Can anyone help me on what to do with this, because I was trying to design it using two different isolated rectangular footings but my boss wanted me to design it as a Combined footing.
Find the centroid of your dead loads.
Locate the centroid of your footing at the same place.
Make its area large enough so that allowable soil bearing is not exceeded.
Make the footing thick enough to be rigid. At least about 10% of the longest dimension.
Check the footing thickness for punching shear. Increase thickness as necessary.
Long dimension steel.
Find the max bending moment in the long dimension due to all load conditions.
Size long bar diameter.
Short dimension steel.
Consider each column independently and, using a width of column width + 2x footing depth,
Find the max bending moment in the short dimension due to all load conditions.
Size short dimension bar diameter.
If bar size at column 1 is similar to column 2, use the largest bar diameter everywhere in the short dimension.
--Einstein gave the same test to students every year. When asked why he would do something like that, "Because the answers had changed."
Very creative, but it helps reduce complexity both in analysis and construction, if you keep foundation lines aligned to one X, Y coordinate system.
Do you know how to replace two forces (here the dead loads) with one resultant force?
Dead
Load, X, Y
100, 5, 2
50, 12, 4
X location
X = (100 x 5 + 50 x 12)/(100 + 50)
Y = (100 x 2 + 50 x 4)/(100 + 50)
X= 1100/150 = 7.33
Y= 400/150 = 2.67
Try footing thickness of 2
(Pressure of concrete in footing)
Unit weight of concrete = 0.5
Footing pressure = 2 x 0.5 = 1
Allowable soil bearing pressure = 2.2
Footing pressure 1
Dead load Min Footing Area = 150/(2.2-1)
Dead load Min Footing Area = 150/1.2 = 125
For now I'd just assume a square Footing.
Magnitude of wind in X and Y directions may affect dimensions later.
Square Footing Dimensions (125)^0.5 = 11.2 x 11.2
11.2÷2 = 5.6
The centroid of the footing is always placed under resulting dead load to minimize differential settlements for sustained loads. You may also want to include live loads (or reduced live loads in this centroid calculation, as they should not be too conservative. But use dead plus full live load for the soil bearing check,)
This is the arrangement for my loads.
You may need to adjust further to get reasonable effective strip widths and a good distribution of steel in the x and y directions, such as when columns are too close to the edge of footings, reducing your effective width too much.
Wind loads may alter your dimensions, especially if wind loads in X direction are greatly different than Y. Temporary loads are not considered in the centroid of footing area calculation. But of course must be included for concrete design and soil bearing checks. You may have to adjust your footing dimensions for these loads, while trying to keep the footing centroid at the same location.
--Einstein gave the same test to students every year. When asked why he would do something like that, "Because the answers had changed."