TomWaggoner
Structural
- Sep 23, 2010
- 23
I have a steel water tank. Supported on a concrete matt on piles.
The seismic analysis of the tank using ASCE 7 and some other sloshing equations yield a base shear coefficient of Cs= 0.06 Wd. The tank and fluids weigh approximately 60,000,000 lbs. Believe it or not it has a 12 second period. Therefore, low base shear
So the shear at the base of the tank is about 3600 kips.
The matt of concrete weighs approximate 65,000,000 lbs.
So, to design the piles for seismic resistance, would you
1. Take the weight of the matt and multiply by 0.06 and add it to the tank base shear to get 3900 + 3600= 7500 kips?
2. Apply some other coefficient (R value) to the weight of the matt. Short period, huge value Cs=0.25Wd, and get 16,250 kips then add that to the 3600 kips for the tank. 3600 + 16250= 19,850 kips.
I lean toward solution 1, but I don’t have any literature to support it.
Any ideas?
The seismic analysis of the tank using ASCE 7 and some other sloshing equations yield a base shear coefficient of Cs= 0.06 Wd. The tank and fluids weigh approximately 60,000,000 lbs. Believe it or not it has a 12 second period. Therefore, low base shear
So the shear at the base of the tank is about 3600 kips.
The matt of concrete weighs approximate 65,000,000 lbs.
So, to design the piles for seismic resistance, would you
1. Take the weight of the matt and multiply by 0.06 and add it to the tank base shear to get 3900 + 3600= 7500 kips?
2. Apply some other coefficient (R value) to the weight of the matt. Short period, huge value Cs=0.25Wd, and get 16,250 kips then add that to the 3600 kips for the tank. 3600 + 16250= 19,850 kips.
I lean toward solution 1, but I don’t have any literature to support it.
Any ideas?
