Face milling hardened steel on a low-power machine can be a "no-win" situation鈥攁nd the machine may be the biggest loser of all. Spindle stalling aside, the frames and spindle bearings on many low-power machines simply aren鈥檛 built for the extreme cutting forces and hammering鈥攖hat is, severe vibration鈥攔esulting from the interrupted cuts inherent in the milling process. Cory Pleschourt, diemaker at SPX (Owatonna, Minnesota), solved this problem by retooling one punishing face-milling operation with an Power-Feed+mill from cutting tool manufacturer Ingersoll, then cranking up feeds and speeds. In addition to increasing metal removal rates by 10 percent, this remedy eased cutting forces鈥攅specially impact forces鈥攐n the machine while reducing spindle load by at least 15 percent. Even at higher feeds and speeds, the hammering that used to plague the operation is largely a thing of the past. Operating 20 hours a day, 5 days a week, the die shop supplies SPX鈥檚 600-employee main plant with the tools it needs to keep running. It makes and repairs forging dies used to produce service, testing and maintenance equipment for automotive and agricultural dealerships. As a small operation, the die shop has limited machines and limited backup capability鈥攊t is "the very definition of 鈥榣ean,鈥�" Mr. Pleschourt says. "We need to get the dies out on schedule, but we can鈥檛 afford to jeopardize the few CNC machines we have."One of the shop鈥檚 mainstay machines is a 40-taper VMC with a 14,000-rpm spindle equipped with ceramic bearings. While this machine is well-suited for fine work on die cavities when the die steel is still in the wrought condition, it runs into problems on heavy face-milling operations required to repair Finkl forging die stock that is hardened to Rc 43. When a worn die arrives, Mr. Pleschourt typically skins off about 3/8 inch from both mating die faces in order to leave enough stock for resinking. Previously, standard practice was to run a 2 1/2 鈥搃nch, 4-flute, positive-rake facemill at 600 rpm, 50 ipm and a 0.03-inch cutting depth. Cutting 3/8 inch off a 12- by 8-inch die block took about 15 passes, each of which was 1.8 inches wide. Even at that low feed rate, hammering often caused further slowdowns. "We鈥檙e always concerned about the ceramic bearings at the first sign of hammering," Mr. Pleschourt says. Seeking to better protect the machine during this operation, Mr. Pleschourt asked Ingersoll field engineer Ondrej Lubinski for help. Noting that the machine spindle was rated at 14,000 rpm, Mr. Lubinski suggested Ingersoll鈥檚 three-flute Power-Feed+mill face mill along with ramped up feeds and speeds. After testing, the two settled on 1,000 rpm, 100 ipm and a 0.02-inch depth of cut. Despite the increase in feeds and speeds, cutting action was smoother with no hammering, and the spindle power gage read 55 percent, or 15 percent lower than the previous reading. Mr. Lubinski says feeding faster and cutting shallower works because modern carbide inserts are durable enough to withstand the added wear involved in repetitive, fast passes. "In other words, you punish the cutting edge in order to protect the machine frame, motor and bearings," he explains.The Power-Feed+face mill is equipped with a negative axial rake and three flutes, whereas the shop鈥檚 previous tool had four flutes. At first glance, this may seem to be a formula for rough cutting action on the hardened steel used for the shop鈥檚 forging dies. Finding success in such operations, however, is simply a matter of juggling settings to take advantage of the cutter鈥檚 geometry, Mr. Lubinski says. Combined with a shallower cut, ramping up feeds and speeds led to 10 percent faster volumetric metal removal with a 20 percent lower chip load per tooth. "A high-feed cutter in a high speed spindle gives you that option," he explains. Moreover, a negative axial rake helps keep the cutter on track and deter insert pullout or digging into the work. The face mill is also stubbier than the shop鈥檚 previous tool, protecting the ceramic spindle bearings against excess lateral forces. The reduced flute count also protects the low-power machine against stalling in the midst of a heavy cut in hardened steel. That鈥檚 because with more edges in the cut, the machine鈥檚 motor has to overcome more friction, Mr. Lubinski says. Using only three flutes ensures that more of the machine鈥檚 limited horsepower goes toward cutting, where it is needed the most. Additionally, the face mill鈥檚 negative axial rake enables the cutter to employ two-sided, triangular inserts. Thus, the shop can buy half as many inserts as before with the same edge life, leading to significant tool cost savings. "Originally, I simply asked (Mr. Lubinski) how to better protect a light but indispensable machine," Mr. Pleschourt says. "We gained that extra safety margin plus faster throughput on a recurring operation."