As LCKurtz implied, your formula is completely wrong and you don't say how you got it. The work required to lift "j" Newtons of water a distance h meters is jh Joules. The problem here, and the reason you need to use calculus, is that the amount of water varies from "height" to "height".
For simplicity "x" be the height above the center of the spherical tank, so that x varies from -3 to 3 to cover the entire tank. Then x^2+ y^2+ z^2= 9 is the equation of the sphere and at a given height, x, the "layer of water" is the circle y^2+ z^2= 9- x^2 which has radius \sqrt{9- x^2} and area \pi(9- x^2). Imagining this "layer" to have thickness dx, its volume is \pi(9- x^2)dx and its weight is \pi(9- x^2)dx times the density of water, \delta (I will explain later why I am NOT using "62.4 pounds per cubic foot) \delta\pi(9- x^2)dx.
The distance from x to the top of the tank is 3- x so the distance that the "layer" of water has to be lifted is 3- x+ 1= 4- x. That means that the work done in lifting that "layer" of water is \delta\pi (4- x)(9- x^2)dx.
Integrate that from the bottom of the tank to the top, from x= -3 to x= 3.
(I am puzzled that you are told to "use the fact that water weighs 62 lbs/ft3" when all the lengths are given in meters.)
