Understanding the ISO Carbide Classification System
The International Organization for Standardization (ISO) classifies cemented carbide grades into six major application categories based on the workpiece material they are designed to machine. Each category is designated by a letter — P, M, K, N, S, or H — and sub-divided by hardness/toughness performance bands numbered 01 through 50. Lower numbers indicate harder, more wear-resistant grades suited for finishing operations, while higher numbers represent tougher grades optimized for roughing.
This reference guide consolidates cutting parameters, grade equivalents, and application data for five major carbide manufacturers — Sandvik Coromant, Seco Tools, Kennametal, Mitsubishi Materials, and Sumitomo Electric Hardmetal — giving machinists a single-sheet comparison across the full ISO spectrum.
ISO Application Categories at a Glance
| ISO Class | Workpiece Material | Color Code | Typical Vc Range (m/min) | Key Challenge |
|---|---|---|---|---|
| P | Steel (carbon, alloy) | Blue | 150–300 | Built-up edge, crater wear |
| M | Stainless steel | Yellow | 100–250 | Work hardening, thermal cracks |
| K | Cast iron (gray, ductile) | Red | 100–400 | Abrasive wear, depth-of-cut notching |
| N | Non-ferrous (Al, Cu, brass) | Green | 300–1000+ | Built-up edge, chip evacuation |
| S | Heat-resistant superalloys (Ti, Ni-based) | Brown | 30–80 | High heat, notch wear, segregation |
| H | Hardened materials (>45 HRC) | Gray/White | 50–200 | Thermal shock, edge chipping |
ISO P — Steel Turning: Grade Cross-Reference
Steel machining accounts for the largest share of indexable insert consumption globally. P-class grades must balance crater wear resistance (driven by high cutting temperatures during continuous cutting) with sufficient edge toughness to handle interrupted cuts and scale on forged surfaces.
Sandvik, Seco, Kennametal, Mitsubishi & Sumitomo — P-Class Equivalents
| Application Band | Sandvik Coromant | Seco Tools | Mitsubishi | Sumitomo | Coating Type |
|---|---|---|---|---|---|
| P01–P05 (Finishing) | GC1010 | TM2500 | UE6020 | AC8025 | Multilayer MT-TiCN + Al₂O₃ |
| P10–P15 (Light Finishing) | GC1525 | TM2501 | UE6025 | AC8100 | MT-TiCN + thick Al₂O₃ + TiN |
| P15–P25 (Medium Finishing) | GC4215 | TP2501 | US735 | AC3300 | CVD Al₂O₃ + Ti(C,N) |
| P25–P35 (Roughing) | GC4025 | TP3001 | UP735 | AC3040 | CVD MT-TiCN + Al₂O₃ |
| P35–P45 (Heavy Roughing) | GC4230 | TP3501 | US8020 | AC4040 | CVD thick MT-TiCN + Al₂O₃ |
Recommended P-Class Cutting Parameters
| Operation | Grade Band | Vc (m/min) | f (mm/rev) | ap (mm) | Insert Geometry |
|---|---|---|---|---|---|
| Finish turning | P01–P10 | 200–300 | 0.08–0.15 | 0.2–1.0 | -MF / -PF (sharp edge) |
| Semi-finishing | P15–P25 | 180–260 | 0.15–0.35 | 1.0–3.0 | -MM / -PM |
| Rough turning | P25–P40 | 150–220 | 0.3–0.8 | 2.0–6.0 | -MR / -PR (reinforced) |
| Heavy roughing | P35–P45 | 120–180 | 0.5–1.2 | 4.0–10.0 | -GR (ground, robust) |
ISO M — Stainless Steel: Grade Cross-Reference
Stainless steel presents a unique machining challenge because it work-hardens during cutting, generates high cutting forces, and tends to weld to the tool edge. M-class grades require a specialized balance of hot hardness, chemical stability, and edge sharpness.
Grade Equivalents for Stainless Steel
| Application Band | Sandvik Coromant | Seco Tools | Mitsubishi | Sumitomo | Key Coating Feature |
|---|---|---|---|---|---|
| M01–M10 (Finishing) | GC2015 | TM2201 | US8020 | AC2200 | Smooth Al₂O₃ surface, low friction |
| M15–M25 (Semi-finishing) | GC2025 | TM2501 | US735 | AC3300 | Multilayer CVD, post-polished |
| M25–M35 (Roughing) | GC2035 | TP3001 | UP735 | AC3040 | Thick MT-TiCN for toughness |
| M30–M40 (Heavy Rough) | GC4015 | TP2501 | US8025 | AC4040 | Enhanced adhesion, micro-peened |
Recommended M-Class Cutting Parameters
| Stainless Type | Vc (m/min) | f (mm/rev) | ap (mm) | Coolant | Notes |
|---|---|---|---|---|---|
| Austenitic (304/316) | 150–200 | 0.12–0.30 | 0.5–4.0 | High-pressure (70+ bar) | Minimize work hardening, avoid dwells |
| Martensitic (416/420) | 100–160 | 0.10–0.25 | 0.5–3.0 | Flood coolant | Higher hardness, use tougher grade |
| Duplex (2205/2507) | 110–170 | 0.10–0.25 | 0.5–3.0 | High-pressure (70+ bar) | Very abrasive, use K/M mixed grade |
| PH stainless (17-4PH) | 80–140 | 0.08–0.20 | 0.3–2.0 | Flood coolant | Machine in aged condition for best tool life |
ISO K — Cast Iron: Grade Cross-Reference
Cast iron machining demands exceptional abrasive wear resistance due to the hard graphite and carbide inclusions within the material. K-class grades typically feature high cubic boron nitride (CBN) content or thick Al₂O₃ coatings to combat the high-speed abrasive action encountered in gray and ductile iron turning.
Grade Equivalents for Cast Iron
| Application Band | Sandvik Coromant | Seco Tools | Mitsubishi | Sumitomo | Typical Application |
|---|---|---|---|---|---|
| K01–K10 (Finishing) | GC3205 | TK2001 | NX2525 | AC2000 | High-speed finish, gray iron |
| K10–K20 (Light Finishing) | GC3210 | TK2501 | NX2525 | AC3000 | Continuous cut, ductile iron |
| K15–K25 (Semi-finishing) | GC3220 | TK3501 | NC3020 | AC3300 | General-purpose cast iron |
| K20–K30 (Roughing) | GC3310 | TP3501 | NC3025 | AC4040 | Interrupted cut, roughing |
Recommended K-Class Cutting Parameters
| Cast Iron Type | Vc (m/min) | f (mm/rev) | ap (mm) | Notes |
|---|---|---|---|---|
| Gray iron (GG25) | 200–400 | 0.15–0.40 | 1.0–5.0 | High Vc possible due to graphite lubricity |
| Ductile iron (GJS400) | 150–280 | 0.15–0.35 | 1.0–4.0 | More abrasive, reduce Vc vs gray iron |
| Compacted graphite (CGI) | 100–180 | 0.10–0.25 | 0.5–3.0 | Highly abrasive, ceramic or CBN preferred |
| SiMo (wear-resistant) | 60–120 | 0.08–0.20 | 0.5–2.5 | Very hard inclusions, use cermet or CBN |
ISO S — Heat-Resistant Superalloys: Grade Cross-Reference
Nickel-based and titanium alloys used in aerospace, energy, and medical industries present the most demanding machining challenges. Low thermal conductivity concentrates heat at the cutting zone, while the material’s inherent strength at elevated temperatures causes rapid tool wear. S-class grades rely on advanced PVD coatings (TiAlN, AlTiN) with high hot hardness.
Grade Equivalents for Superalloys
| Application Band | Sandvik Coromant | Seco Tools | Mitsubishi | Sumitomo | Coating Technology |
|---|---|---|---|---|---|
| S01–S10 (Finishing) | GC1105 | TM3201 | US8020 | AC5300 | PVD AlTiN, fine-grain substrate |
| S10–S20 (Semi-finishing) | GC1115 | TM3501 | US735 | AC5400 | PVD TiAlN/AlCrN multilayer |
| S20–S30 (Roughing) | GC1125 | TP3501 | UP735 | AC5500 | PVD TiAlN + tough substrate |
| S30–S40 (Heavy Rough) | GC1130 | TP4001 | US8025 | AC6040 | PVD AlCrN, cobalt-enriched zone |
Recommended S-Class Cutting Parameters
| Superalloy Type | Vc (m/min) | f (mm/rev) | ap (mm) | Tool Strategy |
|---|---|---|---|---|
| Inconel 718 (Ni-based) | 30–50 | 0.10–0.25 | 0.5–3.0 | Round insert preferred, lead angle < 15° |
| Waspaloy (Ni-based) | 25–45 | 0.08–0.20 | 0.5–2.5 | Lower Vc than Inconel, use S10 grade |
| Ti-6Al-4V (Ti alloy) | 50–80 | 0.10–0.30 | 0.5–3.0 | Use sharp edge, flood coolant essential |
| Haynes 25/188 (Co-based) | 15–35 | 0.08–0.20 | 0.5–2.0 | Extreme conditions, ceramic inserts recommended |
ISO N — Non-Ferrous Alloys: Grade Cross-Reference
Aluminum, copper, and their alloys are typically machined at very high cutting speeds. The primary challenges are built-up edge (BUE) formation and achieving the required surface finish. N-class grades use polished PVD coatings (diamond-like carbon, TiB₂) or uncoated micro-grain carbide to maintain sharp cutting edges.
Grade Equivalents for Non-Ferrous Materials
| Application Band | Sandvik Coromant | Seco Tools | Mitsubishi | Sumitomo | Best For |
|---|---|---|---|---|---|
| GC1010 | CS3001 (diamond) | NX2525 | AC8100 | High-silicon Al, PCD preferred | |
| N10–N20 (Semi-finishing) | GC1020 | TM2501 | US8020 | AC3300 | General Al/Cu alloys |
| N20–N30 (Roughing) | GC1220 | TP3001 | UP735 | AC3040 | Low-silicon Al, roughing cuts |
Recommended N-Class Cutting Parameters
| Material | Vc (m/min) | f (mm/rev) | ap (mm) | Insert Recommendation |
|---|---|---|---|---|
| Aluminum (low Si <5%) | 500–1000 | 0.10–0.30 | 0.5–4.0 | Uncoated carbide or PCD |
| Aluminum (high Si 10–14%) | 300–500 | 0.10–0.25 | 0.3–2.0 | PCD or CVD diamond required |
| Copper (C110/C360) | 300–600 | 0.10–0.30 | 0.5–3.0 | Sharp polished edge, uncoated |
| Brass (C36000) | 200–500 | 0.15–0.40 | 1.0–5.0 | Uncoated, strong rake angle |
ISO H — Hardened Materials: Grade Cross-Reference
Hard part machining (HPM) eliminates grinding operations by turning or milling materials at hardness levels above 45 HRC. This demands grades with exceptional hot hardness, typically using CBN or advanced ceramic substrates. PVD-coated carbide grades can handle up to approximately 55 HRC, while CBN is required for 55–68 HRC materials.
Grade Equivalents for Hardened Materials
| Application Band | Sandvik Coromant | Seco Tools | Mitsubishi | Sumitomo | Substrate |
|---|---|---|---|---|---|
| H01–H10 (Finishing, >55 HRC) | CBN 7025 | CHN2501 (CBN) | NX2525 | BN2000 (CBN) | CBN, low CBN content |
| H05–H15 (Finishing, 45–55 HRC) | GC1010 | TM2501 | UE6020 | AC8100 | Mixed ceramic or cermet |
| H10–H20 (Semi-finishing) | GC3220 | TK2501 | NC3020 | AC5300 | Ceramic or CBN (medium) |
| H20–H30 (Roughing) | GC3310 | TP3501 | NC3025 | AC6040 | CBN high content or Si₃N₄ ceramic |
Recommended H-Class Cutting Parameters
| Material | Hardness | Vc (m/min) | f (mm/rev) | ap (mm) | Tool Material |
|---|---|---|---|---|---|
| Hardened steel | 45–55 HRC | 100–180 | 0.08–0.20 | 0.2–2.0 | Cermet / ceramic |
| Hardened steel | 55–62 HRC | 80–150 | 0.05–0.15 | 0.1–1.0 | CBN (low content, fine grain) |
| Hardened steel | 62–68 HRC | 60–120 | 0.05–0.12 | 0.1–0.5 | CBN (high content) |
| Powder metal (HSS) | 58–65 HRC | 50–100 | 0.05–0.10 | 0.1–0.5 | CBN |
Coating Technology Comparison: CVD vs PVD
The choice between CVD (Chemical Vapor Deposition) and PVD (Physical Vapor Deposition) coatings significantly impacts insert performance. Most P and K class roughing grades use CVD for its thicker, more wear-resistant layers, while finishing and S-class grades favor PVD for sharper edges and lower residual stress.
| Property | CVD | PVD |
|---|---|---|
| Coating thickness | 5–20 µm | 1–6 µm |
| Deposition temperature | 900–1100°C | 300–500°C |
| Edge sharpness | Moderate (rounded) | Excellent (sharp) |
| Wear resistance | Very high | High |
| Toughness | Moderate | High (no eta-phase) |
| Surface finish | Rougher (needs polishing) | Smoother |
| Common layers | TiN, MT-TiCN, Al₂O₃ | TiAlN, AlTiN, AlCrN, TiB₂ |
| Best for | P/K roughing, high Vc | M/S finishing, low ap, sharp edges |
Practical Selection Guidelines
- Always match ISO class to workpiece material. Using a P-class grade on stainless steel or a K-class grade on steel will result in dramatically shorter tool life due to incompatible coating chemistry and substrate toughness.
- When in doubt, go one grade tougher. Selecting a grade that is slightly tougher (higher number) than theoretically necessary usually provides more forgiving performance than choosing the hardest available grade.
- Check coating compatibility. Titanium alloys can react chemically with certain Ti-based coatings, accelerating wear. Use AlCrN or AlTiN coatings for titanium and nickel alloys.
- Consider the cutting operation. Finishing operations prioritize sharpness and wear resistance (lower band numbers), while roughing operations need toughness and thermal shock resistance (higher band numbers).
- Leverage cross-brand equivalents. If a preferred brand grade is unavailable, use this reference to find the equivalent grade from another manufacturer. Always verify with the manufacturer’s catalog, as formulations change between product generations.
- Account for coolant delivery. High-pressure coolant (70+ bar) can shift parameter windows significantly, particularly for stainless steel and superalloys. When HPC is available, upper-range Vc and f values become more achievable.
Conclusion
Selecting the right carbide grade is a foundational decision that impacts every downstream metric — surface finish, tool life, cycle time, and cost per part. By understanding the ISO classification system and how major manufacturers position their grades within it, machinists can make informed substitutions, optimize parameter selection, and avoid common mismatches that lead to premature tool failure. Keep this reference handy at the tool crib or CNC terminal for quick grade lookups during setup.
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