West Manufacturing News • November 2016 • Heavy Duty Machining

"The importance of the toolholder is still understated, especially when it comes to roughing and heavy-duty machining," said a company spokesperson. "Metal removal rates in these types of processes are absolutely crucial for the productivity of the machining operation. By using special shrink fit chucks with drive pins and spiral grooves in the tool shank, it is now possible to perform high-feed full slotting of up to 2 x D (50 mm) or more in difficult to machine materials. Application studies conducted by machine tool manufacturer Heller have proven the effect of the HAIMER Safe-Lock system."

Especially within the aerospace, energy and mechanical engineering sector, production managers have to bridge the gap between economic efficiency and high process reliability when working with materials that are difficult to machine. Fortunately there is peace of mind in knowing that the machine technology innovations continue to develop to meet the ongoing demands of manufacturing. "Heller machine tools are known as a source of inspiration for these kinds of innovations," said a company spokesperson. "The company, located in Nuertingen, Germany, is known for its high quality 4- and 5-axis CNC machining centers, CNC mill / turning centers, CNC machines for crankshaft and camshaft machining as well as flexible manufacturing systems. Customers value its availability of products and its competency in managing special processing demands. Both qualities stem from Heller's in-house manufacturing, which relies on closer collaboration with customers, suppliers and research institutes to remain on the forefront of innovation.

Werner Kirsten, who is working in the Technology Development Department at Heller and is responsible for the difficult to machine materials, explained: "Our service includes optimizing the machining processes together with our customers and suppliers. To support such services with practical trials, our Technology Center is equipped with a variety of machines." In most cases, the aim is to increase productivity without compromising the process reliability. Kirsten added, "We often achieve this aim with an optimized roughing operation which ultimately results in a reduced finishing process. By maintaining the same technological values, but shortening the finishing depth of cut by 50%, the overall machining time is reduced to half. However, this requires process reliable and controllable systems during roughing."

In this regard, all machining components in the process chain have to be considered in order to improve productivity. The machine tool is the most evident component of the machining process, however the tool, the toolholding system, the coolant supply and other elements are also essential for a successful operation. "In the end, the weakest link of the process chain limits the success," Kirsten emphasized. In his opinion, most machine shops do not pay attention to the toolholder even though it is especially significant for high performance cutting. "Many of the trials that we carried out during the last few years have proven this point," Kirsten explained. "We realized that the toolholder has an incredible influence on the machining process. In the case of reinforced shrink fit chucks, for example, the vibration node is closer to the bearing point (due to the larger mass). The result is a smoother machining process with less vibration and a better surface finish quality while using the same tool, machine, process parameters and fixturing technology."

By selecting the right toolholder operators can even achieve good productivity and surface quality results using basic standard cutting tools. Kirsten refers to comparative tests with basic four-edge cutting tools without an inner coolant supply. As an alternative to a standard shrink fit chuck, he selected a HAIMER Power Shrink Chuck with Cool Flash, which ensures that the coolant is transported directly to the cutting edges.

"Compared to using a normal shrink fit chuck and external coolant, we were able to achieve significantly better results." When a group of representatives from the aerospace industry, the Technical University of Dortmund and Technical University of Hamburg-Harburg visited Heller, an especially extensive milling application study was conducted in titanium Ti-6AI-4V.

The available machining center was a 4-axis Heller H 5000 with a gear unit and HSK-A100 spindle, which yields torques up to 2.290 Nm. In order to demonstrate the machining potential, different 25 mm diameter end mills were used to mill full slots into a titanium plate. To simulate holder conditions used in the aerospace industry, the tools were clamped into reinforced shrink fit chucks. At an axial cutting depth of 0.5 to 1.0 x D, the machining process was found to be very reliable. Since the spindle was not running at full capacity, the trial participants agreed to increase full slotting depth to 2 x D. Kirsten explained: "Under these conditions the tool pulled out of the shrink fit chuck during the machining operation, creating a slot closer to 2.5 x D as it progressed through the part. Towards the end of the slot the tool finally broke as a result of increased cutting forces."

The milling specialists all agreed that the clamping force of the chuck was the limiting factor in this process. As soon as the axial pressure and process related vibrations are too high, the tool moves out of the chuck and further into the workpiece. At the same time, the cutting pressure increases such that in the end the tool breaks and the workpiece is irreversibly damaged.

Reasons and possible countermeasures were discussed intensively. In the end, Kirsten developed the idea that the tools are forced to navigate towards the spindle when the holding forces are exceeded. This is how he ultimately noticed the patented HAIMER Safe-Lock system, which in addition to frictional clamping forces, has the same helix pattern as the tool. Theoretically, he realized that even if the tool got loose while using Safe Lock, it would be pulled into the holder through the helical drive keys and not into the part. A movement that can be easily prevented through the use of length presetting screws.

Kirsten got in contact with HAIMER in order to test the Safe-Lock system. "We wanted to know if our ideas could be put into practice using the HAIMER system in an even less forgiving environment," said Kirsten. The Heller technology developer repeated the described trial, with a few major changes. HAIMER Safe-Lock grooves were subsequently added on similar solid carbide tools, but the application would be run again with a reduced spindle taper interface (HSK 63 instead of HSK 100), with a less rigid 5- axis gear driven spindle and a less stable diagonally fixtured workpiece.

The result: despite these additional limiting factors, the tool was able to process a full slot of 2 x D = 50 mm with complete process reliability. Kirsten said, "This way we were able to indirectly prove that Safe-Lock works and that the shrinking technology has even more potential with HSK-A100, especially on 5- axis machining centers with gear spindles." Afterwards this sample machining on Ti-6AI-4V was carried out various times, including during the Airshow in Farnborough, whereby it was proven that the previous limit of 1 x D = 25 mm full slotting in titanium could be doubled with the use of Safe-Lock.

Kirsten summarized the results as follows: "For roughing operations this is a reliable process. Therefore I consider the HAIMER Safe-Lock system a practical, easy to handle and process reliable addition to the shrinking technology that we already utilize, especially in connection with standardized tools of other manufactures."

From the onset of its creation, HAIMER recognized the potential of the Safe-Lock system, which is why the company created a licensing program to give innovative tool manufacturers the ability to integrate the patented pullout protection system into their tools. The result of its vision to create a more open system has been a success, with 14 leading cutting tool manufacturers having now signed licensing agreements. These include Walter, Widia, Sandvik Coromant, Seco Tools, Sumitomo, Kennametal, Helical, Emuge Franken, Data Flute, Niagara, OSG, Melin, SGS Tools and recently Mapal.

"Through the steady increase of Safe-Lock tooling in the market via HAIMER and its licensed partners, the system has become the new standard for heavy machining and roughing," said a spokesperson. "In fact, the popularity and simplicity of Safe-Lock is such that it is also replacing the old Weldon clamping system, particularly when new milling strategies such as trochoidal (dynamic) milling are involved."

President of HAIMER Group Andreas Haimer explained: "With our Safe- Lock system we found a solution that combines a high runout accuracy with 100% pullout protection. The system has established itself successfully as a standard in the aerospace industry and generally speaking for roughing and heavy duty machining. And now more and more companies that make use of the trochoidal (dynamic) milling strategy are also making the switch to Safe-Lock, and for a good reason."

During trochoidal milling operations, where the cutting speed and axial depth of cut can be increased through software support, productivity is significantly improved. However, the increased cutter engagement and cutting forces that result from the higher cutting performance create a situation where tool pullout can easily occur. "Prior to Safe-Lock, this problem was prevented with Weldon shanks and chucks," said the spokesperson. "However, customers had to sacrifice speed and accuracy due to the nature of this clamping system. A shrink fit chuck with Safe-Lock offers the same safety as the Weldon system, but provides the additional advantage of accuracy and balance. The ideal balancing and runout characteristics of the shrinking technology in combination with the clamping safety of the Safe-Lock system permit greater productivity achieve through faster permissible speeds and increased tool life - all with complete tool security assurance."