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- Double-sided Double-edge General Grooving Insert
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- Rhombic 35° (PBVBW)
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- Rhombic 35° (VNGM)
- Rhombic 35° (VNMA)
- Rhombic 35° (VPET)
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- Round (RCGT)
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- Triangle (TCMW)
- Triangle (TCMX)
- Triangle (TEEN)
- Triangle (TEGE)
- Triangle (TEGN)
- Triangle (TEGX)
- Triangle (TNG)
- Triangle (TNGA)
- Triangle (TNGG)
- Triangle (TNGM)
- Triangle (TNMA)
- Triangle (TNMC)
- Triangle (TNML)
- Triangle (TNMM)
- Triangle (TNMN)
- Triangle (TNMR)
- Triangle (TNMU)
- Triangle (TNMX)
- Triangle (TNPL)
- Triangle (TNPR)
- Triangle (TPEW)
- Triangle (TPG)
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- Triangle (TPGB)
- Triangle (TPGD)
- Triangle (TPGG)
- Triangle (TPGH)
- Triangle (TPGT)
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- Triangle (TPGX)
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- Triangle (TPMH)
- Triangle (TPMN)
- Triangle (TPMR)
- Triangle (TPMT)
- Triangle (TPMX)
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- Triangle (TUE)
- Trigon 80° (WBED)
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- Grooving Inserts
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- Irregular arc edge
- Irregular arc edge (XDLT)
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- Octagonal
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- Octagonal (OFCR)
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- Octagonal (OFEN)
- Octagonal (OFER)
- Octagonal (OFET)
- Octagonal (OFEX)
- Octagonal (OFKR)
- Octagonal (OFKT)
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- Octagonal (OFMT)
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- Octagonal (ONET)
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- Octagonal (ONHU)
- Octagonal (ONMF)
- Octagonal (ONMT)
- Octagonal (ONMU)
- Octagonal (ONMX)
- Octagonal (ONPX)
- Octagonal (OWHT)
- Octagonal (OWMT)
- Octagonal (OXMT)
- Parallelogram 75°
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- Parallelogram 85° (ADCT)
- Parallelogram 85° (ADEH)
- Parallelogram 85° (ADGT)
- Parallelogram 85° (ADKR)
- Parallelogram 85° (ADKT)
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- Parallelogram 85° (AEMW)
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- Parallelogram 85° (AOMT)
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- Parallelogram 85° (APKX)
- Parallelogram 85° (APLX)
- Parallelogram 85° (APPT)
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- Parallelogram 85° (AXMT)
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- Rectangular (LPET)
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- Round (RDFG)
- Round (RDGT)
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- Square (SEET)
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- Square (SEGT)
- Square (SEHT)
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- Square (SPKN)
- Square (SPKR)
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- Square (SPKW)
- Square (SPMN)
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- Drill & Mill Combo Insert (QOGT)
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- Irregular arc edge (XDPX)
- Irregular arc edge (XEET)
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- Irregular arc edge (XELW)
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- Irregular arc edge (XNGJ)
- Irregular arc edge (XNMU)
- Irregular arc edge (XNXF)
- Irregular arc edge (XOGU)
- Irregular arc edge (XOHT)
- Irregular arc edge (XOMT)
- Irregular arc edge (XPCW)
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- Micro Internal Grooving Insert
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- Octagonal (ODET)
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- Parallelogram 80° (CNHQ)
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- Parallelogram 80° (HDHN)
- Parallelogram 80° (HNEC)
- Parallelogram 80° (HNEN)
- Parallelogram 80° (HNGF)
- Parallelogram 80° (HNGJ)
- Parallelogram 80° (HNHX)
- Parallelogram 80° (HNPX)
- Parallelogram 82° (BDHX)
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- Parallelogram 85° (ACET)
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- Rectangular (K90BPD)
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- Round (RDCW)
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- Round (REHR)
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- Round (RFHN)
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- Round (RNGJ)
- Round (RNPJ)
- Round (RPCW)
- Round (RPET)
- Round (RPEX)
- Round (RPGB)
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- Special for High Speed Face Milling (GOEN)
- Special for High Speed Face Milling (GOER)
- Square (SDCH)
- Square (SDCN)
- Square (SDCW)
- Square (SDEB)
- Square (SDHN)
- Square (SDPT)
- Square (SEAN)
- Square (SECT)
- Square (SECW)
- Square (SECX)
- Square (SEER)
- Square (SEET)
- Square (SEGN)
- Square (SEGT)
- Square (SEHW)
- Square (SEKN)
- Square (SEKR)
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- Square (SEMT)
- Square (SEPR)
- Square (SEPT)
- Square (SNGN)
- Square (SNHJ)
- Square (SNKN)
- Square (SNMU)
- Square (SNPJ)
- Square (SNXF)
- Square (SOET)
- Square (SOGT)
- Square (SOMT)
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- Square (SPCB)
- Square (SPCH)
- Square (SPCT)
- Square (SPCW)
- Square (SPEB)
- Square (SPEN)
- Square (SPET)
- Square (SPGN)
- Square (SPGX)
- Square (SPKN)
- Square (SPMT)
- Square (SPMW)
- Square (SPMX)
- Square (SPPT)
- Square (SPUN)
- Square Round Nose Finishing Insert (ZCFW)
- Triangle (TNHF)
- Triangle (TNHN)
- Triangle (TPEW)
- Triangle (TPGN)
- Triangle (TPKN)
- Triangular High Feed Milling Insert (JDMT)
- Triangular High Feed Milling Insert (JDMU)
- Triangular High Feed Milling Insert (JDMW)
- Trigon (WEEW)
- Trigon (WNEU)
- Trigon (WNGU)
- Trigon (WOEX)
- Trigon (WPGX)
- Trigon (WPMT)
- Trigon (WPMW)
- Universal Shoulder Milling Insert (MPMX)
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Introduction to Walter Tiger·tec® Coating Technology
Walter AG has established itself as one of the leading innovators in carbide insert coating technology through its proprietary Tiger·tec® system. Introduced initially as a CVD (Chemical Vapor Deposition) multilayer coating platform, Tiger·tec® has evolved into a comprehensive family of coating technologies that now includes Tiger·tec® Silver (PVD-based), Tiger·tec® Gold (PVD-based), and the classic Tiger·tec® CVD multilayer system. Each technology is engineered for specific workpiece material groups and machining conditions, giving shops a precision-matched solution for virtually any turning, milling, grooving, or holemaking application.
In this article, we break down the three generations of Tiger·tec® coating technology, explain the science behind each layer architecture, and provide practical cutting parameter data for common ISO material groups.
Tiger·tec® CVD: The Foundation Multilayer Coating
Layer Architecture
The original Tiger·tec® CVD coating is built on a proven multilayer CVD architecture consisting of three principal layers deposited at high temperatures (approximately 900–1050 °C):
- TiCN (Titanium Carbonitride) base layer — Provides the primary wear resistance and acts as a diffusion barrier between the carbide substrate and outer layers. Typical thickness: 5–8 μm. Hardness approximately HV 3000–3200.
- Al₂O₃ (Aluminum Oxide) middle layer — The defining feature of the Tiger·tec® system. This κ-Al₂O₃ or α-Al₂O₃ layer delivers exceptional thermal insulation, maintaining hardness at cutting temperatures exceeding 1000 °C. Thickness: 3–5 μm. Hardness approximately HV 2200–2500.
- TiN (Titanium Nitride) top layer — A thin (1–2 μm) outer layer that reduces friction against the chip and provides visual wear identification through its distinctive gold color. Hardness approximately HV 2000–2200.
Total coating thickness ranges from 9 to 15 μm, delivering a robust combination of wear resistance, thermal protection, and low-friction chip flow. A proprietary post-coating polishing treatment smooths the rake face, reducing built-up edge (BUE) tendencies and improving surface finish.
Key CVD Grade Designations
| Grade | Primary ISO Application | Secondary ISO Application | Coating Type | Hardness (HV) |
|---|---|---|---|---|
| WPP10 | P01–P15 (Steel, finishing) | M10–M20 | Tiger·tec® CVD (thin Al₂O₃) | 3200 |
| WPP20 | P10–P25 (Steel, medium) | K10–K20 (Cast iron) | Tiger·tec® CVD | 3100 |
| WPP30 | P20–P35 (Steel, roughing) | M25–M30 | Tiger·tec® CVD (thick TiCN) | 3050 |
| WKP10 | K01–K20 (Cast iron, finishing) | N10–N20 (Non-ferrous) | Tiger·tec® CVD | 3150 |
| WKP20 | K10–K30 (Cast iron, medium) | P10–P20 | Tiger·tec® CVD | 3100 |
| WKP35 | K20–K40 (Cast iron, roughing) | P25–P35 | Tiger·tec® CVD (heavy-duty) | 2950 |
| WSM10 | M10–M20 (Stainless, finishing) | S05–S15 | Tiger·tec® CVD | 3050 |
| WSM30 | M25–M35 (Stainless, roughing) | S15–S25 | Tiger·tec® CVD | 2900 |
Tiger·tec® Silver: PVD Breakthrough with Al₂O₃
The Tiger·tec® Silver represents Walter’s breakthrough in applying PVD (Physical Vapor Deposition) technology to produce an aluminum oxide coating — a feat that was previously achievable only through CVD. This is the core innovation that sets Silver apart from conventional PVD coatings like TiAlN or AlCrN used by competing manufacturers.
How PVD Al₂O₃ Changes the Game
Traditional PVD coatings (TiAlN, AlCrN, TiCN) offer excellent hardness and compressive stress but lack the thermal barrier capability of crystalline Al₂O₃. Walter’s proprietary PVD process deposits a thin (3–4 μm total) but highly effective Al₂O₃-containing multilayer at significantly lower temperatures — 500–600 °C compared to 900–1050 °C for CVD. This has several critical advantages:
- Preserved substrate toughness — Lower deposition temperature means the carbide substrate retains more of its original transverse rupture strength (TRS). This is especially important for finishing and semi-finishing applications where edge integrity is paramount.
- Sharper cutting edges — The thinner PVD coating allows for edge honing radii as small as 15–20 μm, compared to 25–40 μm typical with CVD-coated inserts. This translates to lower cutting forces, better surface finish, and reduced burr formation.
- Thermal insulation from Al₂O₃ — Even as a PVD layer, the Al₂O₃ phase provides a thermal barrier that protects the substrate from crater wear at elevated cutting temperatures. This makes Silver grades particularly effective for stainless steel and heat-resistant superalloys where high temperatures are unavoidable.
- Compressive surface stress — PVD coatings inherently apply compressive stress to the insert surface, which helps prevent crack propagation during interrupted cuts — a common failure mode in milling.
Key Silver Grade Designations
| Grade | Primary ISO Application | Coating Process | Total Thickness | Edge Geometry Suitability |
|---|---|---|---|---|
| WPP20S | P10–P25 (Steel turning) | PVD Al₂O₃ multilayer | ~3.5 μm | Finishing to medium (MF) |
| WPP30S | P20–P35 (Steel roughing) | PVD Al₂O₃ multilayer | ~4.0 μm | Medium to roughing (MR) |
| WKP35S | K15–K30 (Cast iron turning) | PVD Al₂O₃ multilayer | ~3.5 μm | Medium to roughing |
| WSM35S | M25–M35, S10–S25 (Stainless & HRSA) | PVD Al₂O₃ multilayer | ~4.0 μm | All geometries |
| WSP45S | P20–P35, M20–M30 (Milling) | PVD Al₂O₃ multilayer | ~3.5 μm | Shoulder milling, face milling |
According to Walter’s internal testing, Tiger·tec® Silver grades like WSM35S can deliver up to 33% higher productivity and 50% longer tool life compared to first-generation Al₂O₃ CVD coatings when machining stainless steel and heat-resistant alloys. The Silver platform is also compatible with dry machining strategies, eliminating coolant costs in appropriate applications.
Tiger·tec® Gold: The Latest Evolution in PVD Coating
Launched as the newest addition to the Tiger·tec® family, Tiger·tec® Gold pushes PVD coating technology even further with its flagship grade WSP45G. This coating utilizes a novel TiAlN-Al₂O₃ composite PVD architecture that simultaneously achieves high hardness and high toughness — a combination that is notoriously difficult to balance in a single coating system.
TiAlN-Al₂O₃ Composite Architecture
The Gold coating is structured as a nanoscale multilayer alternating between TiAlN and Al₂O₃ phases. The TiAlN layers provide the hardness and hot hardness necessary for wear resistance, while the Al₂O₃ layers contribute thermal barrier properties and crack-arresting functionality. The result is a coating that:
- Maintains hardness above HV 3300 at cutting temperatures up to 900 °C
- Exhibits 75% longer tool life on average compared to standard PVD TiAlN coatings when machining abrasive and difficult-to-machine materials
- Features a proprietary post-treatment process that modifies the surface stress state, reducing the likelihood of microcracking along the cutting edge during interrupted cutting
- Displays a distinctive light gold surface color that enables visual wear monitoring, allowing operators to quickly identify unused edges and track wear progression
Primary Applications for WSP45G
WSP45G is designed for the most demanding machining scenarios — particularly those involving difficult workpiece materials (ISO S nickel-based alloys, ISO M stainless steels) and challenging cutting conditions (long overhangs, unstable fixturing, interrupted cuts, entry/exit on uneven surfaces). It is available across Walter’s major milling platforms:
- Xtra·tec® XT shoulder mills and face mills
- Walter BLAXX high-feed and heavy-duty milling cutters
- M4000 high-performance face mills
- Walter D4120 double-margin drilling tools
Head-to-Head: Comparing Tiger·tec® Generations
| Property | Tiger·tec® CVD | Tiger·tec® Silver (PVD) | Tiger·tec® Gold (PVD) |
|---|---|---|---|
| Deposition Temperature | 900–1050 °C | 500–600 °C | 500–600 °C |
| Total Coating Thickness | 9–15 μm | 3–4 μm | 3–4 μm |
| Minimum Edge Radius | 25–40 μm | 15–20 μm | 15–20 μm |
| Primary Hardness (HV) | 2900–3200 | 3100–3400 | 3300+ |
| Thermal Barrier | Excellent (Al₂O₃ layer) | Good (PVD Al₂O₃) | Very Good (TiAlN-Al₂O₃ composite) |
| Substrate Toughness Retention | Moderate (eta-phase risk) | High | High |
| Best Suited For | Continuous turning, high-heat applications | Stainless steel, HRSA, finishing | Milling, drilling, interrupted cuts, abrasive materials |
| Dry Machining Capability | Limited | Good | Good |
| Surface Finish Capability | Ra 1.6–3.2 μm | Ra 0.8–1.6 μm | Ra 0.8–1.6 μm |
Recommended Cutting Parameters by Grade and Material
Steel Turning (ISO P) — CNMG120408-NM4 Style
| Grade | Operation | Workpiece | Vc (m/min) | f (mm/rev) | ap (mm) | Coolant |
|---|---|---|---|---|---|---|
| WPP20 (CVD) | Finishing | Carbon steel (P10) | 250–320 | 0.08–0.15 | 0.5–2.0 | Flood |
| WPP20 (CVD) | Medium | Alloy steel (P20) | 200–260 | 0.20–0.35 | 2.0–4.0 | Flood |
| WPP30 (CVD) | Roughing | Alloy steel (P30) | 160–220 | 0.30–0.50 | 3.0–6.0 | Flood |
| WPP20S (Silver) | Finishing | Carbon steel (P10) | 280–360 | 0.10–0.18 | 0.5–1.5 | Dry / MQL |
| WPP20S (Silver) | Medium | Alloy steel (P20) | 220–300 | 0.20–0.35 | 1.5–3.5 | Dry / MQL |
Stainless Steel Turning (ISO M) — CNMG120408-MR4 Style
| Grade | Operation | Workpiece | Vc (m/min) | f (mm/rev) | ap (mm) | Coolant |
|---|---|---|---|---|---|---|
| WSM30 (CVD) | Roughing | AISI 316L (M30) | 120–170 | 0.25–0.40 | 2.0–5.0 | Flood |
| WSM10 (CVD) | Finishing | AISI 304 (M15) | 180–240 | 0.10–0.20 | 0.5–2.0 | Flood |
| WSM35S (Silver) | Roughing | AISI 316L (M30) | 150–200 | 0.25–0.40 | 2.0–5.0 | Dry preferred |
| WSM35S (Silver) | Semi-finishing | AISI 304 (M20) | 200–260 | 0.15–0.25 | 1.0–3.0 | Dry preferred |
Milling — Shoulder/Face Milling (ISO P, M, S)
| Grade | Workpiece | Vc (m/min) | fz (mm/tooth) | ap (mm) | ae (mm) | Coolant |
|---|---|---|---|---|---|---|
| WSP45S (Silver) | Carbon steel P20 | 200–280 | 0.12–0.20 | 2.0–5.0 | 40–60%Dc | Dry |
| WSP45G (Gold) | Stainless 316 M30 | 150–210 | 0.10–0.18 | 2.0–4.0 | 30–50%Dc | Dry / MQL |
| WSP45G (Gold) | Inconel 718 S25 | 60–100 | 0.06–0.12 | 1.0–3.0 | 25–40%Dc | Dry preferred |
| WSP45G (Gold) | Ti-6Al-4V S15 | 80–130 | 0.08–0.15 | 1.5–4.0 | 30–50%Dc | Dry preferred |
How to Choose the Right Tiger·tec® Grade
Selecting the optimal Tiger·tec® coating for your application requires evaluating three key factors:
1. Workpiece Material Group
- ISO P (Steel): CVD grades (WPP10–WPP30) are the workhorses for continuous turning. Choose Silver (WPP20S/WPP30S) when edge sharpness is critical or when transitioning to dry machining. Gold (WSP45G) excels in milling applications involving alloy steels.
- ISO K (Cast Iron): The CVD platform (WKP10–WKP35) provides the best balance for cast iron turning, especially at higher speeds where thermal barrier properties dominate. Silver (WKP35S) is preferred for finishing operations requiring superior surface finish.
- ISO M (Stainless Steel): Silver grades (WSM35S) are often the first choice due to their combination of sharp edges, thermal protection, and the ability to machine dry. The higher toughness retention at the cutting edge reduces chipping in work-hardened stainless materials.
- ISO S (HRSA — Nickel/Titanium Alloys): Gold (WSP45G) is the recommended platform for milling titanium and nickel-based superalloys. Its TiAlN-Al₂O₃ composite structure handles the extreme heat and abrasive nature of these materials better than single-phase PVD coatings. Silver (WSM35S) remains a strong option for turning operations.
2. Machining Operation Type
- Continuous turning: CVD grades generally offer the longest tool life due to their thicker wear-resistant layers. The Al₂O₃ thermal barrier is most effective in continuous heat generation scenarios.
- Interrupted cutting / milling: PVD grades (Silver and Gold) excel because compressive coating stress resists thermal fatigue cracking. Gold (WSP45G) adds the extra toughness needed for heavy interrupted cuts.
- Finishing operations: Silver grades deliver the sharpest edges and best surface finish capabilities (Ra 0.8 μm achievable).
- Grooving and parting: Silver grades are preferred for their thin coating and sharp geometry, which reduce cutting forces in confined groove geometries.
3. Coolant Strategy
One of the practical advantages of the Silver and Gold PVD platforms is their compatibility with dry machining and MQL (Minimum Quantity Lubrication). The Al₂O₃ thermal barrier in these coatings provides sufficient heat resistance that coolant is not always necessary — and in some cases, eliminating coolant improves tool life by avoiding thermal shock cycling that can cause coating delamination.
Competitive Context: Walter Tiger·tec® vs. Industry Alternatives
While this article focuses on Walter’s technology, it is worth understanding how Tiger·tec® positions against competing coating platforms:
- Sandvik GC4315 / GC4325 (CVD): Sandvik’s second-generation CVD coatings with highly controlled Al₂O₃ crystallography. Comparable thermal barrier performance to Walter CVD, but Walter’s Silver PVD offers sharper edges for finishing.
- Seco Duratomic® (CVD): Uses an unbalanced magnetron sputtering-like CVD process for Al₂O₃. Strong competition in ISO P and K turning, though typically thicker coatings than Walter Silver.
- Iscar IC908 / IC8150 (CVD/PVD): Iscar’s SUMO TEC post-treatment combines CVD and PVD advantages. Walter’s advantage lies in the proprietary PVD Al₂O₃ process unique to Silver and Gold.
- Kyocera PV7100 (PVD): A conventional TiAlN-based PVD coating. Effective for milling, but lacks the Al₂O₃ thermal barrier that gives Walter Silver and Gold their edge in high-temperature machining of stainless and HRSA materials.
Conclusion
Walter’s Tiger·tec® coating system — spanning CVD, Silver PVD, and Gold PVD technologies — provides one of the most comprehensive insert coating portfolios in the industry. The key takeaway for machinists and process engineers is straightforward: match the coating generation to the machining challenge. CVD for high-heat continuous turning where maximum wear resistance is needed. Silver for stainless and heat-resistant alloys where edge sharpness and dry-machining capability deliver measurable advantages. Gold for the toughest milling and drilling applications involving difficult materials and unstable conditions.
By understanding the distinct thermal, mechanical, and edge-quality characteristics of each Tiger·tec® generation, you can make more informed insert selections that directly translate to higher productivity, longer tool life, and more consistent part quality on the shop floor.
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Written by wg
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