Milling on a grinding machine: a grinding machine is not a machining center, but it can sometimes take on milling and drilling to make the overall pro

However, certain profile grinding machines have developed in the direction of this type of multitasking, even when combining operations was not necessarily the goal. The MFP-TC grinding machine pictured, from Magerle (represented in the United States by United Grinding Technologies, Miamisburg, Ohio), provides an example. To support an increasing role for creep-feed grinding (a higher-metal-removal rate process than grinding just for finish), this machine features a powerful spindle and stiff hydrostatic ways. Further, because wheel types such as conventional abrasive, plated CBN and vitrified CBN all excel in different applications, the machine has been equipped with the capability to store different wheels and automatically switch between them.

This latter feature relies on proven technology. Specifically, it relies on a toolchange arm like that of a machining center, along with toolholders (or wheelholders in this case) that use the HSK interface of a machining center's toolholders. Taken together, this machine's tool changing, spindle power and rigidity produce the equivalent of a highly capable machining center. Precise heavy milling can be performed on this machine, and milling and drilling tools can be stored in the tool magazine alongside the grinding wheels.

Minimal Milling

Chris Stine is a vice president of United Grinding Technologies. He says performing chip-making operations such as milling and drilling on a grinding machine is best suited to certain types of parts. It also requires a particular mindset about production.

For a part to benefit from milling or drilling on a grinder, the cycle should consist of mostly grinding. The MFP-TC machine cited above remains a grinder first and foremost, offering precision beyond what might be associated with even a higher-end machining center, he says. As a result, the machine can't compete economically against a machining center if traditional metalcutting makes up most of the work.

However, many ground parts do feature a small but critical amount of this metalcutting. Even on a grinding machine equipped with multiple wheels and capable of high metal removal rates, there are plenty of features that simply cannot be ground. Holes, pockets and slots that don't run completely through the workpiece are examples. When the part has one or more features such as these, performing these cuts on the grinder can save considerable cost by eliminating the need to set up on multiple machines. This is particularly true for parts such as airfoils, in which the location of machined features may be defined with respect to ground surfaces that have complex geometries.

Another argument for consolidating operations relates to the part's size. Large parts magnify the savings in floor space that might result from combining grinding and machining center operations into one machine. Labor savings might also be more significant. The bigger the part, the better it is to set it up in just one place.

For particularly large parts, Mr. Stine says that the range of potential operations expands to include turning. A rotary table that can turn at 70 rpm can deliver 1,500 sfm of cutting speed to a turning tool that cuts at a diameter of 7 feet. This is exactly the solution that GE Gas Turbines (Greenville, South Carolina) adopted for machining large turbine wheels. Parts that used to be machined on a grinder, a vertical lathe and a boring mill now receive all of this machining on one Magerle machine tool. The change saves about 6 hours of setup time and 2 days of queue time, according to engineers at the plant. Overall, there has been a 30 percent cycle time reduction.