The ECP-H7-CF multi-flute (seven flutes) end mill has a hard substrate, IC902 ultra-fine carbide grade with 9 percent cobalt, and is TiAlN PVD coated. It is suitable for machining various materials, including hard steel and cast iron, at high cutting speeds, according to Iscar.

“These screw-in heads are available from 8 mm up to 32 mm in diameter and can be mounted on extensions of various lengths,” he explained. “The smaller diameters have replaced solid-carbide tools in many instances. The advantages of both the replaceable-tip drills and modular, indexable end mills are similar: lower replacement costs, because instead of the entire tool being composed of carbide, only the portion actually doing the cutting contains carbide; less variability in position after indexing; the ability to easily change grades or geometries when cutting different workpiece materials; and less downtime when replacing worn tools.” However, he added, solid-carbide tools still provide better rigidity, deep-hole drilling and greater depth of cut capabilities when milling.

The Mini-Mill series of tools—including Nanmill, Nan3feed, Heli4mill, Heli3mill and Micro3feed—complement Iscar’s solid-carbide tools with diameters starting at 0.312-0.75" (7.92-19.05 mm) with multi-edged inserts for 90o milling and fast-feed milling, he explained.

It’s important to have the right CAM software to avoid wasted rapid travel movement, which increases cycle time. There are times when it is better to take a more conventional cutting pass. One example is when the width of cut is short with, say, a 0.5" (12.7-mm) end mill with the intention of cutting a length of the part that’s 0.5" long and the process needs to remove 0.3" (7.62 mm) of material. In this example, Horn recommends taking all the material off in one or two passes instead of 30 passes. To be efficient, the tool must stay on the part and limit time-wasting retraction.

“All four of those strategies are essentially the same,” said Stusak. “We have developed multi-flute tools, and specifically a seven-flute tool with chip splitting technology to allow very light widths of cut depending on the length of the flute on the end mill. These strategies actively manage all four of the attributes in the CAM systems—including the radial width of cut, the arc of contact, chip thickness and the feed rate—for optimized performance,” he said.

Advanced cutting tools can maximize metal removal rates (MRR) when machining even the most difficult-to-machine materials. Powered by the latest CAM programs, these machining strategies are known variously as high-speed, high-efficiency, optimized roughing and also by proprietary brand names like Mastercam’s Dynamic Milling. Tools such as multi-flute, solid-carbide tools benefit from the latest advanced technologies in machine look-ahead, high-speed spindles, coatings and geometries.

Stusak emphasized the benefits of these machining strategies by explaining that the basic principle of metal cutting is forming a chip properly in relationship to edge geometry so that you are shearing the material, not plowing it. Both roughing and finishing benefit from optimized machining strategies, but especially roughing, where machining time can be greatly reduced.

Seco Tools has developed specific geometries, coatings, carbide substrates and edge preps for these difficult-to-machine materials. The company’s latest development in coatings is its patented HXT silicon-based coating for higher thermal resistance and abrasion resistance. “What we have found is that these same tools can be used to cut easier-to-machine metals such as tool steels, stainless steels and cast iron. So we’re now able to use these high-efficiency milling strategies to increase tool life and productivity on a broader range of easier-to-machine materials,” said Ball.

Also for hard-to-machine materials, Sandvik Coromant’s recently introduced CoroMill 316 exchangeable milling heads are optimized for titanium and nickel-based metals. For titanium, grade 1745 with its 1.5×D cutting edge “is a little bit longer of a replaceable-tip end mill compared to our standard 316s,” explained Scott Lewis, aerospace industry specialist for Sandvik Coromant. To be released in the near future is grade 1710 for nickel alloy, which will also have 1.5XD capabilities. Both grades feature unique substrates and geometries and are currently available in the company’s solid-carbide end mills. These replaceable-tip end mills “can run, cutting data wise, quite close to what a solid is, with a solid being perhaps more rigid because it is shorter—a stouter setup,” Lewis said. “We also have very short, stout adapters for our 316s.”

These machining strategies require more just than the right carbide grade, insert and geometry—the way of approaching the material is also critical. The goal of high-efficiency machining is to reduce the width of cut and increase the length of cut to reduce cutting forces, which allows faster machining. Sometimes it is quicker that way, and sometimes it is quicker using traditional high-feed cutters. Many times with dynamic machining there can be much wasted movement. Applying it depends on the application and complexity of the features, such as pocketing, that are involved.

The modular part of the system “is that there are indexable insert heads that also mount onto the two drill bodies,” said Ewing. They are offered in eight metric sizes (33-40 mm) and two inch sizes (1.375" and 1.5") and use standard SOMX inserts from the DR Twist line. “They also use guide pads from the BTA Deep Drill line. The drilling depth of this system is in the 16.5-17" [419-432 mm] range.”

Horn’s solid-carbide tools with seven or nine flutes with large DOCs and 10-15 percent stepover—as a rule of thumb to start with—help with these strategies, but the machine tool must have the required acceleration and deceleration. An older machine with rapids of 600 ipm will not be sufficient. Similarly, the look-ahead that newer machines have is also required.

Bruhis described how he evaluates and determines an approach to a titanium machining project. “I typically inquire first about the machine capability, whether three-, four-, or five-axis, vertical or horizontal, fixturing and tooling,” he said. He added that in the majority of cases, specific end mills are selected based on axial or radial cut, speeds and feeds, and programming for high-speed and high-efficiency machining.

The initial release of the I-One will feature a single grade for the energy industry, with general-purpose grades and geometries to follow. I-One’s multilayer coating is geared to high or low speeds and is designed to tolerate heat and abrasion and prevent sticking. It is fully coolant-through.

The advantage of multi-flute end mills is that operators can take higher feed rates because of the reduction in DOC and stepover with high-temperature, heat-resistant materials. “These metals don’t like to be machined in the conventional way with large DOCs and large radial stepover and slow feed rates,” said Ball. “Multi-flute tools allow increased MRRs without work hardening because you can run faster feed rates and lighter radial stepovers with more teeth.”

“Various grade options allow better flexibility and optimization vs. solid carbide tools” and feature proprietary Sumo Tec PVD post-coating technology that provides “improved toughness, improved flaking, and chipping resistance, which in turn provides very reliable and repeatable results.” Those grades are:

“The biggest thing we’ve done is introduced new grades optimized for steel, stainless steel and cast iron,” he continued. “Our Zertivo technology uses a PVD process, and we are able to achieve better bonding between the substrate and coating to where we have significant improvements in edge line security—resulting in longer, predictable tool life.” Grades include –PM 4334 for low alloyed and carbon steels, –MM2334 for stainless and –KM3334 for cast iron. While there is no grade specifically for heat-resistant materials, Loughney added, “we can cross over our geometries into those areas” for multiple industries.

But what about performance? Ultimately, using replaceable-tip drilling tools generally does not mean sacrificing much penetration rate or tool life—to a point—experts assert.

Here’s how leading tooling manufacturers are helping customers put these tools to work in machining titanium, nickel-based alloys, superalloys, Inconel and stainless steel.

Chip-splitting technology reduces the radial tool pressure encountered with long lengths of cut and helps break up the chips, producing more manageable chips for the operator or the chip pan or conveyor to remove, Stusak explained. “The key to machining difficult-to-machine materials is the radial engagement,” he said. “You want to minimize the width of cut or arc of contact to beat the heat.” By minimizing the width of cut, not as much heat transfers into the tool because of the limited amount of cut time on the end mill.

Horn’s DSFT end mills—part of the DS line of high-DOC, low-radial-engagement tools—are designed for trochoidal machining. To be effective, DS tools require a solid machine spindle with close runout and a capable controller for programming. CAD programs are available to create simulation of machining time estimates to decide whether traditional end milling or high-speed machining is best. In addition, there are a number of software tools available to evaluate the economics of these tooling decisions.

As a result, the DIAEDGE STAW demonstrates “excellent chip disposability and achieves high-efficiency machining,” Griggs noted. “STAW replaceable carbide tips/inserts are designed for extreme sharpness, precision, positioning and rigidity in our unique clamping system. The wavy edge design delivers a sharp peripheral edge to enhance cutting performance, complemented by a strong center point geometry for initial cutting at entry. A high helix offers a low-resistance drill pocket design that improves chip breaking for superior chip disposal.” The STAW’s clamping system has more material behind the tip for added strength and durability.

Carmex recently introduced new coatings for its Slim MT line. “This nano coating can handle temperatures 30 percent higher than TiAlN and is 25 percent harder than other coatings typically used for indexable cutters,” said White. “These coatings outperform others in high-temperature alloys like inconel and titanium.”

“In evaluating machining for large aerospace parts, for example, while I’m not a programmer, in most cases I can look at the program and tell what ought to be changed,” said Bruhis. “In the last few years between traveling and working all over the world, if I can’t review the program, I have my customer send a video of the simulation and hold an online meeting to discuss possible program modifications. Through Skype interactions, I do simulations and alter programs constantly.”

Not every part is a good candidate for high-speed machining. The choice of strategy is a function of the part geometry and size. Some of the testing that’s being seen has been calling for machining Inconel, titanium, and stainless with light depths of cut, high speeds and low radial engagement and feed rates.

The current crop of replaceable-tip milling and drilling tools features a host of new substrates, geometries, PVD coatings and coolant solutions geared for a range of applications across numerous industries and materials. As always, the decision to use a particular tool is application specific.

YG-1 has developed standard tools specifically for high-speed machining of titanium, but about 30 percent of its tools for this application are still custom made, with special lengths and corner radii. “One of the trends with high-speed machining is the increased number of flutes needed to take light cuts and run very fast,” he said. “The trend of the last five years is for five, six, seven and nine flutes,” he said. The advantage is longer tool life and better heat and chip control as well as machining performance.

“Clearly, a small replaceable insert or tool head made of carbide costs less than an entire solid drill of the same diameter,” noted Andrew Pisorn, solid carbide product manager at Allied Machine & Engineering Corp., Dover, Ohio. And, by extension, using a range of replaceable-tip tools with a smaller number of steel body holders greatly improves operational and cost efficiencies by cutting down on one’s inventory of unique solid-carbide tools. “If your shop can minimize the amount of carbide in your tool cribs and drawers, you’re minimizing inventory costs.”

“Finishing is typically done with a 45o helix end mill for hardened materials up to 65 HRC because the higher helix angle shears the material more effectively,” he said. “End mills with a 60o helix angle are used on nonferrous materials like aluminum and even high-nickel-content alloys in finishing applications. In general, a variable pitch end mill with a 35 to 38o helix angle is the most common we see in the industry because it has a good balance of edge strength and core diameter, and it’s a little bit more up sharp in the cut where it slices through the material more effectively vs a 30o helix end mill.”

The ECY-S5 end mill with five flutes features a general-purpose substrate and AlTiCrSiN coating (IC608) for shoulder or full slot high-speed milling or trochoidal or peel milling. Its primary application is stainless but it can also be used to machine nickel-based, high-temperature alloys.

Slated for release midyear is YG-1’s I-One drill. “We’re performing extensive testing with it in the energy industry, with very good success,” Pulvermacher noted. It will exist alongside the company’s well-established I-Dream drill, which currently has several geometries: Dream Drill General for general purpose (carbon steel, iron); one for stainless (Inox); Dream Drill Alu (aluminum), High Feed (carbon steel, iron); and High Hard (up to 70 HRC).

Like other companies contributing to this article, Horn USA Inc., Franklin, Tenn., stresses both the importance of multi-flute tool design and customer collaboration for tooling success. “I would describe us as an engineering-driven company that approaches tooling solutions for its customers with finesse,” said Edwin Tonne, training and technical specialist. Horn, which is well known for its grooving and cut-off turning tools, offers a broad line of products, including solid-carbide end mills, drills, and indexable milling cutters, as well as its turning products. More than 40 percent of its cutting tools are specials. Horn has developed multi-flute end mills used to machine titanium, Inconel, stainless and other high-temperature-resistant metals using high-speed and high-efficiency machining strategies to achieve the highest MRR.

Inserts are available in sizes from 10-18.1 mm, and the VP15TF and DP5010 PVD coated grades feature tough carbide substrates and proprietary crystal coating technology. For machining a wide range of materials, from alloy steels to various types of stainless steel and cast iron, the VP15TF grade ranges from 100-400 sfm, Griggs added. “The drill body is made resistant to corrosion and abrasion by using a superior high-heat resistance alloy and a special surface treatment suitable to counter new hard-to-machine work materials.”

PVD coatings are most common for smaller diameter tools, he added, “because they help maintain sharper edges than thicker CVD coatings. Kyocera’s R&D efforts in PVD coating technology have resulted in our Megacoat coatings. With high oxidation temperatures and high hardness, they are ideal for running at higher speeds, resulting in reduced cycle times.”

For deeper, large-diameter applications, the Iscar ModuDrill is a combination of replaceable head and indexable insert drills in larger diameters for depths beyond 12×D. The ChamIQ 700 family is offered in a diameter range of 33-40 mm in 0.5 mm increments and “some common fractional-inch increments,” he said. “The HFP carbide blades, which look more like a spade drill, fit into a range of steel adapter heads (MD-DFN), which also mount onto a long steel drill body (MD-BODY). A combination of two drill bodies and seven adapter heads cover the entire diameter range.”

In terms of drilling, the number and type of holes to be made is generally the key determinant for opting to use replaceable-tip tools, according to Allied’s Pisorn. The more holes (from 1,000 to 50,000 or more) and the shallower (up to 13×D) the better.

With high-temperature-resistant, nickel-based alloys being used more commonly by its customers, Seco Tools LLC, Troy, Mich., is focused on maximizing metal removal rates using high-speed, high-efficiency optimized roughing strategies, according to Jay Ball, solid-carbide product manager.

Another inventory factor to consider: Shops that routinely send solid-carbide tools for regrinding must keep an adequate supply of solid tools in reserve to maintain production, said Patrick Loughney, a product manager at Sandvik Coromant, Fair Lawn, N.J.

Cycle times for five-axis machining of molds, blades and other complex aerospace and medical parts can be reduced up to 90 percent with Circle Segment solid-carbide end mills, according to Emuge Corp, West Boylston, Mass. While manufacturers performing high-speed machining may be familiar with using traditional ball nose end mills to make small stepover passes, Circle Segment end mills use high stepover passes up to 10 times greater than ball nose end mills to cut out large areas of material, maximizing efficiency and minimizing cusp height.

Allied’s new GEN3SYS XT Pro drills feature dual gundrills with four outlets for increased coolant flow and material-specific inserts with coatings developed in-house. “A unique connection design offers superior torsional loads while still allowing the convenience of insert swaps while the tool remains in the spindle,” Pisorn said.

“Some smaller sizes come in smaller shank diameters and shorter OAL (overall length) without a flange for Swiss lathe and live tool applications,” he added. “There are also drill bodies with integrated chamfering inserts.”

SumoCham is available from 4-32.9 mm diameter in 0.1 mm increments, Ewing explained. Heads are offered in 10 geometries for various material groups and applications, and bodies are offered in 1.5×D, 3×D, 5×D, 8×D and 12×D through most of the diameter range. Each body accepts a range of head diameters: from 4-14.9 mm, bodies come in 0.5 mm increments, and from 15-32.9 mm, bodies come in 1-mm increments.

Replaceable-tip tools can also provide users with a significant reduction in setup times, Loughney added, for instance on transfer lines for automotive manufacturing. And, with the ever-pressing shortage of experienced manufacturing labor, quick and easy tool switchouts instead of more intensive setups help ease that burden.

“Processing these materials with conventional machining processes tends to work harden them,” he explained. “Using high-efficiency milling and optimized roughing, there is a lot less heat generated because you are taking lighter radial stepovers and depths of cut (DOC), but not putting a lot of heat into the workpiece,” he said. “Where the typical solid-carbide end mill used for roughing and finishing typically had four and five flutes, with high-efficiency milling now taking over the industry we have added six-, seven- and nine-flute tools.”

Another drill that’s been on the market a while is the CoroDrill 870 series by Sandvik Coromant. But since its introduction in 2012, numerous refinements have been made. “We found that the body material was wearing, so we made it more wear-resistant, making the drill more rigid,” explained Loughney.

However, any time an operator makes changes in the machine, something can always go wrong. For instance, they must take care not to drop wrenches and screws into the machine while replacing tools.

For large-diameter applications, true helical flutes are the key to the success of the SRH series of replaceable mills by Carmex, said White. Helical flutes cut freer than straight-flute tools, he explained, although “solid thread mills are still the most efficient choice for anything under 1" (25.4 mm) thread diameter because you get more flutes in the cut and the geometry allows for higher cutting speeds and faster feed rates.” The SRH has been most successful in the oil and gas market, threading buttress and Acme threads in large diameters, he added.

The ECKI-H4R-CF four-flute end mill features corner radii for aerospace applications and either of two coatings, IC300 TiCN or IC900 AlTiN. It offers variable pitch and variable helix and a special edge prep for machining titanium.

The goal is to maximize flute length because that’s what will provide the best MRR in combination with 5 and 10 percent stepovers. Another way to determine tool selection is to decide whether to simply switch to high-feed milling and ramp in with a conventional end mill and rip the stock out.

Understanding the composition of these materials is key to understanding the limitations with cutting speed. “Workpiece hardness and material composition have a huge bearing on machinability,” he explained. “Nickel-based, cobalt-based, and ferrous-based superalloys have certain alloying elements in them that won’t allow elevating the sfm because you can’t eliminate the heat in the cut no matter what you do with the width of cut or cutting speed. [Cutting speeds have] to stay between 80 to 110 sfm depending on the hardness of the material.”

Removing metal is important, and doing it fast enough to make money is more important. To capitalize on the latest machining strategies for milling difficult-to-machine materials, Iscar Metals Inc., Arlington, Texas, continues to add to its lines of multi-flute, solid-carbide end mills, according to Bryan Stusak, national product manager–milling. Iscar has designed solid-carbide end mills specifically for milling strategies, including high-speed milling, high-efficiency milling, optimized roughing and proprietary CAM strategies like Mastercam’s Dynamic Milling.

When drilling difficult-to-machine materials like stainless steel or titanium, steel bodies for replaceables might torque too much, Pulvermacher cautioned. For that reason, fabricators have tended to split their use of solid and replaceable tools for those materials about 50-50, depending on the diameter. For that to change, he said, replaceable-tip tools would have to outperform solid in the 0.5-0.75" (12.7-19.05 mm) range. Replaceable-tip drills might get the nod in larger diameters, where solid drills could cost up to $750; however, replaceables struggle under 7/16" (11.11 mm) because they are somewhat expensive relative to solids—and the small tools, screws and inserts tend to get lost.

Besides the component, programming strategy and software play into this as well. If a shop is performing high-efficiency or high-speed milling, it must have the horsepower and torque required to drive the tool. If it runs the wrong software, there will be a lot of costly, wasted moves.

XT Pro carbide inserts have a combination of substrate coating and geometry engineered to survive the wear of high-penetration drilling, which “inherently produces significant heat,” Pisorn noted. “Combating that heat well is critical to extending tool life and increasing drilling rates. We have worked closely with our coating team and partners to develop several new material-specific, proprietary, multilayer coatings designed to withstand increased heat thresholds.”

At Mitsubishi Materials U.S.A. Corp., Schaumburg, Illinois, the company’s DIAEDGE STAW indexable drills “are unique in that they have cutting edge geometry that is the same as the edge geometry on our DIAEDGE WSTAR solid-carbide drill,” said Barry Griggs, assistant business development manager of cutting tools. “The wave designed cutting edge and center point gash is aimed at improving machined hole accuracy.”

The following is a consensus report of an interview held with Tonne, Eric Carbone, application and sales engineer; John Kollenbroich, head of product management; and Jeff Shope, application and sales engineer.

He also noted that the trend in titanium alloys and exotics machining in the last four or five years is toward high-speed machining for medium to large parts because the cost of removing titanium or Inconel is much higher than that of aluminum or steel.

YG-1 touts its 7×D drill as the only one of its type on the market, Pulvermacher noted. “People really like it because 8×D gives up so much rigidity.”

There are other advantages. “By minimizing the width of cut you can elevate the surface footage on most alloys, with the exception of nickel-based alloys,” said Stusak. “You can’t elevate cutting speed that much because it is impossible to eliminate the heat in the cut, but for Ti6Al4V we have case studies where we have machined up to 400 sfm at 4 percent radial engagement with these tools.”

“We determine the process and program and run it within a range of speeds and feeds and estimate a cycle time,” Bruhis said. “Once the customer has a chance to run the program that we have set, we then can get feedback with real machining time results and, if the cycle time is too long and the cost is not in line with expected results, we make the required adjustments.”

Replaceable-tip cutting tool suppliers offer numerous examples of how those tools surpassed solid-carbide versions. For instance:

The objective of both high-speed and high-efficiency machining strategies is to improve MRR, according to Yair Bruhis, global product and application manager for YG-1 Tool Co., Vernon Hills, Illinois. High-efficiency machining increases cutting by limiting air cutting time. “Because the two machining strategies are so effective, people want to switch everything towards them,” said Bruhis. “But it all depends on the part and the machining parameters. Sometimes, I can look at the part and state that it can’t be machined with high-efficiency strategies because of the shape and complexity of the part, or the machine’s capabilities, or the part features and programming, among other factors.

“For example, if I would expect to get a thousand inches of tool life with a solid, then I would expect the same from a modular tool—but of course exceptions apply,” said Bill Pulvermacher, director of marketing for YG-1 Tool Co., Vernon Hills, Illinois. “I would expect the overall penetration rate of the solid to be just a little bit higher.” Furthermore, some users say replaceable-tip drills over 0.5" (12.7 mm) tend to perform better in lathe applications “because they are much more tolerant of the misalignment that lathes tend to have.”

When weighing the choice of replaceable-tip mills and drills or solid-carbide tools, consider this succinct statement from one industry expert: carbide equals cost.

The option of smaller diameter, high-feed end mills is “a popular option for harder tool and die steels, especially in the aerospace and mold industries,” Wilshire continued. “Customers tend to run the replaceable-tip drills and indexable end mills faster than their solid-carbide counterparts to shorten cycle times because the replacement costs are less and the time to index is shorter.”

The end mills are available in four geometries: barrel-shaped, oval form, taper form and lens shape. Oval and taper form mills are suited for curved shapes such as blades or straight-walled pockets, freely engaging more of the cutting edge. Barrel design mills provide effective flank milling to the sides of spiral grooves and similar applications, according to Emuge. Lens-shaped mills excel in narrow channels or in lands on molds. Specific CAM systems software, such as Mastercam and hyperMILL, are required to support and compute the geometries.

He added: “We have started to play a lot more with variable indexes and [helixes] in multi-flute cutting tools because of their potential for more cutting pressure due to increased tool contact with the workpiece. However, it’s necessary to change [helixes], rakes and indexes to vary the geometry in such a way that it breaks up chatter and harmonics and still retains the tool’s ability to cut efficiently.”

Fabricators seeking smaller diameters can look to Iscar’s SumoCham line, now available down to 4 mm in up to 5×D applications, said Craig Ewing, national product specialist for Iscar Metals.

These optimized high-speed and high-efficiency machining strategies are the wave of the future. And they are here today. According to Ball, 80-90 percent of CAM software suppliers have some sort of optimized milling strategy for roughing and 80-90 percent of the major cutting tool manufacturers have some sort of multi-flute products for these strategies.

Toolholding is vital to precision holemaking with replaceable-tip drills, he continued. “You have to remember that you have collective tolerances—of the body itself and then a tip on top of it.”

Meanwhile, Kyocera Precision Tools Inc., Hendersonville, N.C. is noting increased demand for smaller, modular indexable end mills, said Technical Center Manager Brian Wilshire.

If it’s a very shallow “depth of part,” the machinist will not get the economy of the end mill and high speed and will experience a lot of excess vibration. The reason is if a shop runs a shallow axial depth of cut, it reduces MRR and the operation may not be as efficient as other methods with larger radial and shallower axial stepovers.

The highest MRR possible in high-speed machining with multi-flute tools occurs when the process engages the full flute length of the tool. The more flutes, the larger the core diameter for rigidity. Typically, the first thing to look at when considering high-speed machining is the size of the part and flute length to decide the diameter of the tool, according to Horn. An inch of actual flute length might be handled by a 3/8" (9.5-mm) diameter tool, and two inches of actual flute length by a 5/8" (15.8-mm) diameter tool.

On the larger side, Iscar’s LogIQ-3-Cham is a three-flute, interchangeable-head drill in 14-23.9 mm diameters, in 0.1-mm increments and bodies in 1.5×D, 3×D and 5×D. “Eventually, the line will include all head sizes from 12-25.9 mm. The three-flute design will provide extended tool life and/or increased feed rates,” mostly for ISO-P and ISO-K materials, Ewing said.

To more than double the depths of cut previously available in its Multi-Master line of end mills, Iscar Metals Inc., Arlington, Texas, added replaceable-tip mills capable of reaching depths up to 1.5×D, said Tom Raun, chief technical officer.

According to the company, time and cost savings and increased part quality result. Tool life is increased due to shorter toolpaths. Tolerance deviations due to heat warping at the tool are minimized, and axial deviations of the machine are smoothed, offering a higher quality surface finish in a shorter time frame. Circle Segment end mills feature unique forms with large radii in cutting areas of the mills, allowing a larger axial DOC during prefinishing and finishing operations.

“I talk to a lot of people in aerospace and the trend has changed in the last 10 or 15 years,” Bruhis continued. “It’s not the cost of the tool any more. Customers want to know the real cost of metal removal. There are a lot of cases where I meet with engineers or programmers and they clearly voice that they do not care about the price of the tool. Cycle time and tool life are the most important considerations.”

These drills are being used heavily in structural steel applications like beams and bracketing in areas such as bridge towers, Pisorn said. Planetary gears with flanges might feature 20 to 50 shallow holes; bearing rings for wind energy can feature 50-100 holes. Tube sheets for heat exchangers is another sound application. And, a filtration system plate for the paper industry might feature thousands of shallow holes.

The ECI-H4S-CFE end mill is a short, four-flute design with different helixes (35o and 37o) and variable pitch for chatter dampening. It can be used for high MRR roughing and finishing, with full slot milling up to 1×D. It is also available with the new AlTiCrSiN IC608 coating for machining at elevated temperatures.

Cutter paths vary and can include profiling, slotting, and pocketing. Workpieces can vary in complexity and size as well. YG-1 has tools for specific materials like titanium, Inconel or aluminum as well as general-purpose tools for smaller shops and multiple applications.

He pointed out that while getting material roughed out is difficult and can cause multiple problems, optimized roughing with 6-10 percent maximum radial stepovers is effective on heat-resistant superalloys (HRSA) and titanium. “And you can use these same tools to then finish a lot of these parts as well so you are using more traditional side mill finishing,” he said.

“When major OEMs call me in, it’s generally to improve tool life, the process, or both,” Bruhis continued. “It could be a new project with them facing a serious issue. It might be a problem with part quality, or cycle time or delivering parts in time or total cost, but it’s almost never because of the cost of the tool since YG-1 offers a very attractive performance-to-cost package.”

It is different with PH stainless, some duplex stainless steels, and titanium alloys where speed can be increased to get more productivity out of the tool. “Duplex stainless steels that have a lot of nickel and chrome content machine more like Inconel materials because of the high nickel content. So, it’s essential in machining high-temperature alloys to understand the alloying elements in them,” he said.

Jim White, national sales manager for Carmex Precision Tools LLC, Richfield, Wis., concurred. “The reason most customers go with indexable is versatility—using one holder for multiple pitches—or cost,” he said, adding that “indexable thread mills are more cost effective in large-thread diameter applications or low-volume jobs where cycle time is not a consideration.”