Balancing load on milling cutting elements

What is claimed is: 1. A method for manufacturing a mill structure for milling a window in a cased wellbore, comprising: determining a configuration of a cutting structure of a mill to cut a window in a well casing, the cutting structure of the mill having sets of radially adjacent cutting elements on a plurality of blades of the mill; determining a configuration of a whipstock having a plurality of ramp sections; calculating a volume of casing removed in cutting the window per set of cutting radially adjacent cutting elements based on a predicted movement of the mill along the plurality of ramp sections of the whipstock; based on the calculated volume of the casing removed, balancing a volume of casing removed between each set of radially adjacent cutting elements by adjusting one or more of the configuration of the cutting structure of the mill and the configuration of the whipstock subject to a constraint that a difference in volume of casing removed in cutting the window between each set of radially adjacent cutting elements does not exceed about 30%; and manufacturing the mill structure having a configuration of a cutting structure based on the adjusted configuration of the cutting structure and in accordance with the adjusted configuration of the whipstock. 2. The method of claim 1 , wherein balancing the volume of casing removed between each set of radially adjacent cutting elements comprises iteratively modifying the configuration of the cutting structure of the mill or the configuration of the whipstock until satisfying the constraint that the difference in volume of casing removed between each set of radially adjacent cutting elements does not exceed about 30%. 3. The method of claim 1 , wherein balancing the volume of casing removed between each set of radially adjacent cutting elements comprises iteratively modifying the configuration of the cutting structure of the mill or the configuration of the whipstock to minimize the volume of casing removed between each set of radially adjacent cutting elements. 4. The method of claim 1 , wherein determining the configuration of the whipstock includes determining an angular orientation and a length of each ramp section of the plurality of ramp sections. 5. The method of claim 1 , wherein determining the configuration of the whipstock includes determining a unique angular orientation and a unique length for each ramp section of the plurality of ramp sections. 6. The method of claim 1 , wherein determining the configuration of the whipstock includes determining a number of ramp sections. 7. The method of claim 1 , wherein balancing the volume of casing removed between each set of radially adjacent cutting elements comprises iteratively modifying both the configuration of the cutting structure of the mill and the configuration of the whipstock until satisfying the constraint that the difference in volume of casing removed between each set of radially adjacent cutting elements does not exceed about 30%. 8. The method of claim 1 , wherein balancing the volume of casing removed between each set of radially adjacent cutting elements comprises iteratively modifying both the configuration of the cutting structure of the mill and the configuration of the whipstock to minimize the volume of casing removed between each set of radially adjacent cutting elements. 9. The method of claim 1 , further comprising: calculating a cutting load per cutting element for each cutting element based on the predicted movement of the mill along the plurality of ramp sections of the whipstock. 10. The method of claim 9 , further comprising: balancing the cutting load between each set of radially adjacent cutting elements by adjusting one or more of the configuration of the cutting structure of the mill and the configuration of the whipstock. 11. The method of claim 10 , wherein balancing the cutting load includes modifying at least one of the configuration of the cutting structure and the whipstock-and re-calculating the cutting load on a per cutting element basis until each of the plurality of cutting elements has a cutting load no greater than about 30 cubic inches of well casing cut. 12. A method for milling a window in a cased wellbore, comprising: tripping a mill into a wellbore, the mill being arranged and designed to mill a window in a well casing using a plurality of cutters coupled to circumferentially offset blades of the mill, the plurality of cutters comprising sets of radially adjacent cutters corresponding to respective portions of the circumferentially offset blades of a cutting structure of the mill; tripping a whipstock into the wellbore, the whipstock having at least one ramp section configured to move the mill in a lateral direction during milling of the window; and milling a window in the well casing by moving the mill along the at least one ramp section of the whipstock, wherein milling the window includes loading the plurality of cutters such that an absolute difference in casing volume removed in cutting the window in the well casing by each set of radially adjacent cutters while moving along the least one ramp section of the whipstock is less than about 35%. 13. The method of claim 12 , wherein milling the window includes loading the cutters such that each cutter of the plurality of cutters on the mill removes no more than about 30 cubic inches of well casing. 14. The method of claim 12 , wherein milling a window in the well casing by moving the mill along the at least one ramp section of the whipstock includes milling with a dogleg severity of less than 4 degrees per 100 feet. 15. The method of claim 12 , wherein the respective portions of the circumferentially offset blades of the cutting structure of the mill comprise two or more of: a cone section; a nose section; a taper section; and a gage section. 16. The method of claim 12 , wherein each set of radially adjacent cutters corresponding to the respective portions of the circumferentially offset blades includes a different number of cutters. 17. A mill for cutting a window through casing in a borehole, comprising: a lead mill body having a plurality of circumferentially offset blades; and a plurality of cutting elements coupled to the plurality of offset blades, the plurality of cutting elements comprising sets of radially adjacent cutting elements corresponding to radially offset portions of the lead mill body coupled to respective blades of the plurality of offset blades and being arranged and designed to limit an absolute difference in calculated casing volume removed in cutting a window in a well casing while moving in a direction defined by one or more ramp sections of a whipstock by each set of radially adjacent cutting elements to less than about 35 percent. 18. The mill of claim 17 , the plurality of cutting elements being arranged and designed to limit the absolute difference in calculated casing volume removed by each set of radially adjacent cutting elements to less than about 30 percent. 19. The mill of claim 17 , the plurality of cutting elements being arranged and designed to limit the absolute difference in calculated casing volume removed by each set of radially adjacent cutting elements to less than about 25 percent. 20. The method of claim 17 , wherein the well casing comprises an outer casing of a cylindrical borehole, and wherein the direction defined by the one or more ramp sections of the whipstock is a lateral direction relative to a vertical orientation of the cylindrical borehole.