CNC Insert Type and Selection

Mastering CNC insertion selection: a comprehensive guide to precise machining

In the high-risk world of CNC machining, success often depends on the component smaller than the thumbnail: the cut insert. As a cornerstone of the tool system, the CNC insert is a replaceable cutting edge mounted on the tool holder. Their performance directly affects machining efficiency, finishing accuracy, tool life and ultimately the cost-effectiveness of your project. In Greatlight (the leader in advanced five-axis CNC machining), we know that choosing the best insert is not a guessing game. This is a scientifically driven decision that is critical to solving the challenges of manufacturing complex metal parts.

Why insertion is important

The insert absorbs cutting forces, heat and friction during processing. Poor inserts can lead to premature wear, poor surface effect, vibration problems and scrap parts. Instead, the correct insert can cut cycle time, extend tool life, and unlock the full potential of complex devices. For the aerospace, medical equipment or automotive industries, accuracy is not commercially acceptable, and insertion selection becomes a competitive advantage.

Decode CNC insertion type

Insert by Material,,,,, geometryand coating– Impact performance in a specific application.

1. Insert material: the backbone of performance

• carbide: Undisputed industry leader, offering versatility. Tungsten carbide is mixed with cobalt binder to provide an ideal balance of hardness and toughness. Grades with ultrafine grain or microcrystalline structures can allow for higher speeds and feeding.
• Ceramic products: Highly wear-resistant at extreme temperatures (2,000°F+). High-speed finishing of steel, cast iron and super alloys, but fragile under heavy interruptions. Common types: based on alumina and silicon nitride.
• Cermet: Mix ceramic hardness with metal toughness (nickel adhesive titanium alloy/titanium nitride). Provides excellent finish on steel and casts irons when precision is most important. Resist the edges and oxidation of established edges.
• CBN (cube boron nitrate): The second is only hardness diamonds. Extremely thermally stable. Hardened steel (45 hours +) and hard irons first choice. High-speed applications are required.
• PCD (poly crystal diamond): Excellent, used in non-absorbing materials such as aluminum, graphite and composite materials (such as aluminum, graphite and composite materials). Provides unparalleled tool lifespan. Ferrous materials cannot tolerate due to carbon migration.

2. Geometry: Shaping the cutout

Geometric shape control chip control, strength, acquisition and cutting force:

• shape:

  • Round: The strongest bending angle (e.g., CTGA).
  • Square (90°): Robust and suitable for multiple operations (such as SNMG).
  • triangle: Three effective margins, economics (e.g., TNMA).
  • Diamond (55°-80°): Popular compromises in edge strength and tool access (e.g. DNMG).

• Relief angle:

  • Rake (+): Sharp cutting action; reduce cutting force. Ideal for elongated parts or weaker materials.
  • Negative Rake (-): Stronger tip edges for heavy rough or hard materials.

• Edge Preparation and Chip Circuit Breakers:

  • Edge preparation: Durability of T-Land edges; sharp edges of non-productive materials.
  • *Chip circuit breaker**: Designed as a curl/break chip. The selection depends on the material, cutting depth and feed rate.

3. Paint: Improve performance and life

Chemical vapor deposition (CVD) or physical vapor deposition (PVD) layers enhance alkaline materials:

• Tin (titanium nitrate): Basic gold coating, initial wear resistance of AIDS.
• TICN (Titanium Carbon Dititanium): Harder than tin; more suitable for abrasive materials.
• tialn (titanium aluminum): Excellent heat resistance (> 1,300°F), perfect for high-speed processing. The PVD version provides a clearer edge.
• Altin (aluminum titanium): High-quality thermal barrier than tialn; enhances the hard function of the machine.
• DLC (diamond carbon): Ultra-smooth, low friction coating is perfect for sticking aluminum or plastics.

Mastering Insertion Selection: A Practical Way

Selecting the correct insert requires an overall analysis of the variables:

1. Workpiece material:

   • Aluminum/non-produced: Positive geometry + sharp, polished PCD or coated carbide. Avoid easy appearance of paint.
   • Steel and alloy steel: Durable carbide (uncoated or Tialn/TICN). Graduation is based on alloys to perfect the choice. Crazy hard material (> 55 hours)? Select CBN.
   • Stainless steel: Hard WV carbide grade with thermal protection (\~Altin layer) and chip control. Avoid ceramics.
   • *Cast Iron**: Used for high-speed finished ceramics or CBN; carbide coated carbides, rough with strong edges.

2. Processing operations:

   • Turn/Rough: Negative riding insert (square or circular) with chip circuit breaker maximizes material removal.
   • *Complete/High Precision**: Positive number. Tolerant tolerant fine carbide/cermet tolerance.
   • Thread/separation/slot: Design-specific insertion profiles, with great attention to coolant delivery.

3. Machine and Setting Constraints:

   Rigidity is crucial. Lower size settings require positive/neutral inserts with higher rake angles to alleviate tremors. Ensure your CNC platform stability/fixation matches insert strength.

4. Optimize parameters:

   Inserts come with recommended speed/feed range. Target consistency: Stable reduction of 70-80% of the stable maximum SFM enhances life. Verify the depth cut of the depth cut before final selection.

5. Cost and performance trade-offs:

   Priority is given to tool life and cycle time exceeding the price tag. The $80 ceramic insert is better than 4+ carbide inserts and can pay for yourself quickly.

Conclusion: Accuracy designed by expertise

CNC inserts are precise scalpels made in modern times. Scientific selection of them (matching material grades, geometry and coatings to specific applications) can directly improve efficiency, quality and profitability. Although this guide lays the foundation, real-world variables often require nuanced judgments through experience. At Greatlight, our engineers understand more than just the theory. We deploy cutting-edge five-axis CNC technology and deep metallurgy expertise every day to drive these decisions under high-risk production needs. Whether it’s solving complex titanium aerospace components or large volumes of automotive parts, we use this mastery to solve complex manufacturing problems under a roof (by one-stop post-processing).

Not sure which insert or process maximizes the potential of your project? Work with pioneers with precision.

👉 Custom CNC machining starts with the perfect tool selection. Contact Greatlight now for an optimization solution.

FAQ: CNC insertion mystery

Q1. How often should I replace the CNC insert?

Depend on material, parameters and wear restrictions – always wait for catastrophic failure. Monitor for side wear, fragmentation or degradation of surface quality. Using industry-standard programs like ISO 3685 helps judges wear down land restrictions.

Q2. Can ceramic inserts be used on aluminum?

Few ideals. The low melting point risk of aluminum welded to the ceramic surface ("Build the edge"). Use sharp carbides or PCD for heat-resistant aluminum grinding or drilling.

Q3. Why choose an uncoated carbide plug-in?

Uncoated carbides stand out in cases where there is a problem with coating adhesion (e.g., severe disruption) or abrasive nonproductive cutting (e.g., brass/composites). Ideal for cost-sensitive fixed operations.

Q4. Which insertion shape allows the most edges?

Triangular inserts typically have six indexable edges (three corners per side). The circular insert provides nearly infinite indexes, but has fewer cut scenes.

Q5. What happens if I use the negative rake tool on a weak setting?

Negative rakes greatly increase cutting forces, risking bending, vibration (“chat”) or dimensional deviation. Defaults to the positive geometry of the elongated/long-term workpiece.

Q6. Does the coating insert require special treatment?

Yes. Avoid impact/dropping. Clean using a non-soaking method to protect the thin coating. Proper storage prevents edge degradation.

Q7. How to optimize chip rupture?

Match the profile of the chip circuit breaker to insert geometry and feed rate: The rough circuit breaker handles high feed. Chip gap jam cutting machine insufficient – consult the application diagram of tool manufacturer!

Q8. Greatlime: How to ensure the best insertion selection?

In addition to catalog-level draft picks, our process for quantum citations includes material testing, parameter simulations and runtime analysis of our advanced five-axis system, including trials and errors.