Sandvik Coromant’s CoroDrill 860 -GM multimaterial drill promises precision and accuracy at higher productivity rates. Sandvik Coromant Canada

If you are cutting stainless steels or heat-resistant superalloys, synthetic and semi-synthetic coolants should be shelved to make use of an emulsion water-soluble oil with a 10 to 15 per cent coolant concentration.

These tools also typically have symmetrical cutting edges and can drill holes to much closer tolerances than an indexable drill.

“That's the good thing about drilling: Chipping and BUE are both remedied by increasing the cutting speed,” said Vetrecin.

According to McEachern, it’s important to have high-pressure coolant when cutting with solid-carbide drills, and smaller diameters typically need higher pressure than larger drills. For larger indexable and exchangeable-head drills, it is the volume of coolant flow that becomes important.

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“The flute is one of the most important features,” said McEachern. “You need a flute that enables good chip evacuation so there's no jamming. Often we even have multiple helix angles in the flute for evacuating chips at different sections of the hole.”

Iscar’s SUMOCHAM drills feature exchangeable heads, cylindrical shanks, and internal coolant holes. They can be fitted with four standard drilling head types for drilling on four different material groups while keeping the same steel body. Iscar Tools

“Often there are problems that are not spotted until it's too late because these machines are running at a high rate of speed, chips are flying, and doors are closed and coolant is flying,” said McEachern. “You can’t see much, but you can still listen. Sometimes even leaning on a machine or putting your hand on the door of the machine to feel for vibration helps diagnose a problem.”

And while drilling is a seemingly simple and common metal cutting process, its success or failure is based on many quality measurements, including concentricity, wall and floor surface finish, straightness, and hole size tolerance.

If chipping occurs, the chips will show a smeared, scratchy surface. You essentially can see one scrape for each corresponding chip on the cutting edge.

This group of materials tends to create wear on the cutting edges because of material adhesion. However, aluminum often contains silicon, which makes it abrasive in nature.

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When it comes to the exchangeable-head drills, you're not just indexing a single insert, you change out one big piece of carbide – at the drill’s head, which is a more expensive changeover.

“Most materials can use synthetic water-based coolants with success,” said Tonne. “I also have seen some cases where neat oil improved performance in nickel-based alloys because the shearing action was improved.”

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Other types of multipurpose drills, including Horn USA’s Supermini HP, can perform multiple machining functions, such as drilling, boring, face turning, and skimming. Horn USA

First, increase cutting speed while keeping the feed rate (feed per rev.) the same. If you change more than one parameter at a time, you won't know what solved the problem.

There are three things to examine when looking for wear, and according to Iscar’s Vetrecin, it’s best to do this at the testing or prove-out stage, before real parts are being produced.

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A look at the cutting edges, either with the naked eye or, even better, under a microscope, will tell you a lot about the operation. Wear is going to happen. But as long as it’s in the right area of the tool, and it is predictable, drilling operations can be successful.

“If indexable or exchangeable-head drills are suited to the hole size, I would not use solid-carbide multipurpose drills when I see applications in which the setup might be very weak,” said McEachern.

The importance of the individual quality data points also depends on the parameters of the hole being drilled. The type of hole (through, blind, chamfered, stepped, entry, exit, and cross), hole diameter (micro, small and medium, and large), and hole depth all matter.

When the grade is combined with tool design features such as the chisel point, cutting edges, flutes, helix angle, and coating, you get a tool that works well across numerous materials.

In busy job shops, machines typically are used for multiple materials, and changeovers happen regularly. Because downtime is a pure productivity sink, efforts should be made to reduce this non-productive time.

The type of wear that affects drills often depends on the material being processed. Some examples of the material/wear relationship are:

Coolant provides lubricity at the cutting edge and margin, helps break the chip, flushes chips out of the hole, and controls the cutting zone’s temperature to eliminate thermal shock.

For drilling on a lathe, McEachern’s first impulse is to use indexable or exchangeable-head drills for multipurpose drilling because they have a steel body that flexes a little bit. If you use a solid-carbide drill on a lathe, you need to have a solid setup with good alignment.

Stainless steels are quite heat-resistant and, therefore, produce wear on the cutting edge of the drill. Notching and built-up edge (BUE) commonly occur on the cutting edge.

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“I’m not concerned about the pressure anymore with the large-diameter drills. It's all about flow. It allows you to keep a cool temperature, and there is plenty of lubricity and flow to help evacuate chips out of the flutes,” said McEachern.

“With exchangeable-head drills and indexable insert drills, the coolant flow is really critical,” he said. “This is because it's more important to have good flow on larger-diameter drills than it is to have high pressure. So, 1,000-PSI output may be no good to you if you're not getting enough litres per minute.”

His general rule is to have 1 litre of coolant per minute per 25 mm of diameter of the drill. So if you have a 25-mm-dia. drill, you should have 25 litres per minute of coolant flow.

A look at the cutting edges, either with the naked eye or, even better, under a microscope, will tell you a lot about the operation. This works best during the testing phase as the cutting parameters are dialed in. Iscar Tools

“Smaller shops that are doing small-batch runs have a lot of variety in their shops,” explained Randy McEachern, product specialist, Sandvik Coromant Canada, Mississauga, Ont. “This lends itself well to using multipurpose drills.”

When Sandvik Coromant designs a multipurpose tool, it starts with a geometry that is productive and secure in different materials. Then it pairs with a grade that is safe and secure through all the material groups as well. Sandvik Coromant Canada

For example, in an operation that is drilling to a depth of 7xD, the chips come out of the first part of the hole easily and quickly. Then as the drill moves toward the bottom of the hole, a different shape in the chip flute helps ensure that the chips will still evacuate well. Also, the coolant flow needs to provide enough lift to get the chips up the flutes and out of the hole.

“It is important for machinists to be able to evaluate and understand the wear factors and understand how to react to them,” said McEachern.

“Less experienced machinists might interpret that as a chip in the cutting edge, when it's in fact just the coating being ripped off when the buildup pops off. This usually means that the tool is moving too slowly, which can be remedied by increasing the cutting speed,” said McEachern.

According to Edwin Tonne, training and technical specialist, Horn USA, Franklin, Tenn., many reasons exist for using a multipurpose drill. These include:

With so many variables come many drilling options, and solid-carbide, indexable, and exchangeable-head tools all have their place.

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“Switching tools for different materials has gotten a lot easier thanks to exchangeable-head systems,” said Dave Vetrecin, holemaking product manager for Iscar Tools, Oakville, Ont. “If you have one tool body and you're drilling stainless one day, you can use a head for that material, and then later, if you're cutting steel or cast iron, you can have a different head for that. These interchangeable heads are very versatile and also have the ability to hold quite accurate tolerances.”

“What we really want is even flank wear along both cutting edges, because if we are getting a nice, even wear pattern there, then we know that we're going to get some good life out of the tool. It means that we are very close to having the correct cutting data in terms of speed and feeds to allow this drill to produce many holes with good quality,” said McEachern.

Solid-carbide multipurpose drills typically have symmetrical cutting edges, so they create very accurate positional tolerancing. Even exchangeable-head drills can have a strong chisel point at the centre to give good centring capabilities. Indexable drills have multiple cutting corners and, therefore, create good edge economy and cost efficiency, but struggle with tight tolerances.

“It’s crucial to understand the setup to recommend a drill,” said McEachern. “When we're working in machining centres, the drill is rotating in the spindle through to a centre line. These machines are pretty well aligned with the spindle perpendicular to the workpiece. However, when you're on a lathe, the drill is stationary and mounted in a turret. They can get out of alignment over time from a lot of different factors.”

“You have to be dead-on perpendicular to the workpiece. If there's any angularity in the setup whatsoever, a solid-carbide drill can snap. That’s why I very seldom ever recommend a solid-carbide drill for a lathe setup,” he said.

“The chips when you first start will have a nice, smooth surface,” said Vetrecin. “If you develop a built-up edge, the surface of the chip will be rougher and have lines on it. You can see exactly where there's a piece of material stuck on the cutting edge because of a scratch on the chip.”

“Tool selection, especially in job shops, all starts with the material and batch size. If our customer has a large enough batch size, then I always recommend a dedicated geometry and grade for high productivity. However, if they only have five parts to make, and there's only one hole per part, I recommend a more economical drill and maybe a drill that serves multiple purposes,” said McEachern.

And measure your mixture right with a refractometer. It’s the best method to get an accurate idea of what’s going on with your cutting fluid.

“What Sandvik does is design a [multipurpose tool] with a geometry that is productive and secure in different materials. Then we design the grade that is safe and secure through all the material groups as well,” said McEachern.

Cast iron causes wear on the transition from the margins to the cutting edge because its silicon carbide (SiC) content makes it highly abrasive.

The most common wear that affects a drill’s cutting edges is BUE. When this wear occurs, material sticks to the cutting edge before eventually popping off and taking with it part of the tool’s edge and coating.

“I always give a lot of credit to the operators when it comes to diagnosing a problem because they know more about their specific process than we do,” said Vetrecin. “We know how to fix these problems easily once they are identified, but every process is different in terms of fixturing, clamping, rigidity, and coolant use and pressure. There are so many variables. A skilled operator can tell you exactly what does work and what doesn't.”

If you start seeing crater wear, which occurs on the rake face of an insert when using an indexable drill, for example, it is caused by excessive speed and too much heat.

Drilling often is a late-stage machining process, deployed only after many other operations have had their turn removing material from -- and adding value to -- the part.

This group of steels requires a strong chisel point to battle the higher pressure or axial thrust at its centre. These steels generate a lot of heat during cutting and are very abrasive to the cutting edge. Tools for hardened steel need to be strong and chemically stable at high heats. This heat also can lead to plastic deformation.

Iscar’s LOGIQ3CHAM assembled drills carry exchangeable carbide heads with three effective cutting edges. Three polished flute surfaces help ensure easy chip evacuation, and the variable flute angle design results can sustain high axial forces. Iscar Tools

Steels wear on the tool’s margins, but this wear typically is slow with dialed-in cutting conditions. The machining of steel is relatively easy, but it becomes more difficult depending on its hardness and the carbon content.

Second, inspect the cutting edge after each test cut as you increase the speed. You should see the BUE move toward the centre of the cutting edge until it becomes minute or even non-existent. That’s the time to stop increasing the speed.

An award-winning writer and graduate of the Sheridan College journalism program, he has published articles worldwide in a variety of industries, including manufacturing, pharmaceutical, medical, infrastructure, and entertainment.