Big Kaiser adds 30 pressed-geometry carbide inserts for its tools - carbide insert geometry

Included angle at the point of a twist drill or similar tool; for general-purpose tools, the point angle is typically 118°.

ATI Stellram  (615) 641-4200www.stellram.com Greenleaf Corp. (800) 458-1850www.greenleafcorporation.com Kennametal Inc. (800) 446-7738www.kennametal.com Sandvik Coromant Co. (800) 726-3845www.coromant.sandvik.com/us Seco Tools (800) 832-8326www.secotools.com

Measurement of the total angle within the interior of a workpiece or the angle between any two intersecting lines or surfaces.

Also, a machine operator can vary a round insert’s approach angle to reduce chip thickness. “We’re always looking for thinning the chip,” Gardner said. “When we thin the chip with the approach angle, it gives us better productivity; we create less heat. The more heat we put into them, the more friction we create, the more [heat] these materials will throw back,” producing a burned-out insert. Protecting the tool from burn-out doesn’t mean applying it timidly, though.

For example, a round insert’s maximum DOC shouldn’t be more than 25 percent of the tool’s diameter. At more than 25 percent, the tool will have too much contact area with the workpiece, resulting in too much pressure and heat, Gardner said. “We’re going to just blow the insert away,” he added, “or we’re going to damage the component.”

As the Advanced Engineering show approaches, there are fresh announcements of cutting-edge technologies and products to be showcased at the upcoming event at the NEC in Birmingham on October 30 and 31. As a result, this year’s exhibition is shaping up to be a must-attend for engineering and manufacturing professionals, offering a glimpse into the f...

The 3D Finish tools are available in a barrel, oval, taper or lens shape and are ideal for the five-axis finishing of free-form surfaces, such as in tool and die production or, in the aviation and aeronautical industries. The cutters are available in a wide variety of size and style to ensure the ideal cutter geometry for any component shape. Also, in terms of application they are universal in that the 3D Finish milling cutters are suitable for machining steel, stainless steels, cast iron, non-ferrous metals, heat-resistant steels and hardened steel.

Consequently, parts manufacturers have to maximize machine tool and workholding rigidity if they want to successfully apply round inserts.

Workholders and machine tools must be rigid to apply round inserts because the tool’s radius, relatively large compared with a straight-edged insert, means more contact area and therefore more cutting pressure.

Time saved via higher feed rates means money saved. “The amount of money you can save [by using round inserts] over the life of running an insert is phenomenal,” Tisdall said, adding that actual cost savings depend on a shop’s overhead, annual number of components and reduction of a part number’s process time.

Also, Graham recommended the tool have a PVD coating, not a CVD coating, when machining a high-temperature alloy with a hardness of greater than 32 HRC because PVD is usually thinner and therefore better maintains a tool’s edge definition. He added that PVD coatings are also preferred because of their resistance to wear, BUE and cratering—all common failure modes when machining nickel-base alloys.

Machining grooves and shallow channels. Example: grooving ball-bearing raceways. Typically performed by tools that are capable of light cuts at high feed rates. Imparts high-quality finish.

Workholding device that affixes to a mill, lathe or drill-press spindle. It holds a tool or workpiece by one end, allowing it to be rotated. May also be fitted to the machine table to hold a workpiece. Two or more adjustable jaws actually hold the tool or part. May be actuated manually, pneumatically, hydraulically or electrically. See collet.

Their greater strength makes round inserts excellent at rough turning the scale present on forged and cast workpieces. Their strength also makes them less prone to chipping and breakage than other types of inserts.

Depressions formed on the face of a cutting tool caused by heat, pressure and the motion of chips moving across the tool’s surface.

Round inserts can be made with different features, like a chamfer (upper left and lower right) and a positive rake angle (lower right), to reduce problems that can be encountered when turning high-nickel alloys.

Trochoidal turning, however, involves smaller DOCs. “It’s a light plunge into a turn,” Tisdall said. “With a lighter DOC, you don’t have as much engagement of the insert when you come up to that wall.”

Workpiece is held in a chuck, mounted on a face plate or secured between centers and rotated while a cutting tool, normally a single-point tool, is fed into it along its periphery or across its end or face. Takes the form of straight turning (cutting along the periphery of the workpiece); taper turning (creating a taper); step turning (turning different-size diameters on the same work); chamfering (beveling an edge or shoulder); facing (cutting on an end); turning threads (usually external but can be internal); roughing (high-volume metal removal); and finishing (final light cuts). Performed on lathes, turning centers, chucking machines, automatic screw machines and similar machines.

However, a negative rake angle tends to create greater cutting force, which may not be right for a particular application. Hill recommends the correct geometry for the job. “Use negative whenever possible for strength and economy—negative tools are generally double sided, allowing for more cutting edges. Use positive geometry if surface finish, tool force or built-up edge is a concern.”

Round inserts can be worthwhile, though, because they’re strong and can be fed at higher rates than other types of inserts, more than making up for their disadvantages in certain applications.

Walter has now launched its new X·treme Evo Plus drill from the DC180 Supreme product family that is now available up to 8XD for the first time.

Finally, a round insert can more easily damage a workpiece than a straight-edged insert. A round insert has a relatively large radius compared with a straight-edged insert, which has small radii at its corners. A large radius means more contact surface, which results in higher cutting forces. “This can be detrimental when applied in weak setups, extended tooling or on workpiece features that have a thin cross section,” said Dale Hill, applications engineer for toolmaker Greenleaf Corp., Saegertown, Pa. Detrimental effects include workpiece deflection and vibration.

According to Graham, a tool material exists for machining at even higher speeds than ceramics. “With CBN, you can run 1,000 sfm.”

The tool’s inability to create small-radius corners leads many parts manufacturers, and their programmers, to apply other insert shapes. “The CNMG is pretty much the first choice for any programmer because of the combination of flexibility and edge strength,” said Bill Tisdall, development specialist manager for toolmaker Sandvik Coromant Co., Fair Lawn, N.J. “You can OD turn, you can face, you can out-copy, you can turn to a square shoulder. With a round insert, you can’t turn to a shoulder. You can do all the other things.” (Out-copying is machine movement that combines a Z-axis movement toward the chuck with an X-axis movement away from the center line of the workpiece.)

1. Permanently damaging a metal by heating to cause either incipient melting or intergranular oxidation. 2. In grinding, getting the workpiece hot enough to cause discoloration or to change the microstructure by tempering or hardening.

Tough, difficult-to-machine alloys; includes Hastelloy, Inconel and Monel. Many are nickel-base metals.

Graham estimated that round inserts can be fed 20 percent faster than other types of inserts, depending on the round tool’s chipbreaker, which can be designed for different feed rates. Graham cited a chipbreaker with a neutral land and relatively wide groove as an example, saying that a round insert can take a heavier feed rate than one with a positive rake and narrow groove width. (See recommended feeds and speeds chart on page 39.)

Cutting tool materials based on aluminum oxide and silicon nitride. Ceramic tools can withstand higher cutting speeds than cemented carbide tools when machining hardened steels, cast irons and high-temperature alloys.

Sheffield Business Park Europa Link S9 1XU UNITED KINGDOM

Tooling manufacturer, Horn has introduced a new carbide insert grade, SG66, for turning components from steel that has been case hardened to 58 HRC.

Conditioning of the cutting edge, such as a honing or chamfering, to make it stronger and less susceptible to chipping. A chamfer is a bevel on the tool’s cutting edge; the angle is measured from the cutting face downward and generally varies from 25° to 45°. Honing is the process of rounding or blunting the cutting edge with abrasives, either manually or mechanically.

Engagement of a tool’s cutting edge with a workpiece generates a cutting force. Such a cutting force combines tangential, feed and radial forces, which can be measured by a dynamometer. Of the three cutting force components, tangential force is the greatest. Tangential force generates torque and accounts for more than 95 percent of the machining power. See dynamometer.

Parts manufacturers can take advantage of a PCBN round tool’s ability to turn high-nickel alloys up to 1,000 sfm.

However, Graham said inserts should have CVD coatings when they’re machining softer superalloys, like Inconel 600, because the predominant failure mode is cratering and a thicker coating better protects against cratering.

As good as they are, though, parts manufacturers may find coated, carbide round inserts insufficient for their use. “Their disadvantage is that they will be significantly limited in speed capability compared to ceramic cutting tools,” Kennametal’s Battaglia said.

Machining vertical edges of workpieces having irregular contours; normally performed with an endmill in a vertical spindle on a milling machine or with a profiler, following a pattern. See mill, milling machine.

He added, though, that carbide inserts are sometimes needed when a machine tool’s limitations or a part’s fixtures require running at lower speeds or during final finishing of critical aircraft components. “Often carbide is explicitly specified to be run at a low speed so that any possible damage or ‘white layer’ formation on the part surface is avoided,” Battaglia explained.

1. Permanently damaging a metal by heating to cause either incipient melting or intergranular oxidation. 2. In grinding, getting the workpiece hot enough to cause discoloration or to change the microstructure by tempering or hardening.

Sandvik Coromant’s Tisdall generally prefers that round inserts have a CVD coating in most applications. “A CVD grade will provide better tool life and higher-speed capability because the coating is typically much thicker.” He said, however, that a CVD coating is more prone to notch wear than a PVD coating because of the CVD process itself. According to Tisdall, the CVD process creates an eta phase in an insert’s carbide matrix, depleting the matrix of its cobalt binder, which acts to resist notch wear. Also, depleting the matrix of its binder weakens the carbide substrate.

Groove or other tool geometry that breaks chips into small fragments as they come off the workpiece. Designed to prevent chips from becoming so long that they are difficult to control, catch in turning parts and cause safety problems.

Cutting tool material consisting of polycrystalline cubic boron nitride with a metallic or ceramic binder. PCBN is available either as a tip brazed to a carbide insert carrier or as a solid insert. Primarily used for cutting hardened ferrous alloys.

Crystal manufactured from boron nitride under high pressure and temperature. Used to cut hard-to-machine ferrous and nickel-base materials up to 70 HRC. Second hardest material after diamond. See superabrasive tools.

Round inserts may be underutilized in some manufacturing sectors, but the aerospace and oil and gas industries shouldn’t be among them.

Parts used in extreme conditions require extreme materials. The part may be a large ring or shroud in a jet engine, which operates at up to 1,200° F, or can be a down-hole component in an oil field, operating in a corrosive environment hundreds of feet underground.

Rate at which metal is removed from an unfinished part, measured in cubic inches or cubic centimeters per minute.

Round inserts for turning high-nickel alloys may be CVD or PVD coated depending on the tool’s performance characteristics relative to a particular alloy, such as the tool’s main failure mode.

Ceramics can run at such high speeds because their melting temperatures are much higher than the melting points of any metal they would cut. For example, a whisker-reinforced ceramic round insert—that is, a tool consisting of an aluminum-oxide matrix with silicon-carbide crystals—can have a melting temperature of slightly more than 2,000° C. Given such high melting points, ceramic inserts resist deformation and softening at very high temperatures.

The NeoMill-Alu-QBig indexable insert milling cutter from Mapal stands for top performance in high-volume milling of aluminium. The tool manufacturer thus offers a very economical solution for use on high-performance machines, such as those found primarily in the aerospace industry.

If you find this article informative, consider subscribing digitally to Aerospace Manufacturing for free. Keep up to date with the latest industry news in your inbox as well as being the first to receive our magazine in digital form.

Round inserts can’t cut small-radius corners and aren’t well suited to creating complicated profiles, but the tools have the strongest shape of any insert and can be applied at high feed rates. With appropriate rake angles and cutting strategies, the round insert is excellent at the extreme task of turning high-nickel alloys to create parts for the extreme environments inside jet engines and down-hole in oil fields. CTE

About the Author: Joseph L. Hazelton is a freelance writer with 8 years of experience writing and editing articles for metalworking publications.

“There’s more material behind the force in a round insert, more material to absorb the force,” Graham added.

Hardness is a measure of the resistance of a material to surface indentation or abrasion. There is no absolute scale for hardness. In order to express hardness quantitatively, each type of test has its own scale, which defines hardness. Indentation hardness obtained through static methods is measured by Brinell, Rockwell, Vickers and Knoop tests. Hardness without indentation is measured by a dynamic method, known as the Scleroscope test.

Joseph L. Hazelton is a freelance writer with multiple years of experience writing and editing articles for metalworking publications.

According to Graham, producers of parts for oil and gas applications typically prefer negative or neutral rake angles on their round inserts because the angles provide extra strength. Those companies also like the inserts to have strong, heavy chip grooves.

In assessing the cost-effectiveness of the WNT 3D Finish tools, the machining experts at the Ceratizit Group carried out extensive trials. These highlighted the major time savings that can be achieved when compared to a conventional 10 mm diameter ball nose cutter. In the trial a 100 x 200mm component was milled at a feed of Vc 200m/min. Owing to the higher stepover of 1.5mm for the 3D Finish (compared to 0.1mm for the ball nose cutter), the total milling travel was reduced from 200m to just 13m, with a corresponding reduction in cycle time from 79 minutes to 7 minutes and a resulting reduction in machining cost of 88%. To fully exploit the advantages of the 3D Finish tools fully, a modern 5-axis machining centre and compatible CAD/CAM software are required, such as Open Mind’s hyperMILL MAXX, which supports the tool geometry, other software suppliers also offer CAD/CAM solutions.

Angle of inclination between the face of the cutting tool and the workpiece. If the face of the tool lies in a plane through the axis of the workpiece, the tool is said to have a neutral, or zero, rake. If the inclination of the tool face makes the cutting edge more acute than when the rake angle is zero, the rake is positive. If the inclination of the tool face makes the cutting edge less acute or more blunt than when the rake angle is zero, the rake is negative.

Round inserts can operate at higher feed rates because they have the strongest geometry. “The larger the included angle of the cutting edge, the more inherent strength you have in that insert,” said Frank Battaglia, staff engineer–global machining technology with Kennametal Inc., Latrobe, Pa.

Moreover, their strength and related long life mean round inserts are well suited to turning the large workpieces often manufactured by aerospace and oil and gas companies. “The round insert provides the best tool life and strength of any shape of an insert, so when you have a very large length of cut, you’re able to machine that full length with a round insert,” said Sandvik Coromant’s Tisdall. “With an angled insert, you’re typically going to get less tool life. You’d have to index the tool midcut.”

Process of both external (e.g., thread milling) and internal (e.g., tapping, thread milling) cutting, turning and rolling of threads into particular material. Standardized specifications are available to determine the desired results of the threading process. Numerous thread-series designations are written for specific applications. Threading often is performed on a lathe. Specifications such as thread height are critical in determining the strength of the threads. The material used is taken into consideration in determining the expected results of any particular application for that threaded piece. In external threading, a calculated depth is required as well as a particular angle to the cut. To perform internal threading, the exact diameter to bore the hole is critical before threading. The threads are distinguished from one another by the amount of tolerance and/or allowance that is specified. See turning.

A round insert can be fed up to 20 percent faster into a workpiece than other types of inserts because the tool has the strongest geometry of any insert shape.

Battaglia cautioned, though, that a ceramic round insert can still wear out if run too fast. Also, he recommended ceramic inserts’ cutting edges receive a chamfer, also known as a T-land or radius hone. He said the typical T-land has a width of 0.002 " to 0.004 " on the rake surface and an angle of 20° to 25°. “When you have a sharp-edged insert, that edge is susceptible to crack propagation,” he said. “When you add an edge preparation, you tend to direct those cutting forces more into the bulk of the material, so it makes it more difficult for a crack to propagate and lead to chipping of the cutting edge.”

A parts manufacturer has to consider whether to apply a round insert with a negative geometry, a neutral one or a positive one for machining a nickel-base alloy.

“Another key issue is a coating that will adhere to the edge line for a long period of time,” Tisdall said. “What you don’t want to do is finish a large aerospace component and find out that you’ve lost size because your coating has broken down halfway through the cut. You either are going to have to do a spring pass or you might scrap a part, and you are talking about a lot of money.”

Manufacturing companies are constantly looking to reduce machining times, their search may be over with the arrival of WNT’s 3D Finish range, which provides quick and reliable results, especially on time-intensive finishing processes, where it offers huge potential for shortening cycle times and improving productivity. The new 3D Finish from WNT (part of the Ceratizit Group) is said to enable users to significantly reduce the time spent on finishing processes carried out on 5-axis machines, while achieving improved surface qualities at the same time. The WNT 3D Finish tool range is a development of the ball-nose end milling cutter and has been designed with a large radius (up to 1,500mm) in the cutting area. This feature allows the cutters to achieve considerably increased stepovers when compared to conventional ball-nose cutters with the same tool diameter. The result is processing times in pre-finish and finish machining reduced by up to 90%, without the workpiece, tool and machine being subjected to a higher load. Much greater widths of cut (ap) are also possible so, in addition to reduced cycle times, surface quality is maintained, but is the user chooses to reduce the step-over then surface quality can be improved significantly. A typical Ø 20mm ball nosed cutter would achieve a surface quality of Ra1.6 µ with a stepover of 0.5mm, but with the 3D Finish and a radius of 1,500mm, the stepover could be increased to 6.93mm with the same surface quality result. The 3D Finish tools are available in a barrel, oval, taper or lens shape and are ideal for the five-axis finishing of free-form surfaces, such as in tool and die production or, in the aviation and aeronautical industries. The cutters are available in a wide variety of size and style to ensure the ideal cutter geometry for any component shape. Also, in terms of application they are universal in that the 3D Finish milling cutters are suitable for machining steel, stainless steels, cast iron, non-ferrous metals, heat-resistant steels and hardened steel. In assessing the cost-effectiveness of the WNT 3D Finish tools, the machining experts at the Ceratizit Group carried out extensive trials. These highlighted the major time savings that can be achieved when compared to a conventional 10 mm diameter ball nose cutter. In the trial a 100 x 200mm component was milled at a feed of Vc 200m/min. Owing to the higher stepover of 1.5mm for the 3D Finish (compared to 0.1mm for the ball nose cutter), the total milling travel was reduced from 200m to just 13m, with a corresponding reduction in cycle time from 79 minutes to 7 minutes and a resulting reduction in machining cost of 88%. To fully exploit the advantages of the 3D Finish tools fully, a modern 5-axis machining centre and compatible CAD/CAM software are required, such as Open Mind’s hyperMILL MAXX, which supports the tool geometry, other software suppliers also offer CAD/CAM solutions. www.wnt.com/uk/cutting-tools/milling-tools/3d-finish.html

Tool-coating process performed at low temperature (500° C), compared to chemical vapor deposition (1,000° C). Employs electric field to generate necessary heat for depositing coating on a tool’s surface. See CVD, chemical vapor deposition.

He compared inserts’ different included angles; the 100°, 90°, 80° and 60° corners of various inserts, all the way down to a VNG-insert, which has a 35° angle. “The cross-sectional area, going from one side of that insert to the other, gets smaller and smaller as you go down in that angle,” Battaglia said. “With a round insert, it’s really just maximized to the point where you have the largest cross-sectional area going across from one side of the cutting edge to the other side.”

High-temperature (1,000° C or higher), atmosphere-controlled process in which a chemical reaction is induced for the purpose of depositing a coating 2µm to 12µm thick on a tool’s surface. See coated tools; PVD, physical vapor deposition.

“Typically in aerospace, they will produce massive forgings,” Graham said. A 40 "-dia. ring that’s 0.5 " thick × 2 " wide may have started as a 48 "-dia. ring with a 6 " thickness and a 6 " width. “They remove massive amounts of material to produce that ring. That’s where a round insert is very useful because you can hog out a lot of material in an aggressive fashion,” Graham said.

Substances having metallic properties and being composed of two or more chemical elements of which at least one is a metal.

Angle between the side-cutting edge and the projected side of the tool shank or holder, which leads the cutting tool into the workpiece.

Manufacturing companies are constantly looking to reduce machining times, their search may be over with the arrival of WNT’s 3D Finish range, which provides quick and reliable results, especially on time-intensive finishing processes, where it offers huge potential for shortening cycle times and improving productivity.

The carbide’s structure is the first consideration. Gardner recommended a submicrograin substrate for continuous cutting without vibration. Seco Tools’ Graham agreed. “The micrograin provides increased abrasion resistance as well as deformation resistance,” he said. “The latter is extremely important when you’re machining nickel-base materials. They generate a lot of heat and pressure [when cut].” A steel, for example, softens when it gets red hot, Graham noted, whereas a superalloy retains its strength and hardness when red hot. “So even when it’s red hot, it’s still putting a lot of pressure on the insert.”

The next Southern Manufacturing & Electronics show will take place from 4th to 6th February 2025 at the Farnborough International Exhibition & Conference Centre.

Moreover, round inserts aren’t well suited to machining complicated profiles, like undercuts, and can’t create profiles not present in their geometry, according to Don Graham, manager of turning products for toolmaker Seco Tools Inc., Troy, Mich.

So aerospace and oil and gas companies have many of their parts made from nickel-base alloys (heat-resistant superalloys). To turn these materials, which include Inconel, Hastelloy, Waspaloy and Monel, manufacturers should have their eyes firmly fixed on that humble cutting tool, the round insert.

In a race, carbide—even a coated, submicrograin carbide—would be chasing ceramic at a long distance. “Say we take our best-case scenario of carbide—300 sfm on typical Inconel 718,” Greenleaf’s Hill said, adding that that speed involved light finishing, not roughing. “Ceramics are capable of running 800 to 900 sfm.”

He also said round inserts need an edge hone that’s not too large because that would create too much cutting force.

1. Spreading of a constituent in a gas, liquid or solid, tending to make the composition of all parts uniform. 2. Spontaneous movement of atoms or molecules to new sites within a material.

Greenleaf’s Hill added that a negative rake angle is particularly suitable for interrupted turning. “When it engages the workpiece, the majority of that chip or swarf impacts that top surface of the insert, which is the strongest area of that cutting tool,” he said. “So, in interrupted turning you’re now presenting the strongest area of your cutting tool to that abusive situation.”

Martin Gardner, global product manager—turning, threading and grooving for toolmaker ATI Stellram, La Vergne, Tenn., agreed. He suggested an RCMT insert, which has a 7° rake angle, for this application. “That’s probably the most popular insert we see in these types of applications,” he said. “They’re used for profiling and for narrow grooves.”

Nonetheless, Tisdall prefers a CVD coating when machining superalloys with a round insert. “The strength and chip thinning effect of a round geometry makes up for the inherent weakness of the edge line,” he said. “When machining superalloys with an insert with a point angle—CNMG, DNMG or VNMG in combination with a small lead angle tool—a PVD grade is preferable.”

Besides a round insert’s geometry, part makers for aerospace and oil and gas applications must consider whether they want a coated tool.

The new 3D Finish from WNT (part of the Ceratizit Group) is said to enable users to significantly reduce the time spent on finishing processes carried out on 5-axis machines, while achieving improved surface qualities at the same time. The WNT 3D Finish tool range is a development of the ball-nose end milling cutter and has been designed with a large radius (up to 1,500mm) in the cutting area. This feature allows the cutters to achieve considerably increased stepovers when compared to conventional ball-nose cutters with the same tool diameter. The result is processing times in pre-finish and finish machining reduced by up to 90%, without the workpiece, tool and machine being subjected to a higher load. Much greater widths of cut (ap) are also possible so, in addition to reduced cycle times, surface quality is maintained, but is the user chooses to reduce the step-over then surface quality can be improved significantly. A typical Ø 20mm ball nosed cutter would achieve a surface quality of Ra1.6 µ with a stepover of 0.5mm, but with the 3D Finish and a radius of 1,500mm, the stepover could be increased to 6.93mm with the same surface quality result.

Angle between the insert’s side-cutting edge and the line perpendicular to the milling cutter’s axis of rotation. Approach angle, which is also known as cutting edge angle, is used with metric units of measurement. See lead angle.

Any manufacturing process in which metal is processed or machined such that the workpiece is given a new shape. Broadly defined, the term includes processes such as design and layout, heat-treating, material handling and inspection.

In a significant move to streamline mechanical testing and enhance material insights, Airbus is collaborating with Plastometrex to support the standardisation of PIP (Profilometry-based Indentation Plastometry) – the innovative mechanical testing technique developed and commercialised by the Cambridge-based technology provider.

Tangential velocity on the surface of the tool or workpiece at the cutting interface. The formula for cutting speed (sfm) is tool diameter 5 0.26 5 spindle speed (rpm). The formula for feed per tooth (fpt) is table feed (ipm)/number of flutes/spindle speed (rpm). The formula for spindle speed (rpm) is cutting speed (sfm) 5 3.82/tool diameter. The formula for table feed (ipm) is feed per tooth (ftp) 5 number of tool flutes 5 spindle speed (rpm).

Tisdall also described a “roll-in method” of plunging and turning. A programming technique, the method includes a radius as an insert comes out of a plunge. “It’s another way of keeping the insert engaged with the workpiece without doing a sudden movement in a different direction. Let’s say you’re plunging in Z, and then you go to the X-axis and make a move in that axis. There’s a lot of stress on the insert. Here, we’re making use of a radius to basically make the process gentler on the insert.”

Despite some major advantages, round inserts may be unattractive to manufacturers for several reasons. One is they can’t machine small-radius corners. For example, a 0.5 "-dia. round insert can’t turn a 90° corner with a radius of 0.004 ". Its smallest corner radius is 0.5".

Dimension that defines the exterior diameter of a cylindrical or round part. See ID, inner diameter.

Some aerospace companies still prefer uncoated inserts, though, because they worry about the coating contaminating parts during manufacture. “Obviously, they don’t want anything that’s going to erode or deform that structure, however minute it is,” said ATI Stellram’s Gardner. “There have been many studies about the coating diffusion into the parent material. We’ve never found that diffusion into the material with a PVD coat. That said, some manufacturers of aero engine components still like to use uncoated inserts.”

Given their strength, it shouldn’t be surprising that round inserts need to be applied carefully to workpieces, even to high-nickel alloys.

Parts manufacturers should head straight to their high-strength round inserts to turn nickel-base alloys.

To turn a pocket, Tisdall recommends trochoidal turning over plunging and turning to reduce potential damage to the round insert or part. In plunging and turning, an insert endures stress when plunged into a workpiece and moved across the material to turn it until it reaches where the pocket’s wall will be. The stress can lead to chipping and possibly catastrophic failure.