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unable to plot centerline velocity
Posted 2011年1月15日 GMT-5 16:01 Studies & Solvers Version 4.1 5 Replies
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I am wondering if someone can help me plot the above graph.
I tried to plot it using 1D plot and a line option but it is not working. I even tried the 2D plot but even that is not working.
Thanks for the help.
Sincerely,
Sirisha
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you are in 3D so you need a Data Sets - Cut Line 3D (and not 1D), then you make a 1D plot from the Cut Line source and it should go
Another comment, particularly in cfd its important to have initial conditions close to the results, to help the solver. You haved all initial conditions at default "0". But you could as well set the parabolic velocity field here too and a first pressure drop along your pipe (using Poiseuille law)
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Good luck
Ivar
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Sirisha
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for the solution right click Data set selelct 3D cut line (and define your 2 points)
in result plot, right click and select 1D plot, in the 1D plot window, , top, select solution 3D cut line. Right click 1D plot and select line plot
for the initial conditions, copy your inflow velocity profile of the type
(note Q [m^3/s]=v0[m/s]/SectionArea[m^2])=v0[m/s]/(pi*(R[m])^2)
v0[m/s]*2*(1-(x^2+y^2)/R_tube[m]^2)
or define a cylindrical (i.e.sys2) coordinate system along the tube and use the formula
v0[m/s]*2*(1-(sys2.r/R_tube[m])^2)
Where R_tube is the interiour tube radius, defined either as a parameter , or calculated with a line integration
check the output you should have about 2*v0 on axis, 0 on the non slip walls (this works also approx. for an elliptical tube shape, or you elaborate the formula further)
Then for the Poiseille law pressure drop it states (see i.e. wiki en.wikipedia.org/wiki/Poiseuille) for the visuosity "mu"
Dp[Pa] = 8*mu[Pa*s]*V0[m/s]/(Radius[m])^2*Length[m]
carefull with the max and average velocity, but even if you are a factor 2 off, it's mostly better than all "0" (except if you inverse the sign ;)
Then you need to replace , in the initial conditions "Length" by (for a pipe of axis aong Z, change if different)
Dp[Pa](z) = 1*8*mu[Pa*s]*V0[m/s]/(Radius[m])^2*Length[m]*(1-z/Total_length)
And get the sign, correct.
For that it's always good to start to ask COMSOL to "get the initial values" by a right-click on Solver - Dependent variable - Compute to selected. Then you can make the plots of the initial conditions
But all this is plain Physics, it's not my jo to train your for that, or ?.
For me that is the main reason of using COMSOL ...
PS: pls check carefully my formulas, as typos are quickly done
Have fun Comsoling
Ivar
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I mentioned thanks for letting me know about how to plot the 3D velocity and also for giving me the tip of setting the initial values = inlet condition:)
I am not sure why you explained it in so much detail. I am sorry if my earlier reply was a bit confusing. I was just conveying my thanks!
Anyway .... thanks once again
sirisha
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well with the details, you, and other can probably better understand the idea, no ?
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Good luck
Ivar