Strategies vary for staying focused on increasing profitability and for remaining competitive in today’s global economy. Machining is an essential process for the strategy of mold builders.
This includes a focus on selecting and using the right cutting tools for each application. The first step to properly setting up each job that hits the shop floor is asking the right questions to assess requirements.
For example, how will you process the roughing and finishing on the part, what type of machine tool and cutting tools will you use for each process, what type of cutter geometry should you use when roughing and finishing, and what type of cutter material should you use, depending on its hardness and the age and capabilities of the machine tool?
These guidelines help answer questions and take some of the guesswork out of cutting tool selection and usage for cutting tool types and carbide grades for typical 3D mold applications.
Tool Type Selection
When selecting the appropriate tool for any roughing applications, consider these key factors.
On old, large, robust machines that are more than 10 years old, standard 90-degree, square shoulder cutting tools often achieve the best metal removal rate (MRR). These cutting tools can handle a heavy depth of cut (DOC) and do not require the high feed rates of some newer cutting tools. Tougher grades of carbide are required, as they provide good resistance to the shock and lack of rigidity that is common in older machines.
New, large, robust machines that are fewer than 10 years old typically achieve optimum MRR with high-feed or button milling tools that are designed to run at higher feed rates with lower DOC than 90-degree cutting tools. High-feed and button milling tools require a machine and control that can quickly process programming information, as well as axis motors capable of smoothly executing rapid changes in direction. A button cutter supports a heavier DOC range, while a high-feed system uses fast feed rates better. A large, powerful, rigid machine is better off with a high-feed cutting tool system, as it can handle heavier DOC than a smaller cutting tool solution. Tools with mid-hardness grades of carbide work well here, as the newer machine’s rigidity often provides more uniform tool pressure, which makes it possible to run a longer-lasting, harder grade of carbide for more extended periods of time before indexing is required.
Old, small, light-duty machines that are more than 10 years old lack rigidity and processing speed. For these machines, button cutters with small diameters of 2 inches or less are often the optimal choice. Button cutters are capable of higher feed rates, but they do not require higher feed rates to succeed. Choose a DOC that the machine handles well and as much feed rate as the machine and control can accept without losing accuracy or repeatability. Tough-grade carbide inserts may help overcome any lingering rigidity issues.
New, small, light-duty machines that are fewer than 10 years old are common in mold and die work. The most affordable are 40-taper machines, and while generally not well suited to heavy cuts, modern machines are capable of feed rates that go well into the range of hundreds of inches per minute. Therefore, high-feed cutting tools are the best choice most of the time, as they operate at a light DOC and feed rates of 200–300 ipm. This helps increase metal removal rates and lengthen tool life. A controlled, rigid cut on a newer machine should support a mid-hardness, high-performance grade of carbide and yield greater tool life (or number of minutes in the cut) before indexing.
When it comes to semi-finishing and finishing applications, tool requirements vary. Both semi-finishing and finishing work involve lighter cuts, faster movement, higher accuracy requirements and smaller-diameter cutting tools. The use of finishing cutting tools for semi-finishing operations is an unconventional cutting strategy. However, the tool life and accuracy that finishing cutting tools offer during semi-finishing operations extends the time in the cut and provides greater accuracy and consistency in the finish stock that remains, which enables final finishing tools to do their work more easily.
For finishing work, sharp-edged cutting tools provide better surface finish and more accurate sizing. Finishing-style indexable cutting tools (which are precision-ground and sharp) and solid-carbide end mills are both suitable for finishing work. Indexable-style roughing tools are designed with heavier edge preparations, which makes them less suitable for a finishing cut where material removal is inadequate for a reinforced cutting edge.
Accuracy is also an issue with typical roughing inserts that have a larger inscribed circle (IC) tolerance (which defines the insert size) in comparison to a precision-finishing insert. Roughing inserts are typically pressed-to-size with a tolerance of ± 0.002 inch on the IC while precision-ground finishing tools carry a tighter tolerance of ± 0.0005 inch.
Ball nose cutters provide high-quality surface finishes for most 3D surfacing work by minimizing the scalloping (or waviness) effect. When conditions exist that jeopardize cutting-edge integrity, like long reach, machine ways/spindle play, vibration or chatter, the design of a ball nose insert and cutter helps tolerate more abuse before chipping occurs. The round cutting edge of a ball nose insert provides inherent strength because there are no sharp corners. This is also why button cutters (or round insert cutters) function well as roughing tools, as they have no corners to chip or break.
Bull nose cutting tools can also be used for 3D surfacing work, but the cutter may “heel,” or hit on the opposite side of the primary cutting point, when it encounters sharp bottom radii.
Backdraft-style cutting tools provide fine finishes and decrease tool pressure for both straight and tapered wall work. Water-line (or Z-level) finishing with these tools is the most common approach. It minimizes the depth engagement per pass to create the most accurate surface.
Plunge finishing is another approach that uses backdraft-style cutting tools in which the tool executes the primary finishing travel on the Z-axis and then moves to the X- or Y-axis for each stepover. This path yields a smaller scallop height and allows for larger stepover. This strategy works best when the surfaces being finished do not require the cutting to intersect with the surface’s floor.
Carbide Grade Selection
Carbide is the most common material for cutting tools, as it provides a good combination of toughness and hardness. Following are some additional factors to consider when choosing the appropriate grade for your application.
Generally, carbide does not respond well to the shock that results from roughing. The safest approach is to start with a grade that is tough and soft. Most major cutting tool manufacturers refer to the grade description by including a large number like 35 or 40 in the designation for their roughing inserts as opposed to a low number like 10 or 15 in the grade description for finishing work.
When using a tough grade, be aware of failure mechanisms, or reasons that the cutting tool must be indexed or changed. For example, be aware of flank wear (or the appearance of rubbing marks along the clearance angle of the cutting edge). This wear is consistent and preferable to chipping or fracturing, which can result in tool breakage, a scrapped part or even spindle damage.
If starting with a tough grade yields unacceptable tool life, try the next-hardest grade available. Today, a tougher carbide grade with a high-temperature coating provides acceptable MRR and tool life performance with more reliable wear predictability.
In most finishing cases, the harder the cutting tool material, or carbide grade, the better. Harder carbide grades (ISO K10-15) tend to hold their edge longer, which reduces the need for zero cuts because of the deflection from a worn cutting edge.
The trade-off from using a hard carbide grade is reduced shock resistance. While a hard grade does maintain edge shape longer, it is more prone to chipping or fracturing in a high-shock environment (where, for example, there are interruptions, vibration and chatter). Keeping cuts light with harder grades helps to maximize tool life.
Another benefit of harder finishing grades is heat resistance, which allows for faster speeds or machining of harder materials. Use hard grades combined with a high-temperature coating for finish machining of heat-treated steels, or steels with a Rockwell hardness of greater than 48. Many cutting tool manufacturers’ grade descriptions include temperature and heat resistance capabilities. Choosing the high-temperature end of the spectrum is required for many finishing applications, as it enables the cutting edge to maintain integrity longer before breakdown occurs.
Successful milling involves more than just the creation of good toolpath. It involves good decision-making in the tool selection process before programming begins. Correctly matching the cutting tool to the machine tool and using the right tool geometry for the application can provide optimal speed, accuracy and profitability.
Selecting the optimal cutting tool for a machining job is a critical decision in any manufacturing operation. The right tool can boost productivity, improve quality, and reduce costs – while the wrong choice may lead to poor finishes, excessive tool wear, or costly downtime. This guide breaks down key factors you should consider when choosing cutting tools, using technical insights that are practical and easy to understand for employees across different manufacturing sectors.
1. Understand Your Workpiece Material
The material you are machining heavily influences the tool you should use. Different materials behave differently under machining conditions, so matching the tool to the workpiece is essential.
Hard or heat-resistant materials (like hardened steels, Inconel): Require very hard, heat-resistant tools such as carbide, ceramic, or CBN. These tools maintain sharpness under high temperatures and loads.
Soft or ductile materials (like aluminum or copper): Need sharp-edged tools with high rake angles to prevent material from sticking. Tools with fewer flutes and polished surfaces improve chip evacuation and reduce built-up edge.
Abrasive materials (like cast iron or composites): Demand wear-resistant tools. Carbide with hard coatings, or polycrystalline diamond (PCD) tools, are ideal.
Tough or work-hardening materials (like stainless steel, titanium): Require strong, rigid tools with heat-resistant coatings. Carbide tools with AlTiN coatings are often used.
Choosing a tool based on the material’s hardness, abrasiveness, and heat sensitivity ensures longer tool life and better machining results.
2. Optimize Tool Geometry
Tool geometry affects chip formation, cutting forces, and surface finish. Two critical aspects are:
Helix Angle
High helix angle (45° or more): Produces smoother cuts and better chip evacuation. Ideal for soft, gummy materials like aluminum.
Low helix angle (30° or less): Provides stronger cutting edges for hard materials and roughing operations but with less efficient chip evacuation.
Flute Count
Fewer flutes (2–3): Better for softer materials due to improved chip clearance.
More flutes (4–6+): Ideal for harder materials and finishing operations where surface quality is critical.
Matching helix angle and flute count to the application helps reduce tool wear and improve finish quality.
3. Select the Right Tool Material
Cutting tools are made from different materials depending on their intended use:
High-speed steel (HSS): Tough and affordable, good for general use and lower-speed applications.
Carbide: The industry standard for high-performance machining. Offers excellent heat resistance and rigidity, enabling faster cutting speeds.
Ceramics and CBN: Used in high-speed and hard-turning applications. Excellent heat resistance but more brittle.
PCD (polycrystalline diamond): Best for non-ferrous, abrasive materials. Extremely wear-resistant but not suitable for steels.
Always select a tool material that’s harder than your workpiece and appropriate for your cutting conditions.
4. Choose the Proper Coating
Tool coatings significantly improve performance by reducing friction, increasing heat resistance, and extending tool life.
TiN (Titanium Nitride): General-purpose coating that improves wear resistance.
TiCN (Titanium Carbo-Nitride): Harder and slicker than TiN; good for aluminum and stainless steel.
AlTiN / TiAlN: Excellent for high-temperature applications like machining hardened steel or titanium.
ZrN / DLC: Great for aluminum and non-ferrous materials; prevents built-up edge.
Diamond coatings: Ideal for composites and abrasives, but avoid using them on ferrous materials.
Choosing the right coating helps prevent premature tool wear, improves chip flow, and increases cutting speed potential.
5. Balance Cost with Performance
Don’t choose tools based only on their price. Consider the total cost of ownership, including:
Tool life: A more expensive tool that lasts longer and performs better can lower cost per part.
Cycle time: A premium tool can cut faster, reducing overall machining time.
Part quality: Higher-quality tools produce better finishes and more consistent results, reducing scrap and rework.
Look at the big picture – the right tool can improve your bottom line more than a cheaper alternative.
6. Monitor Key Performance Indicators (KPIs)
Once a tool is in use, track these KPIs to assess its effectiveness:
Surface finish: Indicates cut quality and tool sharpness.
Tool life: Helps determine when to replace tools and assess cost-effectiveness.
Cycle time: Shorter cycle times boost productivity and reduce per-part cost.
Use this data to refine your tool selection process and continuously improve machining efficiency.
As long as you are familiar with the mold manufacturing process, you can choose the cutting tool correctly.
There are many kinds of cutting tools, and mould processing engineers should be familiar with mould processing technology.