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Heat Treatment

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... Relieving Normalizing Annealing Annealing cont. Hardening and Tempering Hardening and Tempering Fundamental Metallurgy Fundamental Metallurgy Basic ... – PowerPoint PPT presentation

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Title: Heat Treatment


1
Heat Treatment
  • Metals and Welding

2
Heat Treatment
  • An operation, or series of operations, involving
    the heating and cooling of steel in the solid
    state to develop the required properties.
  • Related to the crystalline structure of carbon
    and iron.

3
Heat Treatment
  • Low carbon steels are generally used as rolled
    and in most cases do not respond well to heat
    treating
  • High carbon steels and alloys use heat treatment
    as the means of achieving the ultimate property
    capabilities on the metals

4
Four Types
  • Stress Relieving
  • Normalizing
  • Annealing
  • Hardening and Tempering

5
Stress Relieving
  • Reduces internal stresses that may have been
    caused by machining, cold working or welding.
  • Heat the metal to a temperature below the
    critical range (1100ºF)
  • Hold until temperature is reached throughout the
    piece.
  • Allow to cool slowly

6
Normalizing
  • Promotes uniformity of the structure and alters
    mechanical properties.
  • The steel is heated to a determined temperature
    above the critical range (1600-1700º F)
  • Cooled to below that range in still air.
  • Molecular structure changes
  • Results in higher strength, hardness, and less
    ductility
  • Cools faster than stress relieving or annealing

7
Annealing
  • May be used for the following
  • To soften steel
  • To develop a structure like lamellar pearlite or
    spheroidized carbide.
  • To improve machinability or facilitate cold
    shaping
  • To prepare the steel for additional heat
    treatment

8
Annealing cont.
  • to reduce stress
  • to improve or restore ductility
  • to modify other properties
  • Steel is heated to a point at or near the
    critical range (1600-1700ºF)
  • Cooled slowly at a predetermined rate.

9
Hardening and Tempering
  • Hardens the metal and tempering reheats to
    relieve internal stress.
  • Uses 3 operations
  • Heating the steel above the critical range, so it
    approaches a uniform solid solution
  • Hardening the steel by quenching in oil, water,
    brine or fused salt bath
  • Tempering by reheating to a point below the
    critical range to get the proper combination of
    strength and ductility

10
Hardening and Tempering
  • Molecular structure changes to small grain
    Austenite
  • Quenching locks in hard structure
  • Reheating and tempering to relieve brittleness
    and make the steel tough

11
Fundamental Metallurgy
  • Metal structures determined by molecular shapes
  • Body centered cube
  • 9 atoms 8 at cube corners and 1 in the center
  • Can be worked cold

12
Fundamental Metallurgy
  • Metal structures determined by molecular shapes
  • Face centered cube
  • 14 atoms 8 at cube corners and 1 each on the six
    faces
  • Not plastic and cannot be worked cold

13
Basic Guide to Fundamental Metallurgy
  • Grain size is unchanged as temperature increases
    from ambient (room temperature) up to
    transformation range
  • At extremely low temperature, impact resistance
    is low
  • In the transformation range, grain size becomes
    small as temperature increases
  • Transformation (critical temperature) is the
    lowest at the 0.83 Carbon (Eutectoid steel) level

14
Basic Guide to Fundamental Metallurgy
  • Lower carbon levels have a higher critical
    temperature
  • Carbon steels are body centered cubic structures
    at room temperature and are a face centered cubic
    structure at the transformation temperature

15
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16
Fundamental Metallurgy Terms
  • Cementite - Iron carbide Fe3C chemical compound
    of iron and carbon

17
Fundamental Metallurgy Terms
  • Ferrite - Pure iron
  • Pearlite - Grain structure resulting from a
    mechanical combination of ferrite and
    cementite in layer formation.

18
Terms cont.
  • Austenite - grains of ferrite and pearlite change
    when steel is heated to transformation
    temperature.
  • Austenite will dissolve carbon and alloying
    elements.
  • Martensite - Formed when carbon steel is rapidly
    cooled by quenching. Untempered martensite is the
    hardest and most brittle of the microstructures.
  • Click Here for more crystal structure information

19
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20
Hardenability and Weldability are influenced by
four factors
  • Carbon content Weldable ? .35 C ?Hardenable
  • Heating Cycle maximum temperature
  • Cooling Cycle minimum temperature
  • Speed of cooling

21
Methods of Hardening Steel
  • Quenching
  • Brine severe, fast
  • Cold water medium rate
  • Warm Oil slow rate
  • Tempering reheating and requenching at
    temperature desired
  • Cold chisel allow heat from upper end to reheat
    lower portion

22
Surface Hardening
  • Benefits
  • Resists wear and deformation
  • Two zones result, avoiding brittleness
  • Surface hardness is increased without sacrificing
    desirable mechanical properties

23
Surface Hardening
  • Flame Hardening
  • Heating steel to above the critical temperature
    by use of a flame
  • Followed by quenching
  • Can harden small areas (i.e., push rod ends)

24
Surface Hardening
  • Induction Hardening
  • Heat is generated by electrical induction
  • Frequency between 1000 to 3,000,000 cycles per
    second used
  • Maximum hardness by these two processes is a
    function of the carbon content
  • Used on gears (teeth), shafts, cams,
    crankshafts, cylinders, and levers

25
Surface Hardening
  • Carburizing
  • Hardening the surface in the presence of a
    carbonaceous material as a gas, solid, or liquid
  • Surface is hardened and the core remains as
    original material
  • The depth of the case acquired is governed by
    temperature, time, activity of carburizing
    medium, and the analysis of the ferrous alloy
    used.
  • Since hardness increases with carbon content,
    increasing the carbon content of the surface of a
    low carbon steel (by diffusion) results in high
    hardness at the surface and toughness at the core

26
Surface Hardening
  • Pack or Box Carburizing
  • Work is placed in a pack or box filled with a
    solid carburizing agent
  • Heated to 1550 - 1750º F
  • CO reacts with steel and dissolves into austenite
  • Quench harden after heating, or let cool slowly
    and reheat and quench after working

27
Surface Hardening
  • Liquid carburizing
  • Molten salts containing cyanides and chlorides
  • Heat to 1600-1750º F and place work in cyanide
    salt solution
  • Length of time determines thickness of surface
    hardened
  • Quench in oil or brine after removing from salt
    solution
  • No moisture can be on metal when placed in salt
    solution or an explosion could result

28
Heat Treating Definitions
  • See Pages 64-65

29
Reading Assignment
  • Oxy-Acetylene Welding and Cutting
  • Oxy Acetylene Equipment - Pages 115-128
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