What is CNC Machining? 3 Axis | 4 Axis | 5 Axis - RGBSI Blog

Jun. 05, 2025

What is CNC Machining? 3 Axis | 4 Axis | 5 Axis - RGBSI Blog

CNC (computer numerical control) machining is a process in manufacturing where programmed computer software directs the motions of plant machinery and tools. The application can be used to automate a range of manufacturing techniques such as milling, water jet cutting, and laser cutting materials. Instructions are fed into the CNC machine through a CAD file and transposed into a precise set of sequential instructions. The CNC machine uses these programmed commands to operate automatically without a physical operator. Manufacturers accrue several benefits through the application of CNC machining such as expense reduction, improved speed, better accuracy, and enhanced productivity levels.

Read more

The reference to axes is used to describe CNC machines which operate along multiple axis points. CNC machining is the process of removing material from a workpiece until the desired shape is configured. These machines have at least a 3 axes and operate along an XYZ plane: X axis (vertical), Y axis (horizontal), and a Z axis (depth). The 4th axis denotes the inclusion of an A axis (rotation around the X axis), and the 5th axis denotes the B axis (rotation around the Y axis).

The number of axes on a CNC machine determines the type of work it can do, the level of detail it can cut, and the workpiece locations it can manipulate. So what does this all mean? The following provides a better explanation of the differences between a 3 axis, 4 axis, and 5 axis CNC machines.

3 Axis

3 axis machining implies that the workpiece remains in the same position while the cutting tool operates along the XYZ plane to trim away material. This is suitable for parts that don’t require a lot of depth and detailing. 3 axis machining is most commonly used to produce mechanical components and is best suited for:

Automatic/interactive operation
Milling slots
Drilling holes
Cutting sharp edges

4 Axis

4 axis machining implies that a workpiece is processed in the same way it would be with a 3 axis machine, but has an additional rotary movement around the X axis, which is named the A axis. This rotation allows the workpiece to be cut around the B axis. This method is beneficial when holes or cuts need to be made on the sides of a workpiece. The addition of a fourth axis (A axis) allows a workpiece to be automatically flipped over, so the machine can remove material from both sides. 4 axis machining is multifunctional and can be used for:

Intermittent cutting
Continuous cutting
Engraving curved surfaces

5 Axis

5 Axis machining implies that a workpiece can be automatically manipulated from five sides at one time. In addition to automatic movements along the X, Y, and Z axes, 5 axis CNC machines can select two of the three rotational axes (A,B,C) to use. The A, B, and C axes perform a 180° rotation around the X, Y, and Z axes, correspondingly. This type of machining is used in the automobile, aerospace, and boating industries. Application is commonly favored for extremely complex components that are solid and would otherwise have to be cast. 5 axis machining requires greater CNC programming preparation time to accommodate complex rotatory movement, but allows one workpiece to be worked on all five sides during one operation. 5 axis machining is beneficial when components require a great deal of intricacy and quick precision. This includes:

Feature accuracy
Increased productivity
Higher quality finishes
Cutting intricate details
Machining complex shapes

Takeaway

CNC machining has proven to be operationally beneficial across manufacturing intensive industries. Some advantages include improving product quality control, standardization, and precision. The adoption of CNC machining leverages CAD technology to automate the cutting and shaping of components. The numbers of axes determine what type of movement a CNC machine can conduct.

Axes Movements

X axis – left to right
Y axis – front to back
Z axis – up and down
A axis – 180° rotation around the X axis
B axis – 180° rotation around the Y axis
C axis - 180° rotation around the Z axis

Types of CNC Machines

3 Axis – X, Y, and Z axes
4 Axis – X, Y, Z, and A axes
5 Axis – X, Y, and Z axes and two out A, B, and C axes

About RGBSI

At RGBSI, we deliver business solutions that close the gap between strategy and execution for global organizations of all sizes. Our portfolio of solutions spans across the verticals of workforce management, engineering, quality lifecycle management (QLM), and information technology (IT).

With a strong engineering and IT backing, we work with global clients to deliver CNC programming & validation services in accordance with their business requirements.

What's the difference between 3-axis, 4-axis & 5-axis milling?

At CloudNC, we have a range of state of the art 3-axis, 4-axis and 5-axis milling machines. As a designer, having an understanding of which type of machine your part will be manufactured on is critical in optimising your design. When designing a CNC machined part, you might not have thought about which type of machine your part will be machined on, but the complexity and type of geometry you can design will be different for different types of machines.

The main difference between 3-axis, 4-axis and 5-axis machining is the complexity of the movement both the workpiece and the cutting tool can move through, relative to each other. The more complex the motion of the two parts, the more complex the geometry of the final machined part can be.

3-AXIS MACHINING

The most simple type of machining, where the workpiece is fixed in a single position. Movement of the spindle is available in the X, Y and Z linear directions.

3-axis machining

3-axis machines are typically used for machining of 2D and 2.5D geometry. Machining of all 6 sides of a part is possible in 3-axis machining but a new fixturing set-up is required for each side, which could be expensive (more on that below). For a single fixture setup, only one side of the part can be machined.

A unique setup is required for each side of a part

Many complex and practical shapes can be manufactured by 3-axis CNC milling, especially when in the hands of a world-class CNC machining facility. 3-axis machining is best suited to manufacture of planar milled profiles, drillings and threaded holes in-line with an axis. Undercut features are possible with the use of T-slot cutters and Dovetail milling cutters.

However, sometimes the designed feature physically cannot be manufactured by a 3-axis machine, or the feature might be more economically viable to machine with a 4 or 5-axis machine.

Features not possible in 3-axis milling include any features on an angle to the X-Y-Z co-ordinate system, even if the feature itself is planar. There are two types of angled features you can design, and understanding the distinction between them is important when designing parts for CNC milling.

ANGLED FEATURE

This is a feature machined on an angle to one of the X, Y or Z axes. For example, the planar milled surface below is at 45° to the X-axis e.g. a rotation of the A-axis.

Milled feature angled in a single plane at 45°

Additional reading:
CNC Grinding Machine Buyers' Guide - HM

With competitive price and timely delivery, Ling Yueyang sincerely hope to be your supplier and partner.

COMPOUND ANGLE FEATURE

This is a feature machined on an angle to two axes. For example the planar milled surface below is machined at a 45° angle to the X-axis, and a 30° angle to the Z axis.

Both angled and compound angle features cannot be machined by 3-axis CNC machines.

4-AXIS MACHINING

This adds a rotation about the X-axis, called the A-axis. The spindle has 3 linear axes of movement (X-Y-Z), like in 3-axis machining, plus the A-axis occurs by rotation of the workpiece. There are a few different arrangements for 4 axis machines, but typically they are of the ‘vertical machining’ type, where the spindle rotates about the Z axis. The workpiece is mounted in the X-axis and can rotate with the fixture in the A-axis. For a single fixture setup, 4 sides of the part can be machined.

4-axis machining can be used as a more economically viable way of machining parts theoretically possible on a 3-axis machine. As an example, for a part we recently machined we found that using a 3-axis machine would have required two unique fixtures at a cost of £ and £800 respectively. By utilising the A-axis capability of 4-axis machining, only one fixture was required at a cost of £. This also eliminated the need for fixture change-overs, reducing costs even further. Eliminating the risk of human error meant we machined the part to a high quality with no need for expensive Quality Assurance investigations. Removing the need to change fixtures has the additional benefit that tighter tolerances can be held between features on different sides of the part. Loss of accuracy due to fixturing and re-setup has been removed.

Complex profiles such as cam lobes can be machined on a 4-axis machine

There are two types of 4-axis CNC machining: indexing and continuous.

Index 4-axis CNC machining is when the 4th axis (A-axis) rotates whilst the machine is not cutting material. Once the correct rotation is selected, a brake is applied and the machine resumes cutting.

In continuous 4-axis machining, the machine can cut material at the same time as the A-axis rotation, simultaneously. This allows complex arcs to be machined, such as the profile of cam lobes, and helixes.

4-axis machining gives us the ability to machine angled features, otherwise not possible with a 3-axis machine. Bear in mind that 4-axis machining allows a single axis of rotation per fixture setup, so all angled features must be angled about the same axes, or additional fixtures put in place.

Helical machining possible with 4-axis machines

5-AXIS MACHINING

These CNC milling machines utilise 2 of the 3 possible rotation axis, depending on the type of machine. A machine will either utilise a rotation in the A-axis and C-axis, or a rotation in the B-axis and C-axis. The rotation either occurs by the workpiece, or by the spindle.

There are two main types of 5-axis CNC machines: 3+2 machines, and fully continuous 5-axis machines.

In 3+2 axis machining two rotational axes operate independently to each other, meaning that the workpiece can be rotated to any compound angle in relation to the cutting tool for features to be machined. However, two axes rotation at the same time as machining is not possible. 3+2 machining can produce highly complex 3D shapes. Fully continuous 5-axis machining can simultaneously rotate the two rotation axis, at the same time as machining and the cutting tool moving linearly in XYZ co-ordinates.

‍

5-axis machining

Continuous 5-axis machining can produce highly complex 3D shapes, not only planar compound angled features but complex curved 3D surfaces, giving us the ability to produce parts normally reserved for moulding processes.

5-axis machining gives designers a huge level of flexibility to design very complex 3D geometry. Understanding the possibilities of each type of CNC machining is essential in design of CNC machined parts. If your design needs the use of a 5-axis CNC, make the most of it! Which other features could benefit from the capabilities of 5-axis machining?

At CloudNC, we’re working on software to make machining simpler – automating large parts of the journey and helping people with less experience use CNC machines like an expert can. If you’d like to know more, why not check out our technology to view our CAM Assist solution, watch a video about where we think our solutions can take us, ur mission and vision, or take a look at our careers page!

‍

Contact us to discuss your requirements of 3 Axis Vertical Machining Center. Our experienced sales team can help you identify the options that best suit your needs.

Comments

All Comments (0)

Previous: CNC Grinding Machine Buyers' Guide - HM
Next: 10 Essential Tips for Choosing the Best CV Joint Machine Export