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File:Airflow-Obstructed-Duct.png

Description A simulation using the navier-stokes differential equations of the aiflow into a duct at 0.003 m/s (laminar flow). The duct has a small obstruction in the centre that is paralell with the duct walls. The observed spike is mainly due to numerical limitations.

This script, which i originally wrote for scilab, but ported to matlab (porting is really really easy, mainly convert comments % -> // and change the fprintf and input statements)

Matlab was used to generate the image.


%Matlab script to solve a laminar flow
%in a duct problem

%Constants
inVel = 0.003; % Inlet Velocity (m/s)
fluidVisc = 1e-5; % Fluid's Viscoisity (Pa.s)
fluidDen = 1.3; %Fluid's Density (kg/m^3)

MAX_RESID = 1e-5; %uhh. residual units, yeah...
deltaTime = 1.5; %seconds?
%Kinematic Viscosity
fluidKinVisc = fluidVisc/fluidDen;

%Problem dimensions
ductLen=5; %m
ductWidth=1; %m

%grid resolution
gridPerLen = 50; % m^(-1)
gridDelta = 1/gridPerLen;
XVec = 0:gridDelta:ductLen-gridDelta;
YVec = 0:gridDelta:ductWidth-gridDelta; 

%Solution grid counts
gridXSize = ductLen*gridPerLen;
gridYSize = ductWidth*gridPerLen;

%Lay grid out with Y increasing down rows
%x decreasing down cols
%so subscripting becomes (y,x) (sorry)
velX= zeros(gridYSize,gridXSize);
velY= zeros(gridYSize,gridXSize);
newVelX= zeros(gridYSize,gridXSize);
newVelY= zeros(gridYSize,gridXSize);


%Set initial condition

for i =2:gridXSize-1
for j =2:gridYSize-1
velY(j,i)=0;
velX(j,i)=inVel;
end
end


%Set boundary condition on inlet
for i=2:gridYSize-1
velX(i,1)=inVel;
end

disp(velY(2:gridYSize-1,1));

%Arbitrarily set residual to prevent
%early loop termination
resid=1+MAX_RESID;

simTime=0;

while(deltaTime)
 count=0;
while(resid > MAX_RESID && count < 1e2)
 count = count +1;
for i=2:gridXSize-1
for j=2:gridYSize-1
newVelX(j,i) = velX(j,i) + deltaTime*( fluidKinVisc / (gridDelta.^2) * ...
(velX(j,i+1) + velX(j+1,i) - 4*velX(j,i) + velX(j-1,i) + ...
velX(j,i-1)) - 1/(2*gridDelta) *( velX(j,i) *(velX(j,i+1) - ...
velX(j,i-1)) + velY(j,i)*( velX(j+1,i) - velX(j,i+1))));

newVelY(j,i) = velY(j,i) + deltaTime*( fluidKinVisc / (gridDelta.^2) * ...
(velY(j,i+1) + velY(j+1,i) - 4*velY(j,i) + velY(j-1,i) + ...
velY(j,i-1)) - 1/(2*gridDelta) *( velY(j,i) *(velY(j,i+1) - ...
velY(j,i-1)) + velY(j,i)*( velY(j+1,i) - velY(j,i+1))));
end
end

%Copy the data into the front 
for i=2:gridXSize - 1
for j = 2:gridYSize-1
velX(j,i) = newVelX(j,i);
velY(j,i) = newVelY(j,i);
end
end

%Set free boundary condition on inlet (dv_x/dx) = dv_y/dx = 0
for i=1:gridYSize
velX(i,gridXSize)=velX(i,gridXSize-1);
velY(i,gridXSize)=velY(i,gridXSize-1);

    end

    %y velocity generating vent
    for i=floor(2/6*gridXSize):floor(4/6*gridXSize)
        velX(floor(gridYSize/2),i) = 0;
        velY(floor(gridYSize/2),i-1) = 0;
    end
    
%calculate residual for 
%conservation of mass
resid=0;
for i=2:gridXSize-1
for j=2:gridYSize-1
%mass continuity equation using central difference
%approx to differential
resid = resid + (velX(j,i+ 1)+velY(j+1,i) - ...
(velX(j,i-1) + velX(j-1,i)))^2;
end
end

resid = resid/(4*(gridDelta.^2))*1/(gridXSize*gridYSize);
fprintf('Time %5.3f \t log10Resid : %5.3f\n',simTime,log10(resid));


    

simTime = simTime + deltaTime;
end
mesh(XVec,YVec,velX)
deltaTime = input('\nnew delta time:');
end
%Plot the results
mesh(XVec,YVec,velX)


Date 2007-02-24 (original upload date)
Source Originally from en.wikipedia; description page is/was here.
Author Original uploader was User A1 at en.wikipedia
Permission
( Reusing this file)

Released into the public domain (by the author).

Licensing

PD-icon.svg This work has been released into the public domain by its author, User A1 at the wikipedia project. This applies worldwide.

In case this is not legally possible:
User A1 grants anyone the right to use this work for any purpose, without any conditions, unless such conditions are required by law.

The following pages on Schools Wikipedia link to this image (list may be incomplete):

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