1. BABARIA INSTITUTE OF TECHNOLOGY
DESIGNED BY:
HUSAIN Y MALEK.
E. NO:
ROLL NO:14ME38

2. Heat Treatment on steel

3. HEAT TREATMENT
Heat treatment is a method used to alter the physical, and sometimes chemical properties of a material. The most common application is metallurgical
It involves the use of heating or chilling, normally to extreme temperatures, to achieve a desired result such as hardening or softening of a material
It applies only to processes where the heating and cooling are done for the specific purpose of altering properties intentionally

4. HEAT TREATMENT
Fundamentals: Fe-C equilibrium diagram. Isothermal and continuous cooling transformation diagrams for plain carbon and alloy steels. Microstructure and mechanical properties of pearlite, bainite and martensite. Austenitic grain size. Hardenability, its measurement and control.

5. TTT diagrams
TTT diagram stands for “time-temperature-transformation” diagram. It is also called isothermal transformation diagram.
Definition: TTT diagrams give the kinetics of isothermal transformations.
TTT diagram is a plot of temperature versus the logarithm of time for a steel alloy of definite composition.
It is used to determine when transformations begin and end for an isothermal heat treatment of a previously austenitized alloy.
TTT diagram indicates when a specific transformation starts and ends and it also shows what percentage of transformation of austenite at a particular temperature is achieved.

6. Determination of TTT diagram for eutectoid steel
Davenport and Bain were the first to develop the TTT diagram of eutectoid steel. They determined pearlite and bainite portions whereas Cohen later modified and included MS and MF temperatures for martensite. There are number of methods used to determine TTT diagrams.
These are salt bath (Figs. 1-2) techniques combined with metallography and hardness measurement, dilatometry (Fig. 3),electrical resistivity method, magnetic permeability, in situ diffraction techniques (X-ray, neutron), acoustic emission, thermal measurement techniques, density measurement techniques and thermodynamic predictions. Salt bath technique combined with metallography and hardness measurements is the most popular and accurate method to determine TTT diagram.

7. Fig. 1 : Salt bath I -austenitisation heat treatment.
Fig. 2 : Bath II low-temperature salt-bath for isothermal treatment.

8. Fig. 3(b) : Dilatometer equipment
Fig . 3(a): Sample and fixtures for dilatometric measurements

9. Determination of TTT diagram for eutectoid steel
In bath I number of samples are austenitised at AC °C for eutectoid and hypereutectoid steel, AC °C for hypoeutectoid steels for about an hour. Then samples are removed from bath I and put in bath II and each one is kept for different specified period of time say t1, t2, t3, t4, tn etc. After specified times, the samples are removed and quenched in water.
The time taken to 1% transformation to, say pearlite or bainite is considered as transformation start time and for 99% transformation represents transformation finish. On quenching in water austenite transforms to martensite.
But below 230°C it appears that transformation is time independent, only function of temperature

10. Therefore after keeping in bath II for a few seconds it is heated to above 230°C a few degrees so that initially transformed martensite gets tempered and gives some dark appearance in an optical microscope when etched with nital to distinguish from freshly formed martensite (white appearance in optical microscope). Followed by heating above 230°C samples are water quenched. So initially transformed martensite becomes dark in microstructure and remaining austenite transform to fresh martensite (white).
Quantity of both dark and bright etching martensites are determined. Here again the temperature of bath II at which 1% dark martensite is formed upon heating a few degrees above that temperature (230°C for plain carbon eutectoid steel) is considered as the martensite start temperature (designated MS). The temperature of bath II at which 99 % martensite is formed is called martensite finish temperature ( MF).
Transformation of austenite is plotted against temperature vs time on a logarithm scale to obtain the TTT diagram. The shape of diagram looks like either S or like C.

11. Hardness Temperature Log time
Fig.4: Time temperature transformation (schematic) diagram for plain carbon eutectoid steel
100 T2
At T1, incubation period for pearlite=t2,
Pearlite finish time =t4
Minimum incubation period t0 at the nose of the TTT diagram, T1
% of Phase
50%
Ae1
Austenite +pearlite T2
Pearlite start
Coarse Pearlite
50% Transformation
Pearlite finish
Pearlite T1 t1 t2 t3 t4
Fine pearlite t5 t0
Hardness
50% very fine pearlite + 50% upper bainite
MS=Martensite start temperature
M50=temperature for 50% martensite formation
MF= martensite finish temperature
Austenite+upper bainite
Upper bainite
Temperature
Metastable austenite
Bainite finish
Bainite start
Austenite +lower bainite
Lower bainite
MS, Martensite start temperature
M50,50% Martensite
Metastable austenite +martensite
MF, Martensite finish temperature
Martensite
Log time

12. Fig. 7(a) :Schematic TTT diagram for plain carbon hypoeutectoid steel
Ae3
γ=austenite
α=ferrite
CP=coarse pearlite
P=pearlite
FP=fine pearlite
UB=upper Bainite
LB=lower Bainite
M=martensite
MS=Martensite start temperature
M50=temperature for 50% martensite formation
MF= martensite finish temperature
γ+α
Ae1
α+CP
α+P
γ+P FP t0
Hardness
FP + UB
Temperature UB
Metastable γ LB MS
M50
Metastable γ + M MF M
Log time

13. Fig. 7(b): Schematic TTT diagram for plain carbon hypereutectoid steel
Aecm
γ=austenite
CP=coarse pearlite
P=pearlite
FP=fine pearlite
UB=upper Bainite
LB=lower Bainite
M=martensite
MS=Martensite start temperature
M50=temperature for 50% martensite formation
γ+Fe3C
Ae1
Fe3C+CP
γ +P
Fe3C+FP t0
very FP +UB
Hardness UB
Temperature
γ+UB
Metastable γ
γ+LB LB MS
M50
Metastable γ + M
Log time

14. Fig. 5(b): Optical micrograph showing colonies of pearlite.
Fig. 5(a) : The appearance of a (coarse) pearlitic microstructure under optical microscope.
Fig. 5(b): Optical micrograph showing colonies of pearlite. 14

15. Fig. 5(c): Transmission electron micrograph of extremely fine pearlite.
Fig. 5(d): Optical micrograph of extremely fine pearlite from the same sample as used to create Fig. 5(c). The individual lamellae cannot now be resolved. 15

16. Upper bainite ( °C)
Lower bainite ( °C)
Martensite

17. What’s a CCT Diagram?
Phase Transformations and Production of Micro constituents takes TIME.
Higher Temperature = Less Time.
If you don’t hold at one temperature and allow time to change, you are “Continuously Cooling”.
Therefore, a CCT diagram’s transition lines will be different than a TTT diagram.

18. Slow Cooling
Time in region indicates amount of microconstituent!

19. Medium Cooling
Cooling Rate, R, is Change in Temp / Time °C/s

20. Fast Cooling
This steel is very hardenable… 100% Martensite in ~ 1 minute of cooling!

21. TTT diagram gives
Nature of transformation-isothermal or athermal (time independent) or mixed Type of transformation-reconstructive, or displaciv Rate of transformation Stability of phases under isothermal transformation conditions.
Temperature or time required to start or finish transformation
Qualitative information about size scale of product
Hardness of transformed products

22. Types of heat treatment on steel
We have noted that how TTT and CCT diagrams can help us design heat treatments to design the microstructure of steels and hence engineer the properties.
Thermal (heat treatment)
Or a combination (Thermo-mechanical,
thermo-chemical)
Treatments
Mechanical
Chemical
Bulk
Surface

23. An overview of important heat treatments
BULK
SURFACE
ANNEALING
HARDENING & TEMPERING
THERMAL
THERMO- CHEMICAL
NORMALIZING
Full Annealing
Carburizing
MARTEMPERING
Flame
Recrystallization Annealing
Induction
Nitriding
AUSTEMPERING
Stress Relief Annealing
LASER
Carbo-nitriding
Spheroidization Annealing
Electron Beam

24. Ranges of temperature where Annealing,Normalizing and Spheroidization treatment are carried out for hypo- and hyper-eutectoid steels.
Full Annealing
910C
Acm
Normalization
Normalization A3
Full Annealing
723C A1
Spheroidization
Stress Relief Annealing  T
Recrystallization Annealing
Wt% C
0.8 %

25. Recrystallization Annealing
Full Annealing
The steel is heated above A3 (for hypo-eutectoid steels) | A1 (for hyper-eutectoid steels) → (hold) → then the steel is furnace cooled to obtain Coarse Pearlite Coarse Pearlite has ↓ Hardness, ↑ Ductility Not above Acm → to avoid a continuous network of proeutectoid cementite along grain boundaries (→ path for crack propagation)
Recrystallization Annealing
Heat below A1 → Sufficient time → Recrystallization
Cold worked grains → New stress free grains
Used in between processing steps (e.g. sheet rolling)

26. Stress Relief Annealing
Annihilation of dislocations, polygonization
Residual stresses → Heat below A1 → Recovery
Welding
Differential cooling
Machining and cold working
Martensite formation
Spheroidization Annealing / Process Annealing
Heat below/above A1 (long time) Cementite plates → Cementite spheroids → ↑ Ductility
Used in high carbon steel requiring extensive machining prior to final hardening & tempering
Driving force is the reduction in interfacial energy

27. NORMALIZING
Heat above A3 | Acm → Austenization → Air cooling → Fine Pearlite (Higher hardness)
Purposes
Refine grain structure prior to hardening
To harden the steel slightly
To reduce segregation in casting or forgings
In hypo-eutectoid steels normalizing is done 50oC above the annealing temperature
In hyper-eutectoid steels normalizing done above Acm → due to faster cooling cementite does not form a continuous film along GB

28. HARDENING Quench produces residual strains
Heat above A3 | Acm → Austenization → Quench (higher than critical cooling rate)
Quench produces residual strains
Transformation to Martensite is usually not complete (will have retained Austenite)
Martensite is hard and brittle
Tempering operation usually follows hardening; to give a good combination of strength and toughness

29. Schematic of Jominy End Quench Test
Typical hardness test survey made along a diameter of a quenched cylinder
Variation of hardness along a Jominy bar (schematic for eutectoid steel)
Jominy hardenability test

30. Quenching media Heat Treatments Brine (water and salt solution) Water
Oil
Air
Turn off furnace
Heat Treatments
A – Normalising
B – Annealing or Hardening
C – Spheroidising or Process Annealing
D - Tempering

31. Tempering Heat below Eutectoid temperature → wait→ slow cooling
The microstructural changes which take place during tempering are very complex
Time temperature cycle chosen to optimize strength and toughness
Tool steel: As quenched (Rc 65) → Tempered (Rc 45-55)

32. MARTEMPERING AUSTEMPERING
To avoid residual stresses generated during quenching
Austenized steel is quenched above Ms for homogenization of temperature across the sample
The steel is then quenched and the entire sample transforms simultaneously
Tempering follows
Austenite
Pearlite
Pearlite + Bainite
Bainite
Martensite
100
200
300
400
600
500
800
723
0.1 1 10
102
103
104
105
Eutectoid temperature Ms Mf
t (s) →
T →
 + Fe3C
Martempering
Austempering
AUSTEMPERING
To avoid residual stresses generated during quenching
Austenized steel is quenched above Ms
Held long enough for transformation to Bainite

33. THANK YOU