Hardening and Tempering of Tool Steel: A Comprehensive Guide

Introduction

Tool steels refer to a variety of alloy steels that are specifically engineered for making tools. Their outstanding hardness, strength, and other properties are derived from careful control of alloying elements and heat treatment processes.

The unique properties of tool steels are developed through sequences of hardening and tempering. Hardening transforms the microstructure to very hard martensite, while tempering reduces brittleness and imparts ductility and toughness.

This guide will provide a detailed overview of the theory, methods, procedures, and best practices for successfully hardening and tempering tool steel components of all types.

Why Heat Treat Tool Steels?

Heat treatment is critical for developing the properties needed in tool steel components:

Achieve the necessary hardness for cutting, forming, and shaping capability
Improve strength, wear resistance, and other mechanical characteristics
Enhance dimensional stability during hard machining and grinding
Allow proper microstructural development for desired performance

Without proper hardening and tempering, tool steels will not exhibit their intended properties and tool life will suffer dramatically.

The specific objectives of tool steel heat treatment are:

Form a very hard martensitic structure via quenching
Reduce brittleness and improve toughness through tempering
Produce a uniform hardness profile from surface to core
Avoid distortion, cracking, or other defects during treatment

With optimized hardening and tempering, tool steels will exhibit maximum effectiveness and longevity in demanding applications.

Tool Steel Metallurgy Fundamentals

To properly heat treat tool steels, it is important to understand some metallurgical fundamentals:

Hardening Mechanism

Heating forms austenite which transforms to very hard martensite upon rapid quenching

Tempering Process

Tempering reduces brittleness of martensite by allowing the formation of tempered martensite

Alloy Carbides

Carbides of vanadium, chromium, molybdenum, tungsten and other elements contribute to high wear resistance

Phases

Tool steels contain a mixture of ferrite, carbides, martensite/austenite, and retained austenite phases depending on alloy and condition

TTT Diagrams

Time-temperature-transformation diagrams demonstrate the transformations that occur upon heating and cooling

CCT Diagrams

Continuous cooling transformation diagrams show microstructural development for a given cooling path

A solid grasp of these metallurgy basics is required to properly select parameters and procedures for effective tool steel heat treatment.

Tool Steel Hardening

Hardening involves heating into the austenite phase field, holding at temperature, then rapidly cooling or quenching to form martensite:

Heating

Slow heating to austenitizing temperature above upper critical temperature
Protect from oxidation and minimize scaling

Soaking

Hold at temperature to allow thorough carbide dissolution into austenite
Time depends on alloy composition and section thickness

Quenching

Rapid cooling to transform austenite into very hard martensite
Quenchant must have sufficient speed and severity to ensure full transformation

Straightening

Martensite formation often causes some distortion which should be straightened

The specific temperatures, times, and quenchants depend on the tool steel grade being processed. But the overall goal of hardening remains producing a very hard martensitic microstructure.

Tempering of Tool Steels

Tempering involves reheating quenched martensitic tool steel to intermediate temperatures to impart ductility:

Objectives

Reduce brittleness and improve toughness
Adjust hardness to final requirements
Allow some stress relief from quenching

Temperature

Usually 400-1200°F depending on needed hardness
Multiple tempers at progressively higher temperatures may be used

Time

Soaking time at temperature can range from 1-2 hours depending on alloy

Cooling

Air cooling, but some alloys may require faster forced air or oil cooling

Tempering transforms brittle as-quenched martensite into more ductile tempered martensite to achieve the optimal combination of hardness and toughness.

Critical Aspects of Tool Steel Hardening

There are several critical factors that must be controlled to achieve effective tool steel hardening:

Quenchant Selection

Each tool steel has an optimum quenching media like oil, water, air, or polymer
Quenchant must have sufficient severity and heat transfer rate to properly harden the steel

Avoiding Cracks

Some alloys are prone to cracking during quenching from improper quenchant or agitation
Precracking before hardening and minimizing constraint helps avoid cracking

Temperature Uniformity

Uneven heating causes variation in hardness through cross section
Careful preheating, soaking, and use of thermocouples ensures uniformity

Austenite Grain Size

Coarse austenite grains reduce toughness – fine grains improve toughness
Tight control of temperature minimizes excessive grain growth

Carbide Dissolution

Insufficient soaking time can leave undissolved carbides reducing hardness
Balance between grain growth and carbide dissolution must be achieved

Decarburization Prevention

Loss of surface carbon causes softening which must be prevented
Use protective atmosphere or vacuum furnaces when applicable

Critical Aspects of Tool Steel Tempering

Effective tool steel tempering requires control over several key factors:

Temperature Uniformity

Uneven heating leads to variability in tempering degree and properties
Use of thermocouples and tempering in batches ensures uniformity

Tempering Sequence

A sequence of increasing tempers may be required to achieve needed toughness
Tempering temperature and number of draws depends on alloy

Cooling Rate After Tempering

For some alloys, the cooling rate from the tempering temperature can affect properties
Air, forced air, or even oil cooling may be specified

Distortion Control

Dimensional changes during tempering must be minimized through process control
Fixtures, supports, or restraints help control distortion

Rehardening Prevention

Overtempering can result in reaustenitizing and loss of hardness
Close monitoring of temperature is critical

Oxidation Resistance

Forming a protective oxide before final tempering prevents discoloration
Done by tempering at 1200-1500°F to form thin oxide layer

Common Tool Steel Heat Treating Methods

There are several approaches used for heat treating tool steels:

Batch Furnaces

Simple box furnaces with protective atmosphere
Used for small to medium size tools
Tight temperature uniformity must be maintained

Pit Furnaces

Large furnaces allowing batch or continuous processing
Multiple temperature zones for heating, soaking, quenching
Common for larger parts like dies and molds

Fluidized Bed Furnaces

Bed of fine media is fluidized by heated gas flow
Excellent uniformity and rapid heating/cooling
Used for many tool steels

Vacuum Furnaces

Heating and quenching performed in evacuated chamber
No surface oxidation and very repeatable processes
Utilized for premium tooling

Induction Hardening

Localized rapid heating via induction field for surface hardening
Allows selective hardening of portions of a part
Mainly used for areas like tool edges or wear surfaces

Laser/Electron Beam Hardening

High intensity laser/electron beam as concentrated heat source
Enables very localized hardening of small areas or complex geometries
Growing in use for specialty tooling

Best Practices for Optimized Tool Steel Hőkezelés

To consistently achieve proper hardening and tempering of tool steels, some sound practices should be employed:

Use certified heat treating facilities with qualified personnel and procedures
Ensure all furnace instrumentation and temperature monitoring equipment is properly calibrated
Verify actual temperature uniformity across the furnace hot zone during process validation
Adhere strictly to prescribed time-temperature cycles for each tool steel grade and condition
Closely monitor loads and quenchant circulation and agitation
Check representative samples like hardness test coupons to confirm results
Maintain detailed records of all process parameters and any deviations
Perform metallography periodically to verify proper microstructure
Establish a system for correcting any variations from standards

Following these and other good practices helps minimize problems like cracking, distortion, property variation, or other defects during tool steel heat treatment.

Specific Hardening and Tempering Procedures for Common Tool Steel Grades

The following provides more detailed hardening and tempering procedures for some of the most common tool steel types:

O1 Oil Hardening Tool Steel

Hardening:

Preheat to 1200-1250°F
Austenitize at 1475-1525°F for 30 minutes
Quench in warm oil (120°F) with agitation

Tempering:

Temper at 350-400°F for 1-2 hours
Cool in air after tempering
Double temper for maximum toughness

A2 Air Hardening Tool Steel

Hardening:

Preheat to 1400-1450°F
Austenitize at 1550-1600°F for 30 minutes
Air quench or quench in air or gas blast

Tempering:

Temper at 900-1000°F for 1 hour
Cool in air after tempering
Multiple tempers can be used

D2 High Carbon High Chromium Tool Steel

Hardening:

Preheat to 950-1100°F
Austenitize at 1900-2000°F for 10-20 minutes
Quench in warm oil (120-180°F) with agitation

Tempering:

Temper at 1000-1025°F for 2 hours, cool in air
Draw at 1075-1175°F for 2 hours, cool in air
Finish temper at 400°F for 1 hour, air cool

H13 Hot Work Tool Steel

Hardening:

Preheat to 1450-1550°F
Austenitize at 1950-2050°F for 15-30 minutes
Gas, oil, or air quench depending on section size

Tempering:

Temper at 1000°F for 2 hours, then air cool
Final temper at 1025-1100°F for 1-2 hours

M2 High Speed Tool Steel

Hardening:

Preheat to 1200-1250°F
Austenitize at 2200-2300°F for 15-30 minutes
Air quench or quench in warm oil/salt bath

Tempering:

Temper at 1050-1150°F for 1-2 hours, air cool
Double temper at same temperature for maximum toughness

As seen, each tool steel grade has unique time, temperature, and quenchant parameters tailored to its individual alloy composition and hardenability.

Common Defects and Remedies for Problematic Tool Steel Heat Treating

Despite best efforts, tool steel heat treatment does not always go as intended. Some potential defects and ways to remedy them include:

Cracking – Increase preheat temp, use more ductile quenchant, reduce severity of quench, precrack before hardening

Distortion – Optimize quench severity, use fixtures or restraints, straighten after quenching

Excessive Grain Growth – Tightly control austenitizing temperature, avoid long soaks

Surface Decarburization – Use protective atmosphere or vacuum furnace, minimize furnace leaks

Non-Uniform Hardness – Improve temperature uniformity, use multiple thermocouples, adjust loading

Overtempering – Carefully follow prescribed tempering temperatures and times, check hardness between tempers

Retained Austenite – Increase hardening temperature or time at temperature, or decrease quench rate from austenitizing temperature

Temper Embrittlement – Keep tempering temperatures below or above susceptible range of 700-850°F

Careful evaluation of all process parameters and metallographic analysis of samples can help diagnose and correct heat treating problems.

Innovations in Tool Steel Heat Treatment Technology

There are ongoing advances that allow for improvements in various aspects of tool steel heat treatment:

Computer control and monitoring for enhanced process control and data collection
New quenching systems like intensive quenching, marquenching, or IQ technologies
Specialty alloy wire quenchants or salt baths for unique cooling requirements
Use of vacuum or inert gas environments to minimize decarburization and oxidation
Laser and induction heating capabilities for local surface hardening or highly controlled heating
Novel polymer quenchants with tailored properties of heat transfer and wetting behavior
Additive manufacturing using laser powder bed fusion to allow complex hardened tool geometries

These and other innovations allow heat treaters to develop specialized cycles tailored to the particular nuances of advanced tool steel alloys.

Summary of Tool Steel Hardening and Tempering Key Points

Tool steel heat treatment for developing ideal hardness and toughness involves:

Slow heating and soaking in the austenite phase field
Rapid quenching using the optimal media for the specific alloy
Careful tempering at precise temperatures and times to balance hardness and ductility
Close control of all process parameters to achieve uniformity and consistency
Adjustments as needed based on hardness testing and microstructural verification
Implementation of best practices for temperature monitoring, protective atmospheres, fixturing, and other factors

With a thorough understanding of the fundamentals, phase transformations, critical variables, and potential defects, heat treaters can successfully process a wide range of tool steel grades for outstanding performance.

Frequently Asked Questions About Tool Steel Heat Treating

What is the main purpose of heat treating tool steels?

The primary objective is to develop the necessary hardness, wear resistance, strength, and other properties required for the tooling application through controlled heating and cooling processes.

What happens if a tool acél is not heat treated properly?

Without proper hardening and tempering, tool steels will be too soft, wear too quickly, fail prematurely, and not function as intended. Performance will suffer dramatically.

What are some key advantages of vacuum heat treating?

Vacuum furnaces allow excellent process control, cleanliness, consistency, and minimization of decarburization. They are ideal for high value tooling.

How long does a typical tool steel heat treating cycle take?

A batch process including preheating, austenitizing, quenching, and tempering stages can take 8-12 hours depending on the grade and process parameters.

What are some main difficulties or defects that can arise during heat treating?

Common issues are cracking, distortion, uneven hardness, residual stress, surface oxidation, improper microstructure, or other variances from standards.

What modern innovations are improving tool steel heat treatment?

Additive manufacturing, computer control, new quenchants and heating methods, vacuum processing, and other advances are enhancing capabilities.

I hope this guide provides helpful and practical information on properly heat treating tool steels to achieve optimal microstructures and properties! Please let me know if you have any other questions.