Tool Steel for Cutting and Forming Processes in Metalworking

Introduction

Tool steels are essential engineering materials that enable the cutting and forming of metals in manufacturing applications. The specialized properties of tool steels provide the hardness, wear resistance, strength, and durability required for metal cutting tools, dies, and molds to withstand extreme conditions.

This article explores the use of tool steels in key metalcutting and metalworking processes. It examines the demands of machining, grinding, stamping, forging, extrusion and other processes. Recommendations are provided for selecting optimized tool steel grades for the unique requirements of each process. Heat treating, surface enhancements, quality control, and performance testing considerations are also discussed.

Overview of Metalworking Processes Requiring Tool Steels

Common metal manufacturing processes utilizing tool steels include:

Machining – Turning, drilling, milling, boring, grinding
Metal stamping – Blanking, punching, bending, drawing
Forging – Open/closed die forging, roll forging, upset forging
Extrusion – Cold/hot extrusion of rods, bars, tubes
Wire drawing – Rod breakdown, wire drawing
Shearing – Flat shear cutting, slitting
Fastener manufacturing – Cold heading, thread rolling
Metal casting – Die casting, permanent mold casting
Rolling – Flat rolling, shape rolling

The tooling must withstand high temperatures, pressures, and abrasive wear conditions.

Challenging Requirements of Metalworking Tool Steels

Demanding needs include:

Withstand high cutting forces and temperatures in machining
Resist deformation under high stamping or extrusion pressures
Maintain dimensions and finishes over hundreds of thousands of cycles
Absorb extreme shock loads and pressures from metal flow
Provide abrasion resistance for cutting, shearing and wearing actions
Retain adequate toughness to prevent catastrophic failure
Resist softening and thermal fatigue at moderate temperatures

Selecting the proper tool steel is key to performance.

Desired Properties for Metalworking Tool Steels

To perform effectively, tool steels for metalworking need:

Very high hardness at room and moderately elevated temperatures
Strength to resist deformation under load
Toughness to endure interrupted cutting and prevent brittle failure
Good thermal fatigue resistance for alternating heating and cooling
Excellent wear resistance for abrasion from metal flow
Dimensional stability during thermal cycling
Sufficient corrosion resistance for some applications

The right balance of these properties ensures reliable, long lasting tool performance.

Tool Steel Grades for Machining Cutting Tools

For turning, milling, drilling and grinding metals, suitable grades include:

High speed steels – M2, M4, M42
Cobalt high speed steels – M35, M36, M42
Cemented carbides – Various WC-Co grades
Ceramics – Alumina, silicon carbide, silicon nitride, PCD
Coated carbides or ceramics – TiAlN, TiN, TiCN, DLC

Hardness at high temperatures is critical for cutting tool integrity.

Tool Steel Grades for Metal Forming Dies

Top selections for stamping, forging, extrusion and drawing dies:

Shock resisting cold work tool steels – S5, S7, S390, S590
Air hardening cold work tool steels – A2, A6, A7, A10
High carbon, high chromium cold work steels – D2, D3, D6, D7
Hot work tool steels – H11, H13, H19, H21, H23
Powder metallurgy tool steels – CPM9V, CPM10V, CPM M4

These provide the ultimate hardness and strength for severe forming actions.

Tool Steel Grades for Shearing Blades

Suitable grades for shearing, slitting, blanking and cutting blades include:

Shock resisting tool steels – S5, S6, S7
Cold work tool steels – A2, A6, D2, D3
Hot work tool steels – H10, H11, H12, H13
Powder metallurgy tool steels – CPM9V, CPM10V

Key needs are strength, toughness and resistance to chipping or cracking.

Heat Treating Requirements for Metalworking Tool Steels

Effective heat treatment requires:

High austenitizing temperatures to dissolve complex alloy carbides
Appropriate quenching media and rates tailored to each steel grade
Cryogenic treatment in some cases to enhance properties
Multi-stage tempering for the right balance of hardness and toughness
Stress relieving of machined or ground components
Straightening or dimensional correction after heat treatment

The goal is fully hardened microstructures capable of withstanding metalworking stresses and abrasion.

Enhancement Technologies for Metalworking Tool Steels

Surface treatments and other enhancements that boost performance include:

Diffusion treatments – Nitriding, carburizing, carbo-nitriding
Thin dense chrome plating for extreme abrasion resistance
Diamond-like carbon (DLC) coatings for low friction and wear protection
TiN, TiCN and other PVD coatings for lubricity and hardness
Laser cladding or welding to re-build worn surfaces
Laser shock peening for deep compressive stresses to inhibit cracking

Applied selectively, these technologies extend metalworking tool life significantly.

Quality Control and Validation Testing

Effective quality practices for metalworking tool steels:

Raw material certification to AISI, DIN, JIS or other standards
Liquid particle inspection and ultrasonic testing for material defects
Verification of heat treatment process parameters
Hardness, microstructure and inclusion content analysis
Tensile, impact, and fracture toughness testing
Dimensional tolerances, surface finish, and profile examination
Coating adhesion, porosity, thickness and hardness evaluation
Sample performance testing under actual or simulated conditions

Robust quality control and testing prevents in-service failures or premature wear.

Key Takeaways for Metalworking Tool Steels

In summary:

Numerous tool steel grades are available to match requirements
Alloy selection, heat treating, and enhancements optimize properties
Coatings and treatments combat wear, friction, and cracking
Advanced manufacturing creates clean tool steel microstructures
Extensive quality validation ensures reliable metalworking performance

Proper material, processing, and quality methods allow metalworking tool steels to withstand extreme conditions and maximize production.

Frequently Asked Questions

What are some key differences between metal cutting and metal forming tool staals?

Metal cutting tool steels like high speed steels require high hot hardness at elevated temperatures. Metal forming steels need maximum resistance to deformation under high pressures even at room temperature.

Why is fracture resistance important for metal forming tool steels?

Unlike cutting tools which fail gradually by wear, forming dies and punches can fail catastrophically by chipping, fracturing or cracking if not sufficiently tough. Even if hardened to very high levels, adequate fracture resistance prevents sudden failures.

What recent surface enhancement options show good potential?

Thick, multi-layer chromium platings provide extreme abrasion resistance for sheet metal forming dies, cutting tools, and shear blades. Laser cladding and remelting techniques allow localized treatment only where needed.

What manufacturing methods offer improvements over conventional tool steels?

Vacuum processing, ESR, and powder metallurgy provide the cleanest tool steel microstructures for improved toughness and ductility. Additive manufacturing enables complex 3D geometries tailored for conformal cooling.

Why is heat treatment process control and validation important?

The extreme demands placed on metalworking tool steels mean that any deviations from optimal hardening, tempering or straightening can result in shortened service life or premature failure. Rigorous process control minimizes variability.

Please let me know if you have any other questions!