The G 160 features short chip-to-chip times, an intelligent axis concept, thermal and mechanical stability and ease of operation.
G 160 for components up to module 3 and a maximum OD of 160 mm.
The larger G 250 machine offers enhanced precision, minimal chip-to-chip times and short set-up times.
The G 250 (like the G 160) has a double table. Loading, unloading and measuring of the components thus takes place in cycle time-concurrent.
Particular precision and process reliability have characterized automotive engineering for many decades. With the establishment of e-mobility, however, these demands are increasing once again, because many e-motor components need to be manufactured even more "perfectly." In most cases, this involves the highest surface finish in the micrometer range so that no loud running noises occur on the gear components. In a quiet e-motor, for example, these noises would be audible. In this context, the technology of EMAG SU is drawing the attention of many production planners. Among other things, the specialists developed high-performance solutions for gear grinding-including short chip-to-chip times, intelligent axis concepts, thermal and mechanical stability and a high degree of user-friendliness.
Solutions for the field of gear profile grinding include the G 250 machine and the G 160. The G 160 is used for components up to module three and with a maximum OD of 160 mm. "In this field of application, it is the fastest machine on the market, which is made possible by two parallel workpiece tables that move alternately at high speed to the grinding wheel," said a company spokesperson. "Thus, while one component is machined, the internal loading robot inserts a blank into the other spindle or unloads the finished component beforehand. In addition, the axis concept ensures perfect surfaces, which are so important in e-mobility."
The G 160 does not have a tangential axis, but instead the existing Y and Z axes generate a "virtual" tangential axis through simultaneous movement. As a result, the distance between the A-axis and the tool contact point is very small, which in turn prevents "ghost frequencies" on the surface of the component. The possibilities this approach opens up for e-mobility are shown, for example, by the example of an intermediate shaft with 21 teeth and a normal module, where a floor-to-floor time of only 33 seconds (including entanglement compensation and proportional dressing time) and a grinding time of only 25 seconds are achieved. Similar performance values are shown for an input shaft with 26 teeth and a module of 1.6 mm. Here, the pure grinding time is only 28 seconds.
Minimum Floor-to-Floor Times
The larger G 250 machine also offers precision, minimum chip-to-chip times, short set-up times and reliability for components with a maximum length of 550 mm. The machine has a double table (like the G 160). Loading and unloading operations as well as component measurement are thus performed in cycle time-concurrently. Additionally, the grinding mandrel can accommodate grinding wheels with different diameters, and the entire design is very rigid.
Gear generating grinding and profile grinding take place on the main grinding spindle, so the machine does not have a thermal growth. It can also be retooled for the other process in just a few minutes. In the field of e-mobility, for example, this approach is used for grinding axle drive wheels. The floor-to-floor time here is only 69 seconds (including entanglement compensation and proportional dressing time), with the actual grinding time comprising only 58 seconds. The G 250 achieves a comparably high productivity level when machining pinions with a strong crowning in the tooth flank profile and normal crowning in the flank line. The bottom-to-bottom time is 33 and the grinding-only time is 28 seconds. A DIN 3962 quality of 4 is achieved.
Sky Grind: Lower Costs
EMAG SU illustrates what the general future of gear grinding could look like with the establishment of the new Sky Grind process. Here, the final grinding on the gear is carried out completely dry-with financial advantages for the users, because the filter system, cooler, etc. (which are normally required for wet grinding) are no longer needed, thus reducing the initial investment. In addition, energy consumption is significantly reduced.
The whole thing is made possible by a dual-tool system with two different tool spindles in the machine: one for finish-machining by hobbing and one for finish-machining by grinding. In practice, this means that, for example, in the case of the classic automotive gearwheel with 100 µm allowance per flank, the sky-grind process removes 90 micrometers by hobbing and only 10 micrometers by gear generating grinding. In the end, the cycle times of conventional wet gear grinding and the Sky-Grind process are very similar; however, the costs are very different.
"How can EMAG SU's know-how and offering be summarized? You could certainly say that we guarantee our customers competitive advantages and a fast return in investment," said Alexander Morhard from EMAG SU. "To this end, we continuously invest in research and development to further increase the efficiency and environmental friendliness of the machines. The result is perfect solutions for the production of ultra-fine surfaces with different contours."
Authored by EMAG L.L.C.
For more information contact:
EMAG L.L.C.
38800 Grand River Ave.
Farmington Hills, MI 48335
248-447-7440
info@usa.emag.com
www.emag.com