What is Spindle Speed in Machining?

What is Spindle Speed?

Spindle speed, by definition, is the rotational speed of the CNC machine’s spindle. Its typical unit of measurement is Revolutions Per Minute (RPM).

Spindle speed dictates how fast the cutting tool or workpiece rotates, thereby having a direct impact on factors like machining efficiency, surface finish, and tool life.

Spindle Speed vs. Cutting Speed

Before we get into the details of spindle speed, let us briefly discuss the issue of cutting speed vs. spindle speed. These two machining concepts, although not too different from each other, have distinct roles in a CNC machine shop.

The spindle speed, as we know by now, is the number of rotations the spindle (or tool) turns per minute. It depends on factors like tool diameter, machine tool capabilities, and quality requirements. Machinists often select it from a reference spindle speed chart.

The cutting speed, on the other hand, is a slightly more technical topic. It is the speed at which the cutting edge moves over the workpiece material’s surface. Common units of measurement for cutting speed are meters per minute (m/min) or feet per minute (ft/min).

Cutting speed selection takes into account factors that impact the actual cutting action. These include the material properties, heat generation, coolant, and tool wear.

Why is Spindle Speed Important in Machining?

Spindle speed directly impacts a number of CNC machining quality metrics. This section discusses the relationship between the spindle speed and various performance factors.

Surface Finish

First and foremost, spindle speed plays a critical role in the surface finish of the workpiece. A spindle high speed leads to a finer surface finish as the cutting tool moves more smoothly and consistently across the material surface, reducing tool marks and scallops.

On the other hand, a low spindle speed produces uneven surfaces and possibly vibration. This is generally only acceptable for roughing cuts where the surface finish does not matter and large tool diameters are used.

These are the reasons that high spindle speeds are characteristic of finishing passes in a machining cycle.

Tool Life Optimization

The spindle speed determines how aggressive the cutting action is. Higher spindle speeds translate to high cutting speeds, which cause excessive friction and heat generation, which eventually leads to tool wear and premature tool failure.

Low spindle speeds are also bad for tool life. At very low spindle speeds, the tool rubs against the workpiece surface instead of cutting through it. This rubbing action (also known as ploughing) creates friction and dulls out the sharp cutting edge. This edge deterioration decreases cutting efficiency and can also lead to tool failure.

Therefore, it is important to select a spindle speed that optimizes tool life by minimizing tool wear.

Throughput

Throughput, or material removal rate, relates to how much material is cut per unit of time. Understandably, manufacturers want to maximize throughput as it means fewer cycle times and a higher return on investment.

Spindle speed directly impacts throughput, as higher spindle speeds mean quicker material removal rates. Spindle speed optimization is quite valuable in high-volume production environments, where cycle time improvements pile up to significant machine hours.

Thermal Management

Spindle speed is a major factor in the thermal management of CNC machines. Higher spindle speeds cause more friction and heat generation at the tool-workpiece interface. These high temperatures cause thermal expansions in the workpiece and tool, thermal softening, and deterioration of the cutting edge surface.

Clearly, this type of heat buildup in the cutting zone is damaging to the tool and part quality.

Therefore, spindle speed optimization is a core part of effective thermal management, along with cooling and lubrication strategies.

How to Calculate Spindle Speed?

When planning a typical machining operation, decisions like the cutting speed and tool selection precede the spindle speed computation. Consequently, a standard spindle speed calculator uses the following spindle speed formula to calculate spindle RPM:

Let us do a simple calculation to compute the spindle speed. Suppose the material to cut is mild steel, for which a speed of 30 m/min is appropriate. If the machinist chooses to use a tool diameter of 20 mm, the cutting speed would be:

Selecting the Right Spindle Speed

Spindle speed selection is dependent on a variety of factors, like workpiece and tool materials, and part quality requirements. This section discusses these in detail.

Material Properties

The response of different materials to cutting speed varies significantly with material properties. Hard-to-cut materials like titanium and steel with high hardness and toughness limit spindle speeds to low-to-medium values to prevent tool wear, overheating, and surface damage.

Machinable materials like aluminum, on the contrary, are compatible with higher cutting speeds.

The direct dependence of cutting speed on material properties is clear from a spindle speed chart, where the spindle speed recommendation is often given by material groups.

Cutting Tool Properties

The material and geometry of the cutting tool also influence spindle speed selection. Carbide cutting tools, capable of withstanding higher forces and friction, are a clear choice for high-speed machining operations. Other tool materials like high-speed steel (HSS) are suitable only for medium-speed processes.

The surface coating of the cutting tool also matters in this context. Coatings like TiN or TiAlN improve the friction properties of the cutting edge, allowing higher cutting speeds without overheating risks.

The geometry of the cutting tool is important to consider when setting the spindle speed. Small tool diameters require high cutting speeds to maintain adequate cutting speeds at the cutting edges (see formula above).

Similarly, the quality of tool calibration plays a role in determining spindle speeds. Tools with high runout, for instance, can break at high spindle speeds due to irregular cutting forces and interrupted cutting.

Machining Operation

A CNC machine performs various types of CNC operations. Since these operations differ in cutting mechanics and application, the optimal spindle speed range also varies between them.

Roughing operations, for instance, prioritize maximum material removal and thus do not use high speeds to avoid tool failures. Finishing requires high surface quality, so a high spindle speed is more suitable.

With regard to machining processes, basic operations like facing or pocketing are compatible with high spindle speeds due to their simple geometries. Failure-prone operations like reaming or plunging, however, use slower speeds to allow better control over the cutting process.

Advanced Spindle Speed Techniques

Spindle speed planning and optimization is a wide topic. Owing to the diverse range of CNC machining operations and capabilities, the selection of spindle speed becomes a complex topic.

Variable Spindle Speeds

CNC machinists are dealing with increasingly complex geometric forms, with a growing number and types of materials, using constantly evolving technologies.

These developments mean that during a machining process, the optimal spindle speed is never constant. It is a dynamic value that changes with cutting loads, non-uniform material properties, and tool engagement.

Modern CNC machine tools and CAD/CAM systems allow for the use of variable spindle speeds, where the spindle speed is dynamically adjustable according to the quality requirements based on real-time feedback.

High-Speed Machining

High-speed machining in modern-day CNC machines is pushing the definition of what is spindle speed. High-speed machining generally refers to machining with spindle speeds in the >15,000 RPM range, which is characterized by high efficiency, productivity, and part quality.

A special application of high-speed machining is in micromachining centers, where the cutting tools can be less than 1mm in diameter and the workpiece geometries are incredibly tiny. At the micro-scale, high cutting speed is a requirement to cut through the material instead of ploughing its surface.

Chatter Mitigation

Chatter is a serious problem in machining, which damages the part and tool to the extent of part rejection or tool breakage. While chatter mitigation is a topic on its own, a well-known method to avoid chatter is spindle speed tuning.

Chatter vibrations are avoidable by decreasing, or counterintuitively increasing in some cases, the spindle speed.