design of journal bearing

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matlab coder on 2 Jan 2021

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Commented: matlab coder on 3 Jan 2021

d=input('enter a diameter value:'); %journal diameter (m)
l=input('enter a length value:');   %bearing length (m)
r=d/2;                              %radius (m)
c=input('enter a radial clearance:'); % radial clearance (m)
T1=input('assign an inlet temperature:'); %inlet temperature (celcius)
delta_T=input('enter temperature rise value:'); %assumed temperature rise (celcius)
W=input('enter a radial load on journal:');     %radial load on journal (N)
n_s=input('enter journal speed value of shaft:');       %journal speed (rev/sec)
P=W/(l*d);                                        %bearing pressure (N/m^2)
Tavg_vector=[10:10:140];                        %average temperature vector 
abs_vis_vector=[500 190 90 45 28 18 12 9 6.5 5.2 4.2 3.2 2.8 2.6]; % absolute viscosity vector
Tavg=T1+(delta_T/2);                            %average temperature (celcius)
fabs_vis_vector=csapi(Tavg_vector,abs_vis_vector); %cubic spline interpolation 
absolute_viscosity_value=fnval(fabs_vis_vector,Tavg); %absolute viscosity value mPa.s
absolute_viscosity_value=absolute_viscosity_value*10^-3; %absolute viscosity value Pa.s
Sc=((absolute_viscosity_value*n_s)/P)*(r/c)^2;           %sommerfeld number
%performance parameters for corresponding l/d ratio
if l/d==1
    % for l/d=1 performance parameters
    S_1=[0.0188 0.0446 0.121 0.264 0.631 1.33 ];
    % the corresponding vector for the minimum film thickness variable,h0/c
    hoc_1=[0.1 0.2 0.4 0.6 0.8 0.9 ];
    % the corresponding vector for the coefficient of friction variable, Rf /c
    Rfc_1=[1.05 1.70 3.2 5.79 12.8 26.4];
    % the corresponding vector for the volumetric oil-flow rate, Q/ (RcnL)
    Qc_1=[4.74 4.62 4.33 3.99 3.59 3.37];
    % the corresponding vector for side leakage flow/total flow, Qs/Q
    Qsc_1=[0.919 0.842 0.680 0.497 0.280 0.150]; 
elseif l/d==0.5
    % for l/d=0.5 performance parameters
    S_2=[0.0313 0.0923 0.319 0.779 2.03 4.31];
    % the corresponding vector for the minimum film thickness variable,h0/c
    hoc_2=[0.1 0.2 0.4 0.6 0.8 0.9];
     % the corresponding vector for the coefficient of friction variable, Rf /c
    Rfc_2=[1.60 3.26 8.10 17.0 40.9 85.6];
    % the corresponding vector for the volumetric oil-flow rate, Q/ (RcnL)
    Qc_2=[5.69 5.41 4.85 4.29 3.72 3.43];
    % the corresponding vector for side leakage flow/total flow, Qs/Q
    Qsc_2=[0.939 0.874 0.730 0.552 0.318 0.173];
elseif l/d==0.25
    % for l/d=0.25 performance parameters
    S_3=[0.0736 0.261 1.07 2.83 7.57 16.2];
    % the corresponding vector for the minimum film thickness variable,h0/c
    hoc_3=[0.1 0.2 0.4 0.6 0.8 0.9];
    % the corresponding vector for the coefficient of friction variable, Rf /c
    Rfc_3=[ 3.50 8.8 26.7 61.1 153.0 322.0];
    % the corresponding vector for the volumetric oil-flow rate, Q/ (RcnL)
    Qc_3=[5.91 5.60 4.99 4.37 3.76 3.45 ];
    % the corresponding vector for side leakage flow/total flow, Qs/Q
    Qsc_3=[0.945 0.884 0.746 0.567 0.330 0.180 ];
elseif l/d==inf 
    % for l/d=inf performance parameters
    S_4=[0.0115 0.021 0.0389 0.0626 0.123 0.240];
    % the corresponding vector for the minimum film thickness variable,h0/c
    hoc_4=[0.1 0.2 0.4 0.6 0.8 0.9];
    % the corresponding vector for the coefficient of friction variable, Rf /c
    Rfc_4=[0.961 1.20 1.52 2.57 4.80];
    % the corresponding vector for the volumetric oil-flow rate, Q/ (RcnL)
    Qc_4=[0.760 1.56 2.26 2.83 3.03];
    % the corresponding vector for side leakage flow/total flow, Qs/Q
    Qsc_4=[0 0 0 0 0 0 0 0 0];
end
if l/d==1
% To interpolate the data, the MATLAB function csapi(X,Y) is used:
fhoc_1 = csapi( S_1, hoc_1 );
ffc_1 = csapi( S_1, Rfc_1);
fQR_1 = csapi( S_1, Qc_1);
fQs_1 = csapi( S_1, Qsc_1);
% The values of the interpolated data functions at Sc are calculated with:
hc = fnval(fhoc_1, Sc); % ho/c 
fc = fnval(ffc_1, Sc);  %(r/c)f
Qc = fnval(fQR_1, Sc);  % Q/(r c n L)
Qsc= fnval(fQs_1, Sc);  % Qs/Q 
elseif l/d==0.5
% To interpolate the data, the MATLAB function csapi(X,Y) is used:
fhoc_2 = csapi( S_2, hoc_2);
ffc_2 = csapi( S_2, Rfc_2);
fQR_2 = csapi( S_2, Qc_2);
fQs_2 = csapi( S_2, Qsc_2);
% The values of the interpolated data functions at Sc are calculated with:
hc = fnval(fhoc_2, Sc); % ho/c
fc = fnval(ffc_2, Sc);  %(r/c)f
Qc = fnval(fQR_2, Sc);  % Q/(r c n L)
Qsc= fnval(fQs_2, Sc);  % Qs/Q
elseif l/d==0.25
% To interpolate the data, the MATLAB function csapi(X,Y) is used:
fhoc_3= csapi( S_3, hoc_3 ); 
ffc_3= csapi( S_3, Rfc_3 );  
fQR_3= csapi( S_3, Qc_3 );   
fQs_3= csapi( S_3, Qsc_3 );  
% The values of the interpolated data functions at Sc are calculated with:
hc = fnval(fhoc_3, Sc);  % ho/c
fc = fnval(ffc_3, Sc);   %(r/c)f
Qc = fnval(fQR_3, Sc);   % Q/(r c n L)
Qsc= fnval(fQs_3, Sc);   % Qs/Q
else l/d==inf
% To interpolate the data, the MATLAB function csapi(X,Y) is used:
fhoc_4 = csapi( S_4, hoc_4 );
ffc_4 = csapi( S_4, Rfc_4 );
fQR_4 = csapi( S_4, Qc_4 );
fQs_4= csapi( S_4, Qsc_4 );
% The values of the interpolated data functions at Sc are calculated with:
hc = fnval(fhoc_4, Sc);  % ho/c
fc = fnval(ffc_4, Sc);   %(r/c)f
Qc = fnval(fQR_4, Sc);   % Q/(r c n L)
Qsc= fnval(fQs_4, Sc);   % Qs/Q
end 

4 types of l/d ratio is given on the chart as it seen. but when we write a l/d ratio which is not given on the chart we use interpolation to found it. for example if ı want to find l/d=0.60 how can ı write ıts matlab code and calculate it?

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Answer 1

Cris LaPierre on 2 Jan 2021

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I suggest having a look at this answer.

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matlab coder on 3 Jan 2021

% for l/d=1 performance parameters
    S_1=[0.0188 0.0446 0.121 0.264 0.631 1.33 ];
     % the corresponding vector for the volumetric oil-flow rate, Q/ (RcnL)
    Qc_1=[4.74 4.62 4.33 3.99 3.59 3.37];
    % for l/d=0.5 performance parameters
    S_2=[0.0313 0.0923 0.319 0.779 2.03 4.31];
    % the corresponding vector for the volumetric oil-flow rate, Q/ (RcnL)
    Qc_2=[5.69 5.41 4.85 4.29 3.72 3.43];
    % for l/d=0.25 performance parameters
    S_3=[0.0736 0.261 1.07 2.83 7.57 16.2];
    % the corresponding vector for the volumetric oil-flow rate, Q/ (RcnL)
    Qc_3=[5.91 5.60 4.99 4.37 3.76 3.45 ];
    % for l/d=inf performance parameters
    S_4=[0.0115 0.021 0.0389 0.0626 0.123 0.240];
    % the corresponding vector for the volumetric oil-flow rate, Q/ (RcnL)
    Qc_4=[0.760 1.56 2.26 2.83 3.03];
    

these are the exracted data from the chart but ı still cant solve the proble with your suggestion. can you show me on an example from these data sets. for example can you calculate for l=0.2 and d=0.5 and S=0.20. how can ı find the corresponding Qc value? thank you in advance ı am so glad that you help me

Cris LaPierre on 3 Jan 2021

Edited: Cris LaPierre on 3 Jan 2021

Ok, I put a little more time into this. With one of the lines having a ratio of inf, you can't use interp1 to get the final Qc value. Here's how I was able to do it.

First step is to find the Qc value for each of the 4 lines at your desired S value. You can do this visually or, if you have a decent vector of points representing each line, use interp1. These results represent the inputs

,

and

in the interpolation equation provided by the authors.

If you are needing to do this a lot, it is to your benefit to get a good vector of points for each line, as that will ultimately determine the accuracy of your interpolated value. Also note your Qc_4 vector only had 5 points. It appeared to be missing the first value. I used the graph to estimate a value of 0.4 @S=0.0115.

% Known values
% for l/d=1 performance parameters
S_1=[0.0188 0.0446 0.121 0.264 0.631 1.33 ];
Qc_1=[4.74 4.62 4.33 3.99 3.59 3.37];
% for l/d=0.5 performance parameters
S_2=[0.0313 0.0923 0.319 0.779 2.03 4.31];
Qc_2=[5.69 5.41 4.85 4.29 3.72 3.43];
% for l/d=0.25 performance parameters
S_3=[0.0736 0.261 1.07 2.83 7.57 16.2];
Qc_3=[5.91 5.60 4.99 4.37 3.76 3.45 ];
% for l/d=inf performance parameters
S_4=[0.0115 0.021 0.0389 0.0626 0.123 0.240];
Qc_4=[0.4 0.760 1.56 2.26 2.83 3.03];
% interpolate to get y value of each line at Sq
Sq = 0.20;
y1 = interp1(S_1,Qc_1,Sq);
y12 = interp1(S_2,Qc_2,Sq);
y14 = interp1(S_3,Qc_3,Sq);
yinf = interp1(S_4,Qc_4,Sq);

Now that you have the 4 y values for a specific S value, you can then use the interpolation equation to compute the Qc value for any

ratio between infinity and 0.25. I defined the interpolation equation as an anonymous function. This allows me to easly calculate the Qc value by passing in the values for l,d,yinf,y1,y12,y14. This allows me to reuse the equation.

% desired ratio parameters
l=0.2;
d = 0.5;
% Create interpolatoin equation
ld=@(l,d,ying,y1,y12,y14) (-(1-l/d).*(1-2*l/d).*(1-4*l./d)*yinf/8 + (1-2*l./d).*(1-4*l./d)*y1/3 -(1-l./d).*(1-4*l./d).*y12/4 + (1-l./d).*(1-2*l./d)*y14/24)./(l/d).^3;
% Call interpolation equation with specific inputs
y=ld(l,d,yinf,y1,y12,y14)
y = 5.5067

Cris LaPierre on 3 Jan 2021

In this case, yes. The result of yinf is NaN because you have not defined values of Qc_4 beyond S_4=0.240. This causes the equation for y to return NaN.

When you go beyond your known data, that is called extrapolation. It is possible to exrapolate with interp1, but given the shape of your yinf line, I think it would be better to add more data points to your S_4 and Qc_4 vectors.

matlab coder on 3 Jan 2021

ok thank you ı will rearrange my data table.

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Answer 2

Alan Stevens on 3 Jan 2021

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Here's an example for l/d = 1/4. Note that because the S scale is logarithmic, it's best to interpolate logarithmically:

    S_3=[0.0736 0.261 1.07 2.83 7.57 16.2];
    % the corresponding vector for the volumetric oil-flow rate, Q/ (RcnL)
    Qc_3=[5.91 5.60 4.99 4.37 3.76 3.45 ];
   LOGS_3 = log10(S_3);
   yqtr = @(S) interp1(LOGS_3,Qc_3,log10(S));
   S = 0.08:0.01:10;
    semilogx(S_3,Qc_3,'o'),grid
    hold on
    semilogx(S,yqtr(S))

I'm not sure why you have a different set of values of S for each curve, as they all cover broadly the same range.

Also, I'd be inclined to pick off more than 6 pairs of points for each curve.

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matlab coder on 3 Jan 2021

ı dont know how to express myself but ı guess ı couldnt describe my problem clearly. as it seen on the first code, when ı enter daiemeter value and length value and if they are 1, 1/2 or 1/4 ı calculate them with the data that ı have in tabular form using by "csapi" and "fnval" function. but when l/d=0.4 or 0.8 or 0.6, ı mean for the values that are not given on the chart how can ı find the corresponding Qc value? look, when ı run the code given below with a entered values the program calculate many parameters. you can check by hand when ı write l=0.20 and d=0.20 this means l/d=1. and S value is calculated on the program 0.4158. and as we can see on the chart for l/d=1 and S=0.4158 Qc value is about 3.75. and this program calculate it. and also many more parameters that i didnt share here. now my questıon is that how can ı solve if ı enter a l/d ratio which is not on the chart. ı mean differ from 1, 1/2 1/4 and inf. thank you

% purpose:
% To calculate performance parameters and temperature rise by user specified values
%        Date                   Programmer
%        ====                   ==========
%       31/12/20                M. AKGÖK
% some inputs specified by designer 
d=input('enter a diameter value:'); %journal diameter (m)
l=input('enter a length value:');   %bearing length (m)
r=d/2;                              %radius (m)
c=input('enter a radial clearance:'); % radial clearance (m)
T1=input('assign an inlet temperature:'); %inlet temperature (celcius)
delta_T=input('enter temperature rise value:'); %assumed temperature rise (celcius)
W=input('enter a radial load on journal:');     %radial load on journal (N)
n_s=input('enter journal speed value of shaft:');       %journal speed (rev/sec)
P=W/(l*d);                                        %bearing pressure (N/m^2)
Tavg_vector=[10:10:140];                        %average temperature vector 
abs_vis_vector=[500 190 90 45 28 18 12 9 6.5 5.2 4.2 3.2 2.8 2.6]; % absolute viscosity vector
Tavg=T1+(delta_T/2);                            %average temperature (celcius)
fabs_vis_vector=csapi(Tavg_vector,abs_vis_vector); %cubic spline interpolation 
absolute_viscosity_value=fnval(fabs_vis_vector,Tavg); %absolute viscosity value mPa.s
absolute_viscosity_value=absolute_viscosity_value*10^-3; %absolute viscosity value Pa.s
Sc=((absolute_viscosity_value*n_s)/P)*(r/c)^2;           %sommerfeld number
%performance parameters for corresponding l/d ratio
if l/d==1
    % for l/d=1 performance parameters
    S_1=[0.0188 0.0446 0.121 0.264 0.631 1.33 ];
    % the corresponding vector for the minimum film thickness variable,h0/c
    hoc_1=[0.1 0.2 0.4 0.6 0.8 0.9 ];
    % the corresponding vector for the coefficient of friction variable, Rf /c
    Rfc_1=[1.05 1.70 3.2 5.79 12.8 26.4];
    % the corresponding vector for the volumetric oil-flow rate, Q/ (RcnL)
    Qc_1=[4.74 4.62 4.33 3.99 3.59 3.37];
    % the corresponding vector for side leakage flow/total flow, Qs/Q
    Qsc_1=[0.919 0.842 0.680 0.497 0.280 0.150]; 
elseif l/d==0.5
    % for l/d=0.5 performance parameters
    S_2=[0.0313 0.0923 0.319 0.779 2.03 4.31];
    % the corresponding vector for the minimum film thickness variable,h0/c
    hoc_2=[0.1 0.2 0.4 0.6 0.8 0.9];
     % the corresponding vector for the coefficient of friction variable, Rf /c
    Rfc_2=[1.60 3.26 8.10 17.0 40.9 85.6];
    % the corresponding vector for the volumetric oil-flow rate, Q/ (RcnL)
    Qc_2=[5.69 5.41 4.85 4.29 3.72 3.43];
    % the corresponding vector for side leakage flow/total flow, Qs/Q
    Qsc_2=[0.939 0.874 0.730 0.552 0.318 0.173];
elseif l/d==0.25
    % for l/d=0.25 performance parameters
    S_3=[0.0736 0.261 1.07 2.83 7.57 16.2];
    % the corresponding vector for the minimum film thickness variable,h0/c
    hoc_3=[0.1 0.2 0.4 0.6 0.8 0.9];
    % the corresponding vector for the coefficient of friction variable, Rf /c
    Rfc_3=[ 3.50 8.8 26.7 61.1 153.0 322.0];
    % the corresponding vector for the volumetric oil-flow rate, Q/ (RcnL)
    Qc_3=[5.91 5.60 4.99 4.37 3.76 3.45 ];
    % the corresponding vector for side leakage flow/total flow, Qs/Q
    Qsc_3=[0.945 0.884 0.746 0.567 0.330 0.180 ];
elseif l/d==inf 
    % for l/d=inf performance parameters
    S_4=[0.0115 0.021 0.0389 0.0626 0.123 0.240];
    % the corresponding vector for the minimum film thickness variable,h0/c
    hoc_4=[0.1 0.2 0.4 0.6 0.8 0.9];
    % the corresponding vector for the coefficient of friction variable, Rf /c
    Rfc_4=[0.961 1.20 1.52 2.57 4.80];
    % the corresponding vector for the volumetric oil-flow rate, Q/ (RcnL)
    Qc_4=[0.760 1.56 2.26 2.83 3.03];
    % the corresponding vector for side leakage flow/total flow, Qs/Q
    Qsc_4=[0 0 0 0 0 0 0 0 0];
end
if l/d==1
% To interpolate the data, the MATLAB function csapi(X,Y) is used:
fhoc_1 = csapi( S_1, hoc_1 );
ffc_1 = csapi( S_1, Rfc_1);
fQR_1 = csapi( S_1, Qc_1);
fQs_1 = csapi( S_1, Qsc_1);
% The values of the interpolated data functions at Sc are calculated with:
hc = fnval(fhoc_1, Sc); % ho/c 
fc = fnval(ffc_1, Sc);  %(r/c)f
Qc = fnval(fQR_1, Sc);  % Q/(r c n L)
Qsc= fnval(fQs_1, Sc);  % Qs/Q 
elseif l/d==0.5
% To interpolate the data, the MATLAB function csapi(X,Y) is used:
fhoc_2 = csapi( S_2, hoc_2);
ffc_2 = csapi( S_2, Rfc_2);
fQR_2 = csapi( S_2, Qc_2);
fQs_2 = csapi( S_2, Qsc_2);
% The values of the interpolated data functions at Sc are calculated with:
hc = fnval(fhoc_2, Sc); % ho/c
fc = fnval(ffc_2, Sc);  %(r/c)f
Qc = fnval(fQR_2, Sc);  % Q/(r c n L)
Qsc= fnval(fQs_2, Sc);  % Qs/Q
elseif l/d==0.25
% To interpolate the data, the MATLAB function csapi(X,Y) is used:
fhoc_3= csapi( S_3, hoc_3 ); 
ffc_3= csapi( S_3, Rfc_3 );  
fQR_3= csapi( S_3, Qc_3 );   
fQs_3= csapi( S_3, Qsc_3 );  
% The values of the interpolated data functions at Sc are calculated with:
hc = fnval(fhoc_3, Sc);  % ho/c
fc = fnval(ffc_3, Sc);   %(r/c)f
Qc = fnval(fQR_3, Sc);   % Q/(r c n L)
Qsc= fnval(fQs_3, Sc);   % Qs/Q
else l/d==inf
% To interpolate the data, the MATLAB function csapi(X,Y) is used:
fhoc_4 = csapi( S_4, hoc_4 );
ffc_4 = csapi( S_4, Rfc_4 );
fQR_4 = csapi( S_4, Qc_4 );
fQs_4= csapi( S_4, Qsc_4 );
% The values of the interpolated data functions at Sc are calculated with:
hc = fnval(fhoc_4, Sc);  % ho/c
fc = fnval(ffc_4, Sc);   %(r/c)f
Qc = fnval(fQR_4, Sc);   % Q/(r c n L)
Qsc= fnval(fQs_4, Sc);   % Qs/Q
end 
Temperature_rise = (8.3*P*fc)/(10^6*Qc*(1-0.5*Qsc));

Alan Stevens on 3 Jan 2021

So , in the general expression for y, replace y1 by fnval(fQs_1, Sc);, y1/2 by fnval(fQs_2, Sc); etc.

matlab coder on 3 Jan 2021

thank you so much

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design of journal bearing

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