Answering the most common questions about 5-axis milling.
“Every block of stone has a statue inside it and it is the task of the sculptor to discover it.”—Michelangelo (1475-1564)
Imagine what Michelangelo could have done with a 5-axis milling machine.
It might sound odd, but if the Renaissance artist could have traded his hammer and chisel for a computer numerical control (CNC) and the right machine tools, we could have had thousands of statues of David carved from a host of different materials.
If you’re still in doubt about describing 5-axis machining as an art, click here or here.
Whether you’re sculpting a masterpiece from marble or milling a blisk from titanium, the basic principle is the same: start with a block of material and remove the unnecessary bits until the target object is all that’s left. Of course, the details of that process are much more complicated, especially for 5-axis machining.
What is 5-axis CNC Machining?
In the simplest terms, 5-axis machining involves using a CNC to move a part or cutting tool along five different axes simultaneously. This enables the machining of very complex parts, which is why 5-axis is especially popular for aerospace applications.
However, several factors have contributed to the wider adoption of 5-axis machining. These include:
- A push toward single-setup machining (sometimes referred to as “Done-in-One”) to reduce lead time and increase efficiency
- The ability to avoid collision with the tool holder by tilting the cutting tool or the table, which also allows better access to part geometry
- Improved tool life and cycle time as a result of tilting the tool/table to maintain optimum cutting position and constant chip load
What are the Axes in 5-Axis?
We all know the story about Newton and the apple, but there’s a similarly apocryphal story about the mathematician and philosopher, Rene Descartes.
Rene Descartes. (1569-1650)
Descartes was lying in bed (as mathematicians and philosophers are wont to do) when he noticed a fly buzzing around his room. He realized that he could describe the fly’s position in the room’s three-dimensional space using just three numbers, represented by the variables X, Y and Z.
This is the Cartesian Coordinate system, and it’s still in use more than three centuries after Descartes’ death. So X, Y and Z cover three of the five axes in 5-axis machining.
What about the other two?
Imagine zooming in on Descartes’ fly in mid-flight. Instead of only describing its position as a point in three-dimensional space, we can describe its orientation. As it turns, picture the fly rolling in the same way a plane banks. Its roll is described by the fourth axis, A: the rotational axis around X.
Continuing the plane simile, the fly’s pitch is described by the by the fifth axis, B: the rotational axis around Y.
Astute readers will no doubt infer the existence of a sixth axis, C, which rotates about the Z-axis. This is the fly’s yaw in our example.
If you’re having difficulty visualizing the six axes described above, here’s a diagram:
The A, B and C axes are ordered alphabetically to correspond with the X, Y and Z axes. Although there are 6-axis CNC machines, such as Zimmermann’s FZ 100 Portal milling machine, 5-axis configurations are more common, since adding a sixth axis typically offers few additional benefits.
One last note about axis-labeling conventions: in a vertical machining center, the X- and Y-axes reside in the horizontal plane while the Z-axis resides in the vertical plane. In a horizontal machining center, the Z-axis and Y-axis are reversed. See the diagram below:
(Image courtesy of Cameron Anderson/Aerotech.)
5-Axis Configurations
A 5-axis machine’s specific configuration determines which two of the three rotational axes it utilizes.
For example, a trunnion-style machine operates with an A-axis (rotating about the X-axis) and a C-axis (rotating about the Z-axis), whereas a swivel-rotate-style machine operates with a B-axis (rotating about the Y-axis) and a C-axis (rotating about the Z-axis).
The rotary axes in trunnion-style machines are expressed via the movement of the table, whereas swivel-rotate-style machines express their rotary axes by swiveling the spindle. Both styles have their own unique advantages. For instance, trunnion-style machines offer larger work volumes, since there’s no need to compensate for the space taken up by the swiveling spindle. On the other hand, swivel-rotate-style machines can support heavier parts, since the table is always horizontal.
For more information on the benefits of trunnion-style and swivel-rotate-style machines, check out this pair of videos from Hurco North America:
Benefits of a Trunnion Table on a 5-Axis Machining Center
Benefits of a Swivel Head on a 5-Axis Machining Center
How Many Axes Do You Need?
You may have seen references to machining centers offering seven, nine or even eleven axes. Although that many additional axes may seem difficult to envision, the explanation for such staggering geometries is actually quite simple.
“When you’re dealing with machines that have, say, more than one turning spindle, then you already have more axes,” explained Mike Finn, industrial applications engineering manager at Mazak America.
“For example, we have machines with second spindles and lower turrets. On those machines, you’ll have several axes: the top turret is going to have 4 axes and the lower turret has 2, then you have opposing spindles that have 2 axes as well. Those machines can have up to 9,” Finn continued.
“The parts you’re making are still 5-axis parts,” added Wade Anderson, product specialist sales manager at Okuma America.
“A component, like an aerospace valve might be done on our MU-5000 vertical center, which is a 5-axis machine. Or we could do that part on a multi-axis machine that has a rotary B-axis and twin spindles for two C-axes, plus X, Y and Z. There’s also a lower turret that gives you a second X and Z. So it gives you more axes, but the part itself is the same geometry,” Anderson explained.
So how many axes do you need?
As is often the case in manufacturing, the answer to that question hinges on your particular application. Finn gave the following example:
“A turbine blade is a freeform surface and can be rather complex. The most efficient way to finish machine a blade like that is to use 5-axis, taking the tool in a spiral around the airfoil of the blade. You can use a 3-axis to machine if you index the blade to a position and then use three linear axes to surface machine it, but that’s typically not the most efficient way.”
Anderson agrees: “The geometry of the part will tell you if you need a 3, 4 or 5-axis configuration.”
However, it’s important to remember that the number of axes you need depends on more than just one part. “The part will dictate a lot of it, but then there’s also what the shop wants to accomplish,” said Anderson.
“A customer might bring me a part, say a titanium aerospace bracket, and I might say, ’That’s a perfect part for a 5-axis machining center,’ but they might be planning on making parts that would work better on one of our MULTUS U machines. That multi-function machine might not be optimized the same way a 5-axis machining center is, but it may give the customer opportunities for doing lathe, shaft or chucker work that’s part of their long-term plan.”
“Another thing to consider is the work envelope,” Finn added. “What’s the maximum size part that you can put in the machine and still perform tool changes and part transfers? It’s understanding the machine’s capabilities and what it can and can’t do.”
Why use 5-Axis Machining?
Trying to decide between 3-axis machining and 5-axis machining is a bit like trying to decide between having a MacDonald’s Quarter Pounder or a T-bone steak; if cost is your only concern, then the former is obviously the way to go.
However, the dilemma becomes much more complicated when comparing 5-axis and 3+2-axis.
5-Axis vs 3+2 Axis
It’s important to distinguish between 5-axis machining and 3+2-axis machining. The former—also called continuous or simultaneous 5-axis machining—involves continuous adjustments of the cutting tool along all five axes to keep the tip optimally perpendicular to the part.
In contrast, the latter—also called 5-sided or positional 5-axis machining—involves executing a 3-axis program with the cutting tool locked at an angle determined by the two rotational axes. Machining that involves reorienting the toolbit along the rotational axes between cuts is called ‘5-axis indexed’ though it still counts as 3 + 2.
The main advantage of continuous 5-axis machining over 5-axis indexed is speed, since the latter necessitates stopping and starting between each reorientation of the tool whereas the former does not.
However, it should be possible to produce the same results whether using continuous or indexed 5-axis. (Readers who disagree are encouraged to share examples of parts that can only be machined with continuous 5-axis in the comments section below.)
It’s also worth noting that with the speed advantage comes more moving parts, which leads to increased wear and tear as well as a greater need for part crash detection. This is one of the reasons continuous 5-axis machining is more difficult from a programming standpoint.
5-Axis Machining vs 3D Printing
3D printing—or additive manufacturing—is a hot topic in the manufacturing world right now, especially as it compares to subtractive manufacturing processes like 5-axis machining.
Although it is sometimes suggested that these two methods are in competition—with die-hard 3D printing fans arguing that the technology will soon disrupt the entire manufacturing industry—the more moderate view takes additive and subtractive manufacturing to be complementary processes.
“I don’t think additive manufacturing is going to completely take over, but I do think there are opportunities to design parts that couldn’t have been designed in the past,” said Finn. “But there are still parts that require subtractive machining. For example, parts that have a really tight circularity tolerance.”
“It’s possible to grow a feature to a near-net shape, but that feature may still need to be machined to achieve the proper tolerance,” Finn added.
Does that mean the future of manufacturing will be a hybrid 3D printer/5-axis CNC—maybe with a coordinate measuring machine thrown in for good measure?
Anderson isn’t so sure: “The real world application [of 3D printing] outside a laboratory environment is not having a combined style machine, but [for example] having a laser deposition machine do what it does best, having a turning or milling machine do what it does best and combining the two through automation.”
The reasoning behind having two separate machines comes down to powder and chip management.
“The amount of powder you flow in laser deposition to make a 30-pound part, for example, could be 150-300 lbs of titanium,” said Anderson. “If that goes into a machine where everything is combined, there’s not a good way to reclaim all that powder.”
In other words, questions regarding the relationship between 3D printing and 5-axis machining are less often about competition than cooperation. “I think additive manufacturing may reduce the amount of roughing that needs to take place,” Finn concluded.
How to Get the Most from 5-Axis Machining
It’s not uncommon to see 5-axis capabilities being under-utilized.
“Some may have the machine but not understand it’s full capability, or they may not have the software that’s needed to create a cutting program that would utilize the machine’s full capabilities,” Finn observed.
Anderson agrees: “That’s a heart-breaker for companies like ours; when we see a company that goes all in, gets a piece of equipment, they put it on the floor, and then for various reasons they take a multi-function machine that has 5 or more axes and they use it like a 3-axis machine. It happens all the time.”
“A lot of that is personnel,” Anderson added. “It’s training and understanding how to utilize the machine. Sometimes it’s difficult for them to think about processing this part with an upper turn, a lower turn, a main spindle and a sub-spindle, all in the process at one time. It’s overwhelming.”
“There are a lot of software companies that are getting a lot better at being able to do that type of thinking for you, but it is tough,” Anderson concluded.
The Importance of 5-Axis Controls and Software
Although having a machinist with the right skill set is a major contributor to maximizing a 5-axis machine’s capabilities, the machine’s control and software are just as important.
“When you’re doing high-speed 5-axis machining, the servo drives on the machine and the response time is very important to avoid shortcutting or overshooting when machining,” said Finn. “The controller in the machine has to be able to process the data fast enough so the toolpath is a nice, smooth, uniform motion. You don’t want jerky motions that could cause gouging.”
“Likewise, the software that creates the 5-axis programs has to be able to create nice smooth code so the machine can move in that smooth motion,” Finn concluded.
Choosing the right CAD/CAM package is essential to getting the most from your machine.
“If you’re doing aerospace blisks, for example, you need to be working on the high-end packages,” said Anderson. “If you’re just making small aluminum widgets for a die cast component for an automotive company and all you’re doing is drilling a couple of holes on an engine case, that’s a completely different story.”
“If you are cutting parts that require a CAM system to generate cutting programs, you should invest in a CAM system that complements the machine’s abilities,” Finn added.
Avoiding Collisions in 5-Axis
When it comes to creating 5-axis toolpaths, there is generally a trade-off between running at higher speeds and feeds and minimizing the risk of crashing. Fortunately, there are a number of software tools on the market today that can help eliminate that.
“With our collision-avoidance software, you can load a 3D model of the part and the tools, and the program looks ahead of every move the tool makes to see if it’s going to run into anything,” said Anderson. “Provided your fixture is modelled correctly, it will catch the collision before it happens.”
“There is software out there that will do machine simulation,” Finn commented. “So that is important, especially on your high-dollar parts. You don’t want to have any type of collision that would cause you to scrap a part, cause someone to get injured or damage the machine.”
“Vericut offers 3D virtual monitoring software that will do the same thing, only on an offline computer,” added Anderson. “So instead of running in real time on the controls, you run your part program through Vericut and it will check all your toolpaths and verify that it’s going to do what you think it’s going to do.”
5-Axis Tool Sensing
High productivity is a benefit of 5-axis machining, but it also increases the risk of errors, such as using a broken tool or the wrong tool. One way to minimize these errors is to opt for a tool-detection system, such as this BLUM laser on the DMG MORI DMU 50:
A DMU 50 featuring a BLUM laser detection system.
5-Axis: Done in One?
The notion of ‘Done in One’ is a lofty goal in manufacturing: you load a block of material into a machine, run the program and remove a completely finished part. Like having zero setup time, the done-in-one goal is worthwhile, even if it’s ultimately unattainable.
That being said, 5-axis machining gets us closer to the done-in-one goal than any other process; even 3D-printed parts require finishing. In this context, a major constraint on 5-axis machining is workholding.
“So much of 5-axis work revolves around the workholding,” said Anderson. “I can have the best machine in the world, but if my workholding is lousy, I’m never going to have the part that I want at the end of the day.”
According to Finn, the key to getting around this bottleneck lies in utilizing machines with more than five axes:
“For example, our INTEGREX machine can be equipped with opposing turning spindles and a lower cutting turret. So parts can be cut on one spindle and then transferred to the opposing spindle to machine the remainder of the part. So in essence you can load in a piece of raw stock and then unload a finished part.”
The Art of 5-Axis Milling
5-axis machining offers significant benefits, including reduced lead time, increased efficiency and improved tool life. However, it’s important to recognize that attaining these benefits requires more than just purchasing the latest 5-axis machining center.
Mastering the art of 5-axis necessitates taking a host of factors into account. On that topic, Anderson said this:
“When you look at problems that customers have, very seldom is it machining a part. Typically, the problem that’s holding them back is centered around something other than making a chip. It’s training, it’s having personnel, having communication go correctly from the routing to the machine or knowing before they get started that they’re going to have enough tools in the magazine to finish the part when they start on it. The peripheral parts of the business hold them back more than actually making the part.”
This article has only scratched (or chipped) the surface of 5-axis machining. Keep an eye on Manufacturing 101 for an in-depth look at other aspects of 5-axis, including:
- Tool Selection
- Cooling
- Toolholding
- Pallet Loading
- In-Machine Measurement
For more information on 5-axis, visit the websites for DMG MORI, Hurco, Mazak and Okuma.
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