Don't forget to look at the following: a) Verify that the conditions the blower inlet was designed for are accurate, and that a worst case for design conditions is properly established. A fan taking atmospheric air can be -20F in winter, as well as 105F in summer, will have different motor draws (at a given fan speed) due to a change in gas density. If essentially a constant inlet gas density (this fan is inside a building), then the motor bhp will follow standard fan law, whereby BHP2=BHP1x(RPM2/RPM1)^3. If at design point, the fan vendors states the motor will draw 10 bhp at 900 rpm, then at 300 rpm, BHP2=0.37 bhp.
b) Fan curves are based on a specific fixed (i.e. buyer stated) inlet condition. If the inlet side process changes, or you have a complex duct system, suction or discharge, you also may request a set of fan curves from the fan supplier with your preferred operating speeds stated.
c) Verify that your fan design point is based on valid analysis of the system (i.e. pressure drops at the designated flow rate thru all duct, fittings, dampers, entrance/exit losses from/into larger or open chambers, etc), since this will determine where on the curve you will actually operate. Oversized duct, shorter runs, fewer elbows, etc than originally planned, and you will operate further out on the fan curve - thus handling greater flowrate, which will consume greater power.
Also be careful with motor SF and inverter nameplate ratings. A 10hp inverter operating a 10hp motor having a 1.15 service factor cannot access this safety factor, since the inverter is not provided with a matching SF. If you want access to this motor SF, jump to a 15 hp drive. Un-matching drives are not uncommon, and can be used for a future upgrade in motor hp if the process can potentially change down the road.
Hope this is helpful and not overly complicated, but simple questions often do not have simple answers. - Al
"Beware of the man who won't be bothered with details".
