Tank A is a full water tank( always being filled up from the top)of 100m^3 with a pipe on the bottom filling into tank B , an empty water tank of 50m^3 . The pipe is 100mm in diametre.
Both tanks are 10 m high
And where 1m^3 of water = 1 ton
The problem I.m having is that the flow rate slows down as the tank fills'
decanting one tank into another
Re: decanting one tank into another
This is non-steady flow problem for which differential equation should be written.
I will try to provide one later today.
I will try to provide one later today.
Pipe flow calculations - since 2000
Re: decanting one tank into another
Here is how you can start:
Pressure drop in pipe due to friction is:
Dp=rho * f * L * V^2 / (2 * D), or
(A) Dp = 8 * rho * f *L * Q^2 / (D^5 * pi^2);
where is:
(B) Dp = rho * g * (H - Dh); - available energy due to level difference if both reservoirs are on atmospheric pressures
(Dh - is the change in elevation due to tank B being filled in time)
Dp - pressure drop due to friction [Pa]
rho - fluid density [kg/m3]
f - friction factor [ - ]
L - pipe length [m]
V - flow velocity [m/s]
D - pipe diameter [m]
pi = 3.1416
Q - flow rate - [m3/s]
Flow rate in tank B is: Q = Dh * D^2 * pi / 4 * Dt,
where is
Dt - change in time
Dh - change in level
As (A) has to be equal to (B) (if local resistances are negligible) than we get:
rho * g * (H - Dh) = 8 * rho * f *L * Q^2 / (D^5 * pi^2)
g * (H - Dh) = (f * L / (2 * D)) * (Dh / Dt)^2
Dt^2 = (f * L / (2 * D * g)) * ((Dh^2)/(H - Dh))
where is once again:
Dh - change in elevation - rise of level in tank B
Dt - time change
f - friction factor - for turbulent flow it is constant value
L - pipe length
D - pipe diameter
H - elevation difference on the start of filling
As result of this equation you can get how the elevation h will change in respect to time change t with start conditions - when t=0, elevation h - equals some height.
This is now mathematical problem - differential equation for which I (or you) have to take a look some where for solution.
Hope this gives some clue...
Pressure drop in pipe due to friction is:
Dp=rho * f * L * V^2 / (2 * D), or
(A) Dp = 8 * rho * f *L * Q^2 / (D^5 * pi^2);
where is:
(B) Dp = rho * g * (H - Dh); - available energy due to level difference if both reservoirs are on atmospheric pressures
(Dh - is the change in elevation due to tank B being filled in time)
Dp - pressure drop due to friction [Pa]
rho - fluid density [kg/m3]
f - friction factor [ - ]
L - pipe length [m]
V - flow velocity [m/s]
D - pipe diameter [m]
pi = 3.1416
Q - flow rate - [m3/s]
Flow rate in tank B is: Q = Dh * D^2 * pi / 4 * Dt,
where is
Dt - change in time
Dh - change in level
As (A) has to be equal to (B) (if local resistances are negligible) than we get:
rho * g * (H - Dh) = 8 * rho * f *L * Q^2 / (D^5 * pi^2)
g * (H - Dh) = (f * L / (2 * D)) * (Dh / Dt)^2
Dt^2 = (f * L / (2 * D * g)) * ((Dh^2)/(H - Dh))
where is once again:
Dh - change in elevation - rise of level in tank B
Dt - time change
f - friction factor - for turbulent flow it is constant value
L - pipe length
D - pipe diameter
H - elevation difference on the start of filling
As result of this equation you can get how the elevation h will change in respect to time change t with start conditions - when t=0, elevation h - equals some height.
This is now mathematical problem - differential equation for which I (or you) have to take a look some where for solution.
Hope this gives some clue...
Pipe flow calculations - since 2000