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greenpick
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Homework Statement
Gasoline is stored in a cylindrical tank buried on its side, with the highest part of the tank 5 ft below the surface. The tank is 6 ft in diameter and 10 ft long. Density of gasoline is 45 lb/cubic ft. Assume that the filler cap of each automobile gas tank is 2 ft above the ground.
(a) How much work is done in emptying all the gasoline from the tank, which is initially full?
(b) Recall that 1 hp is equivalent to 33,000 ft-lbs/min. For electrical conversions 1 kW (1000W) is the same as 1.341 hp. The charge for use of electricity generated by a power company is about 7.2 cents per kWh. Assume that the electrical motor in the gas pump is 30% efficient. How much does it cost to pump all the gasoine from this tank?
Homework Equations
see above
The Attempt at a Solution
(a)volume of a generic "slice" = 10 * 2x[tex]\Delta[/tex]y = 20[tex]\sqrt{9-y^2}[/tex][tex]\Delta[/tex]y
Force acting on that slice = 45 * 20[tex]\sqrt{9-y^2}[/tex][tex]\Delta[/tex]y
W to pump that slice up =
900[tex]\sqrt{9-y^2}[/tex][tex]\Delta[/tex]y(10-y)
Total work = [tex]\int900\sqrt{9-y^2}(10-y)[/tex] from -3 to 3 [tex]\approx[/tex] 127,234.5 ft-lbs
(b)I know this isn't right... And it's probably very confusing as well.
127,234.5 ft-lbs * (1 hp/ 33,000 fl-lbs/min) = 3.8559 hp * min * (1 kW/ 1.341 hp) = 2.875 * 1000 J/s * min = 2.875 * 1000 J/s * 60 s = 175,209.66 J * (1 kWh/ 3,600,000 J) = .0479 kWh * 7.2 cents = .345 cents
for efficiency, I divided the final answer by .3 which gives me 1.15 cents, which is obviously not right.
The first part may be right, but I really don't know what to do on the second part. Any help would be greatly appreciated.
