By far the main challenge with machining titanium is dealing with heat. Titanium is tough stuff, so the potential for heat from friction is huge. It also doesn’t conduct heat well, so the heat is focused in the cut zone and it doesn’t dissipate quickly.

Combination type of machine screw die with two or more thread profiles, available in different sizes and thread forms; mostly used in Studs .Studs provide the ability to obtain much more accurate torque values because the studs don’t twist during tightening as do bolts and tends to remain stationary during nut tightening, the studs stretch in one axis alone, providing much more even and accurate clamping forces. Also, the use of studs results in less wear applied to the block’s threads, this extends the life of the threaded holes in the block over periods of servicing/rebuilding.

This is why titanium cutters will have something called secondary relief. Instead of a duller edge, there will be a very small flat along the cutting edge that’s not at such an aggressive angle. This makes that cutting edge considerably stronger, but doesn’t negatively affect the chip flow.

High pressure coolant, in the range of 300-1000 psi is considered a must by most machinists. The tricky part is that the coolant can push chips back into the cutter. This chip recutting not only drastically reduces tool life; it can cause process instability when it builds up and snaps the tool.

Dies can be supplied on a special basis for other machines and face depths, as well as from other special materials. In addition, other special thread forms, left hand threads and multiple leads can be supplied.

Machining titanium brings some unique challenges compared to other more common materials like aluminum and steel. But since there’s good money to be made in this kind of work, more and more shops are eyeing up these jobs.

For machining titanium, you want something with high torque, and generally lower RPM. Working out a practical max RPM is fairly straightforward. Just calculate the speed of the smallest diameter tool that you want to use to the full.

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A real perk of this technique is that it makes use of chip thinning – small stepovers produce thinner chips. This means that you can increase the feed to maintain chip thickness.

The strategies for machining titanium are very different from soft materials like aluminum or mild steel. If you’re familiar with machining high-temp superalloys like Inconel, you’ll see a lot of similarities in approach.

So let’s say that we’ll use a 1.0″ endmill to shear off a cut 1.5″ deep and 0.100″ wide, with a RPM of 800 and a feedrate of 24 IPM.

This usually is just a matter of testing. Eventually you’ll get enough of a feel for it where you’ll be able to guesstimate reasonably enough, but until then it’s just a matter of adding teeth until something breaks, and then going back one step.

This is a viable option when there’s a lot of material to remove and the geometry is highly accessible. It can also be a really effective way of tackling shallow geometry and facing operations.

Cutters for titanium are very different from what you’d typically use for other materials, like steel. While regular endmills for steel will work for titanium in a pinch, they really won’t perform very well at all.

The reason that heat is so deadly in titanium machining is because titanium work hardens. This means that if the material gets too hot while you’re working on it, it will get harder and harder. Harder material = more heat when cutting = harder material.

Titanium used to be a mystery material that only a few specialized shops could handle well. Now it’s nearly become a staple, and quite a few machinists will come across it at least at some point in their career.

With 10 flutes, you’ll get phenomenal feed rates. But if you’re shoving it into tight corners where there’s a huge amount of radial engagement and nowhere the chips can go, it’ll snap in half instantly. It doesn’t matter how fast your CAM says it can go, a snapped endmill won’t get the parts out the door any faster.

Use the calculator below to see how much harder you can feed the endmill to produce the desired chip thickness. Note: this is to calculate max chip thickness, not average chip thickness.

Titanium really sends a shock into the cutter every time the edge enters the material. To improve surface finish and make your cutters last significantly longer, these specialized endmills for titanium have a high helix angle on the cutting edges.

If you have a part with deep pockets that are at all kinds of tight angles, it’s really easy to bury a cutter in the corners. In this application, a 6 flute endmill might work best.

Even still, plunge milling for roughing paired with peel milling for semifinishing and finishing is an extremely effective way of handling titanium.

Dies to be used for machine screw having straight flutes at point with incomplete threads allowing for heavy paint drizzled into the tapped holes be removed. Unthreaded Screw blanks are tapered at the point.Dies produce straight flutes during thread rolling.Meets the locking standards thereby extreme resistance to vibrational loosening brings them categorically as self-locking asteners under conditions of severe vibration or high clamp load.

In other words, if a pocket has a wall thickness of 0.090″, you’ll have a hard time using standard toolpaths if the height is over 0.720″.

Machine screw dies having bolt maker taper, having threads on one side of the die only. It can be single or two way setting. Recommended for Lap free rolling and After Heat Treatment Rolling(AHT).Boltmaker style thread rolling dies can be used in other thread rollers i.e. Waterbury Farrel, with the use of suitable backing blocks.

For something that will handle really hard milling, look for something that advertises rigidity against low-frequency vibration. This is because the cutting is done at a relatively low RPM, which translates into lower frequencies.

At Kadimi we adapt to the customer's needs, manufacturing single face, split-face style, or duplex thread rolling dies to obtain higher performance from the tool.

I've been working in manufacturing and repair for the past 14 years. My specialty is machining. I've managed a machine shop with multiaxis CNC machines for aerospace and medical prototyping and contract manufacturing. I also have done a lot of welding/fabrication, along with special processes. Now I run a consulting company to help others solve manufacturing problems.

Since titanium is such a hard material that sends shocks into the cutter, there’s a major risk of vibration when cutting. When these impacts matches the resonant frequency of the part and workholding, this can compound the vibration into something unmanageable.

Dies can be supplied on a special basis for other machines and face depths, as well as from other special materials. In addition ,other thread forms, left hand threads and multiple leads can be supplied; either as Duplex, single or split face dies.

Through-tool coolant is a really good idea. High-end cutters will have a well thought-out delivery system that puts the coolant right where it needs to be, with enough pressure and volume to blast chips even out of deep pockets.

The downside to this approach is that there will usually be a fair amount of semifinishing; plunge milling leaves a very scalloped , rough surface that needs to be cleaned up later.

Some materials just have an automatic go-to for number of teeth on an endmill. Three for aluminum, four for steel… Not so with titanium.

To illustrate this, I tested two different endmills under the exact same conditions. Same material, same holder, same speeds and feeds, same coolant, same program. The difference in performance were absolutely massive.

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Dies are treated with special proprietary surface treatment which provides even higher performance when rolling difficult to form materials.

Titanium puts a lot of heat into the tool. Way more than other materials, like hard tool steels or steel alloys. The coolant needs to be directed straight into the cut area with high volume and high pressure to get rid of this heat.

Both materials are challenging to tap. Be careful not to work harden when drilling, use specialized taps, and follow the tool manufacturer’s instructions closely.

I like to think of it like surfing. If you stay ahead of that wave (hot zone), you’ll be fine. Let the wave catch up to you, you’re done. Fast, cool cuts are usually the way to go.

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These are special Flat ground thread rolling dies for machine screw for providing chamfer; these are straight faced die(Single or Duplex) with Insert for different angles for chamfer as per customer requirement. Dies are designed to add a chamfer to the end of a straight blank and to roll threads into the chamfer.

What this means is that the teeth spiral noticeably, instead of being closer to straight. Usually for steel the teeth will be as a slight helix, but for titanium the angle of the teeth is often between 30-60 degrees from the tool axis.

This is by far my first choice for roughing. You’ll be hard pressed to find a technique that will get a higher material removal rate.

Since titanium cutting is so prone to vibration, rigid machines really shine. If you need to remove a lot of material efficiently, don’t expect to do it on a cheap machine.

Flat thread rolling dies with sharp corners on the run out threads generates stress concentration areas which result in fatigue cracks in the thread rolled screw. With the Radius Run Out (RRO) offered by KADIMI, the smooth radius in the root of the thread continues right up to the point where the thread blends in the shank of the screw. This Radius Run Out was designed for rolling high strength aerospace bolts, however, it is available on all KADIMI dies.

A useful way to treat geometry that exceeds this is to leave a lot of stock for finishing. Leave enough stock to match this 8 to 1 rule, and then use a low axial depth of cut but a high radial depth of cut for finishing.

Tool wear with titanium isn’t linear. When it fails, it fails fast. It’s better to be swapping your tools out quickly so you can send them out for regrinding instead of crying over carbide pieces and scrapped work.

Depending on the operations you want to do, your existing machines might not be up for it. You may not be able to push the tools as hard as what they’re able to take. Take this into account when quoting titanium jobs – you need to know what your machines can handle.

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This works great for deep pockets and slots. With shallow geometry, you really start to lose the advantage of this technique.

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As always, this is just a matter of balancing parameters to find the “sweet spot”. A low helix leaves a poor surface finish and leaves the cutter more prone to chipping; a high helix endures more wear and therefore can dull faster.

Kadimi LF dies are developed to help roll the best quality fasteners without modifying any of the processes (e.g. blank preparation and machine operation). In controlling manufacturing variables to yield lap-free thread fasteners, LF technology

I've been involved in metalworking in its various forms for the past 14 years. On this website, I share some of the really cool things that I've learned while working in all kinds of different shops.

So when you’re looking at a lineup of possible cutter options and comparing prices, just take a look at the tolerance of the tools too. It can make a big difference on your process.

This is pretty well guaranteed to make your cutter rub and it’ll make a hot zone, while will cause work hardening. Once you’re in the cut, let it run.

There are a few different styles and sizes of secondary relief, so usually finding the sweet spot for your application is just a matter of a bit of testing.

A variable helix accomplishes basically the same thing as what the variable pitch cutter is aiming for. The uneven helices prevent that rhythmic hitting into the workpiece.

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If you’d like to know more about how you can get the most out of peel milling, I’d really recommend that you read this article about peel and trochoidal milling  .

Titanium really resists cutting, so your workholding needs to be dead solid. This is especially true for plunge milling. Here are a few pointers:

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The downside to this is that these cutters are usually large in diameter – often around 1.25″ or more. This means that they can’t get in to tight corners for geometry like small pockets.

Since there’s less heat generated, you can often crank up the RPM. As a rule of thumb, you can often double the RPM with 10% radial engagement compared to a full slotting speed, and increase it by 50% for a 25% radial engagement. This is a significant increase in material removal rates.

The good news for this is that modern machines are becoming more and more solid, even at an entry level. This is because modern tolerances are much tighter than they were even 15 years ago. This results in stronger, more accurate equipment.

Now I’m not saying that the tool will fall out of the holder (although that can happen too) but this can do two things to your process:

Another real advantage of peel milling is that the teeth are in the cut for much less time per revolution. This means that overall, much less heat is produced. It’s also distributed over more of the cutter, since there’s a higher axial depth of cut.

If the cutter shank isn’t particularly precise, it affects how well the holder can grip the tool. For example, if the tool is undersized or has concentricity issues, you could have either a weaker hold or an imbalanced chip load.

Since the cutting pressures are so high, the shock that the cutter experiences when engaging and disengaging from the material really does a number on it. Aside from extra wear on the cutting edges, this is where the tool is most likely to chip.

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A really good trick to prevent this is to use a varying depth of cut. For example, if you’re using a cutter that has a 1″ cutting depth, don’t do all of your cutting 1″ deep.

This process works particularly well on deep part geometry, like pocketing, or anything that a large diameter cutter can fit into.

This results in a smoother cutting action that more so shears the material away instead of whalloping it off. You can really hear the difference between a low helix and a high helix cutter.

Different designs of thread rolling dies available in Metric and Inch sizes for Machine screw in the field of Machine Building, Automotive and Industrial fastener applications.

Round inserts work well when the depth of cut doesn’t exceed 25% of the insert diameter. Beyond that ratio, the benefits of chip thinning are lost. You can use the same calculation for peel milling to determine how the feed rate can be increased.

If this article, I’ll go over what strategies have worked really well for me, how to select great cutters, and what other considerations need to be made.

Boltmaker single face dies have a threaded profile that provides a uniform rate of penetration over approximately two-thirds of the die length. The remaining dwell section accurately sizes the thread. These dies can be used for rolling ASME 1A,2A and 3A as well as ISO class 6g and 4h right hand, single lead threads.

An average number used is 1 HP required per cubic inch per minute of titanium stock removal. Obviously, sharp tools will take less and dull tools would be more. But this is a nice, easy rule of thumb that will get you in the ballpark.

If you’re having problems with chipping, though, there’s another coating you can try. Titanium carbo-nitride is stronger and more resistant to fracturing. This is more common to see on indexable inserts, and it can really increase the life of your tool.

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The minimum depth of the die face should be at least two pitches greater than the length of thread to be rolled. Select the nearest larger depth of the die face whenever possible.

A common application for titanium is aerospace parts, which typically have tall, thin walls to provide strength. With heavy cutting forces, these walls can deflect. This will result in walls that are thicker than permitted.

What this means is that wear can really concentrate on the tool where it contacts the part at the top of the cut. This is a common area to see chipping on the cutter, which can leave lines on the part and cause a hot area that results in work hardening.

High feed milling uses a really low axial depth of cut, usually about 0.030″-0.050″, but a full-diameter radial depth of cut. Using specialized inserts with large radii, we’re able to achieve significant chip thinning. This means that we can crank up the feed rate and remove material efficiently.

Titanium is a really tough material. It’s abrasive when you cut it, and it puts a lot of pressure on the cutting edges. There’s also a very thin but hard oxide layer that forms on the part surface.

Unless you have a variable pitch cutter. A variable pitch cutter has an unequal spacing between the teeth. What this does is break up the harmonics that you can otherwise get from the even, rhythmic slamming of the teeth into the workpiece.

For a 1/8″ endmill, the max speed at 600 SFM would double to  about 18,000 RPM. To be honest, though, it’s pretty rare that you’d ever run such a little endmill that fast. In real life, a 10k RPM machine will work great. Realistically, many of the high-torque titanium machines max at 6k RPM and they work just dandy.

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Machining 17-4 overall has a lot of similarities when compared to titanium. For example, fast, light cuts work well on both materials. 17-4 machinability is greatly affected by the heat treat condition it’s in. In an annealed condition, it can be gummy, inconsistent and challenging. When heat treated to an H900 and lower (lower numbers mean harder material) it becomes noticeably easier to cut.

First, the weak connection won’t dampen vibration. Second, the uneven chip load will cause some of your teeth to wear out prematurely.

For metals like steel, prepping an edge by slightly rounding it can make the cutting edge stronger. This is especially common to see with indexable inserts. Since steel is free-cutting, the tool doesn’t need to be razor sharp.

This isn’t the case with titanium. A slightly rounded edge will put a lot of heat into the cut, resulting in work hardening and an overall bad day. The cutting edge needs to be as sharp as possible to keep the cut cool.

That said, even smaller, more entry level machines can do a good job of small components. They usually can’t take very heavy cuts, but if the job only requires small tools, then you don’t need anything bigger.

Duplex dies have threads on both faces, offering twice the life of single face dies. Four settings may be used with duplex dies when the depth of the face is in excess of two thread lengths. These dies can be used for rolling ASME 1A,2A and 3A as well as ISO class 6g and 4h right hand, single lead threads.

For heavier cuts, try using tool configurations with a lead angle on the insert. For example, a 45-degree lead angle will produce a chip that is 30% thinner. That means that a traditional feed rate of 0.020″ per rev can be increase to 0.026″ if the tool has a 45-degree lead angle.

The reason for this is that you’re cutting in the direction where the tool is strongest. Side milling pushes on the tool in a cantilevered way, whereas plunge milling  directs the cutting forces straight up into a rigid spindle.

Using larger arc-ins and arc-outs are a great way of reducing the shock. Even if you’re doing a straight cut along the outside of a part, a generous arc will help your tool last longer.

Aside from making sure that you’re using a high-end concentrate and you follow the manufacturer’s mixing instructions to a T, coolant delivery is a major aspect of being successful.

What works way better is to maximize your axial depth of cut as much as the part geometry and flute length will allow, and use a small radial stepover. I find that 5-10% of the cutter diameter works really well. At more than 25% engagement, you really start to lose the advantages of this technique.

In general, you’ll commonly see titanium endmills with 6-10 teeth. The number of teeth that works best is really dependent on part geometry and chip evacuation.

If possible, do some cuts at 1″, some at 0.875″, some at 0.750″. This will spread that wear concentration along a greater area of the tool and increase tool life.

In essence, this reduces vibration. You’ll see this perform best in applications with low radial engagement, like with peel milling.

If your part is more so full of squarish pockets that are fairly open, then a 10-flute endmill might work great. It all boils down to what’s the largest amount of teeth you can pack onto an endmill without it getting clogged with chips.

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The most common coating you’ll find for titanium tools is titanium aluminum nitride, or TiAlN. This coating will create an aluminum oxide that protects the tool. This is my general go-to.

So instead of having a 6-flute endmill evenly spaced with teeth 60 degrees apart, you’ll have one spacing at 63 degrees, another at 57, one at 59, one at 61, etc.

The classic approach of a 0.5xD radial and axial stepover really doesn’t work for titanium. This just generates way too much heat, and it’s really likely to snap your endmill in half.

For machining titanium and other high-temp superalloys, proper coolant is absolutely critical. Some say that it’s one of the most important things to get right.

I’ve noticed a major difference in tool life when the right coolant is being used properly. Aside from making your process more productive, it also makes it safer. Titanium chips are very flammable, and if the coolant isn’t taken care of properly, you could have a very hard to put out fire in the machine. I’ve seen it happen in my shop several times.