POWDER POWDER METALLURGY POWDER METALLURGY
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About This Presentation
Metal processing technology in which parts are produced from metallic powders
Usual PM production sequence:
Pressing - powders are compressed into desired shape to produce green compact
Accomplished in press using punch-and-die
Sintering – green compacts are heated to bond the particles into a har...
Slide Content
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
POWDER METALLURGY
1.The Characterization of Engineering Powders
2.Production of Metallic Powders
3.Conventional Pressing and Sintering
4.Alternative Pressing and Sintering Techniques
5.Materials and Products for PM
POWDER METALLURGY
1.The Characterization of Engineering Powders
2.Production of Metallic Powders
3.Conventional Pressing and Sintering
4.Alternative Pressing and Sintering Techniques
5.Materials and Products for PM
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Powder Metallurgy (PM)
Metal processing technology in which parts are
produced from metallic powders
Usual PM production sequence:
1.Pressing -powders are compressed into desired
shape to produce green compact
Accomplished in press using punch-and-die
2.Sintering –green compacts are heated to bond the
particles into a hard, rigid mass
Temperatures are below melting point
Powder Metallurgy (PM)
Metal processing technology in which parts are
produced from metallic powders
Usual PM production sequence:
1.Pressing -powders are compressed into desired
shape to produce green compact
Accomplished in press using punch-and-die
2.Sintering –green compacts are heated to bond the
particles into a hard, rigid mass
Temperatures are below melting point
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Why Powder Metallurgy is
Important
PM parts can be mass produced to net shapeor near
net shape, eliminating or reducing the need for
subsequent machining
PM process wastes very little material -~ 97% of
starting powders are converted to product
PM parts can be made with a specified level of
porosity, to produce porous metal parts
Filters, oil-impregnated bearings and gears
Why Powder Metallurgy is
Important
PM parts can be mass produced to net shapeor near
net shape, eliminating or reducing the need for
subsequent machining
PM process wastes very little material -~ 97% of
starting powders are converted to product
PM parts can be made with a specified level of
porosity, to produce porous metal parts
Filters, oil-impregnated bearings and gears
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
More Reasons Why PM is
Important
Certain metals that are difficult to fabricate by other
methods can be shaped by powder metallurgy
Tungsten filaments for incandescent lamp bulbs
are made by PM
Certain alloy combinations and cermetsmade by PM
cannot be produced in other ways
PM compares favorably to most casting processes in
dimensional control
PM production methods can be automated for
economical production
More Reasons Why PM is
Important
Certain metals that are difficult to fabricate by other
methods can be shaped by powder metallurgy
Tungsten filaments for incandescent lamp bulbs
are made by PM
Certain alloy combinations and cermetsmade by PM
cannot be produced in other ways
PM compares favorably to most casting processes in
dimensional control
PM production methods can be automated for
economical production
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Limitations and Disadvantages
High tooling and equipment costs
Metallic powders are expensive
Problems in storing and handling metal powders
Degradation over time, fire hazards with certain
metals
Limitations on part geometry because metal powders do
not readily flow laterally in the die during pressing
Variations in density throughout part may be a problem,
especially for complex geometries
Limitations and Disadvantages
High tooling and equipment costs
Metallic powders are expensive
Problems in storing and handling metal powders
Degradation over time, fire hazards with certain
metals
Limitations on part geometry because metal powders do
not readily flow laterally in the die during pressing
Variations in density throughout part may be a problem,
especially for complex geometries
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
PM Work Materials
Largest tonnage of metals are alloys of iron, steel,
and aluminum
Other PM metals include copper, nickel, and
refractory metals such as molybdenum and tungsten
Metallic carbides such as tungsten carbide are often
included within the scope of powder metallurgy
PM Work Materials
Largest tonnage of metals are alloys of iron, steel,
and aluminum
Other PM metals include copper, nickel, and
refractory metals such as molybdenum and tungsten
Metallic carbides such as tungsten carbide are often
included within the scope of powder metallurgy
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Collection of PM Parts (courtesy
of DorstAmerica, Inc.)
Collection of PM Parts (courtesy
of DorstAmerica, Inc.)
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Engineering Powders
A powdercan be defined as a finely divided
particulate solid
Engineering powders include metals and ceramics
Geometric features of engineering powders:
Particle size and distribution
Particle shape and internal structure
Surface area
Engineering Powders
A powdercan be defined as a finely divided
particulate solid
Engineering powders include metals and ceramics
Geometric features of engineering powders:
Particle size and distribution
Particle shape and internal structure
Surface area
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Measuring Particle Size
Most common method uses screens of different
mesh sizes
Mesh count-refers to the number of openings per
linear inch of screen
A mesh count of 200 means there are 200
openings per linear inch
Since the mesh is square, the count is equal in
both directions, and the total number of openings
per square inch is 200
2
= 40,000
Higher mesh count = smaller particle size
Measuring Particle Size
Most common method uses screens of different
mesh sizes
Mesh count-refers to the number of openings per
linear inch of screen
A mesh count of 200 means there are 200
openings per linear inch
Since the mesh is square, the count is equal in
both directions, and the total number of openings
per square inch is 200
2
= 40,000
Higher mesh count = smaller particle size
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Screen Mesh for Sorting Particle
Sizes
Screen Mesh for Sorting Particle
Sizes
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Particle Shapes in PM
Particle Shapes in PM
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Interparticle Friction and
Powder Flow
Friction between particles
affects ability of a powder
to flow readily and pack
tightly
A common test of
interparticlefriction is the
angle of reposeformed by
a pile of powders poured
from a narrow funnel
Larger angles mean
greater interparticlefriction
Interparticle Friction and
Powder Flow
Friction between particles
affects ability of a powder
to flow readily and pack
tightly
A common test of
interparticlefriction is the
angle of reposeformed by
a pile of powders poured
from a narrow funnel
Larger angles mean
greater interparticlefriction
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Observations About
InterparticleFriction
Smaller particle sizes generally show greater friction
and steeper angles
Spherical shapes have the lowest interparticalfriction
As shape deviates from spherical, friction between
particles tends to increase
Easier flow of particles correlates with lower
interparticlefriction
Lubricants are often added to powders to reduce
interparticlefriction and facilitate flow during pressing
Observations About
InterparticleFriction
Smaller particle sizes generally show greater friction
and steeper angles
Spherical shapes have the lowest interparticalfriction
As shape deviates from spherical, friction between
particles tends to increase
Easier flow of particles correlates with lower
interparticlefriction
Lubricants are often added to powders to reduce
interparticlefriction and facilitate flow during pressing
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Particle Density Measures
True density -density of the true volume of the
material
The density of the material if the powders were
melted into a solid mass
Bulk density -density of the powders in the loose
state after pouring
Because of pores between particles, bulk density
is less than true density
Particle Density Measures
True density -density of the true volume of the
material
The density of the material if the powders were
melted into a solid mass
Bulk density -density of the powders in the loose
state after pouring
Because of pores between particles, bulk density
is less than true density
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Packing Factor = Bulk Density
Divided by True Density
Typical values for loose powders are 0.5 to 0.7
If powders of various sizes are present, smaller
powders fit into spaces between larger ones
Thus higher packing factor
Packing can be increased by vibrating the powders,
causing them to settle more tightly
Thus higher packing factor
Pressure applied during compaction greatly
increases packing factor of powders
Packing Factor = Bulk Density
Divided by True Density
Typical values for loose powders are 0.5 to 0.7
If powders of various sizes are present, smaller
powders fit into spaces between larger ones
Thus higher packing factor
Packing can be increased by vibrating the powders,
causing them to settle more tightly
Thus higher packing factor
Pressure applied during compaction greatly
increases packing factor of powders
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Porosity
Ratio of volume of the pores (empty spaces) in the
powder to the bulk volume
In principle, Porosity + Packing factor = 1.0
The issue is complicated by possible existence
of closed pores in some of the particles
If internal pore volumes are included in above
porosity, then equation is exact
Porosity
Ratio of volume of the pores (empty spaces) in the
powder to the bulk volume
In principle, Porosity + Packing factor = 1.0
The issue is complicated by possible existence
of closed pores in some of the particles
If internal pore volumes are included in above
porosity, then equation is exact
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Chemistry and Surface Films
Metallic powders are classified as either
Elemental -consisting of a pure metal
Pre-alloyed -each particle is an alloy
Possible surface films include oxides, silica,
adsorbed organic materials, and moisture
As a general rule, these films must be removed
prior to shape processing
Chemistry and Surface Films
Metallic powders are classified as either
Elemental -consisting of a pure metal
Pre-alloyed -each particle is an alloy
Possible surface films include oxides, silica,
adsorbed organic materials, and moisture
As a general rule, these films must be removed
prior to shape processing
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Production of Metallic Powders
In general, producers of metallic powders are not the
same companies as those that make PM parts
Any metal can be made into powder form
Three principal methods by which metallic powders
are commercially produced
1.Atomization
2.Chemical
3.Electrolytic
In addition, mechanical methods are occasionally
used to reduce powder sizes
Production of Metallic Powders
In general, producers of metallic powders are not the
same companies as those that make PM parts
Any metal can be made into powder form
Three principal methods by which metallic powders
are commercially produced
1.Atomization
2.Chemical
3.Electrolytic
In addition, mechanical methods are occasionally
used to reduce powder sizes
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
High velocity gas stream flows through expansion nozzle,
siphoning molten metal and spraying it into chamber
Gas Atomization Method
High velocity gas stream flows through expansion nozzle,
siphoning molten metal and spraying it into chamber
Gas Atomization Method
Water Atomization Method
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
High velocity water
streams flow
through nozzles,
rapidly cooling and
solidifying molten
metal into collection
chamber
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
High velocity water
streams flow
through nozzles,
rapidly cooling and
solidifying molten
metal into collection
chamber
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Iron Powders for PM
Iron powders
produced by
water atomization
(photo courtesy of
T.F.Murphyand
Hoeganaes
Corporation)
Iron Powders for PM
Iron powders
produced by
water atomization
(photo courtesy of
T.F.Murphyand
Hoeganaes
Corporation)
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Conventional Press and Sinter
Conventional PM part-making sequence consists of:
1.Blending and mixing of powders
2.Compaction -pressing into desired shape
3.Sintering -heating to temperature below melting
point to cause solid-state bonding of particles and
strengthening of part
In addition, secondary operations are sometimes
performed to improve dimensional accuracy,
increase density, and for other reasons
Conventional Press and Sinter
Conventional PM part-making sequence consists of:
1.Blending and mixing of powders
2.Compaction -pressing into desired shape
3.Sintering -heating to temperature below melting
point to cause solid-state bonding of particles and
strengthening of part
In addition, secondary operations are sometimes
performed to improve dimensional accuracy,
increase density, and for other reasons
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Conventional PM Production
Sequence
(1) Blending, (2) compacting, and (3) sintering
Conventional PM Production
Sequence
(1) Blending, (2) compacting, and (3) sintering
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Blending and Mixing of Powders
For successful results in compaction and sintering,
the starting powders must be homogenized
Blending-powders of the same chemistry but
possibly different particle sizes are intermingled
Different particle sizes are often blended to
reduce porosity
Mixing-powders of different chemistries are
combined
Blending and Mixing of Powders
For successful results in compaction and sintering,
the starting powders must be homogenized
Blending-powders of the same chemistry but
possibly different particle sizes are intermingled
Different particle sizes are often blended to
reduce porosity
Mixing-powders of different chemistries are
combined
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Compaction
Application of high pressure to the powders to form
them into the required shape
Conventional compaction method is pressing, in
which opposing punches squeeze the powders
contained in a die
Work part after pressing is called a green compact,
the word green meaning not fully processed
The green strengthof the part when pressed is okay
for handling but far less than after sintering
Compaction
Application of high pressure to the powders to form
them into the required shape
Conventional compaction method is pressing, in
which opposing punches squeeze the powders
contained in a die
Work part after pressing is called a green compact,
the word green meaning not fully processed
The green strengthof the part when pressed is okay
for handling but far less than after sintering
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Conventional Pressing in PM
Pressing in PM: (1)
filling die cavity with
powder by automatic
feeder; (2) initial and
(3) final positions of
upper and lower
punches during
pressing, (4) part
ejection
Conventional Pressing in PM
Pressing in PM: (1)
filling die cavity with
powder by automatic
feeder; (2) initial and
(3) final positions of
upper and lower
punches during
pressing, (4) part
ejection
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
450 kN(50-ton)
hydraulic press for
conventional
pressing of PM
parts (photo
courtesy of Dorst
America, Inc.).
450 kN(50-ton)
hydraulic press for
conventional
pressing of PM
parts (photo
courtesy of Dorst
America, Inc.).
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Sintering
Heat treatment to bond the metallic particles, thereby
increasing strength and hardness
Usually carried out at 70% to 90% of the metal's
melting point (absolute scale)
Generally agreed among researchers that the
primary driving force for sintering is reduction of
surface energy
Part shrinkage occurs during sintering due to pore
size reduction
Sintering
Heat treatment to bond the metallic particles, thereby
increasing strength and hardness
Usually carried out at 70% to 90% of the metal's
melting point (absolute scale)
Generally agreed among researchers that the
primary driving force for sintering is reduction of
surface energy
Part shrinkage occurs during sintering due to pore
size reduction
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Sintering Sequence on a
Microscopic Scale
(1) Particle bonding initiated at contact points; (2) contact
points grow into "necks"; (3) pores between particles are
reduced in size; (4) grain boundaries develop between
particles in place of necked regions
Sintering Sequence on a
Microscopic Scale
(1) Particle bonding initiated at contact points; (2) contact
points grow into "necks"; (3) pores between particles are
reduced in size; (4) grain boundaries develop between
particles in place of necked regions
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Densification and Sizing
Secondary operations are performed on sintered part to
increase density, improve accuracy, or accomplish
additional shaping
Repressing -pressing in closed die to increase
density and improve properties
Sizing -pressing to improve dimensional accuracy
Coining -pressing details into its surface
Machining -for geometric features that cannot be
formed by pressing, such as threads and side holes
Densification and Sizing
Secondary operations are performed on sintered part to
increase density, improve accuracy, or accomplish
additional shaping
Repressing -pressing in closed die to increase
density and improve properties
Sizing -pressing to improve dimensional accuracy
Coining -pressing details into its surface
Machining -for geometric features that cannot be
formed by pressing, such as threads and side holes
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Alternative Pressing and
Sintering Techniques
Conventional press and sinter sequence is the most
widely used shaping technology in powder metallurgy
Some additional methods for producing PM parts:
Isostaticpressing -hydraulic pressure is applied
from all directions to achieve compaction
Powder injection molding (PIM) -starting polymer
has 50% to 85% powder content
Polymer is removed and PM part is sintered
Hot pressing -combined pressing and sintering
Alternative Pressing and
Sintering Techniques
Conventional press and sinter sequence is the most
widely used shaping technology in powder metallurgy
Some additional methods for producing PM parts:
Isostaticpressing -hydraulic pressure is applied
from all directions to achieve compaction
Powder injection molding (PIM) -starting polymer
has 50% to 85% powder content
Polymer is removed and PM part is sintered
Hot pressing -combined pressing and sintering
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
Materials and Products for PM
Raw materials for PM are more expensive than for
other metalworking because of the additional energy
required to reduce the metal to powder form
Accordingly, PM is competitive only in a certain range
of applications
What are the materials and products that seem most
suited to powder metallurgy?
Materials and Products for PM
Raw materials for PM are more expensive than for
other metalworking because of the additional energy
required to reduce the metal to powder form
Accordingly, PM is competitive only in a certain range
of applications
What are the materials and products that seem most
suited to powder metallurgy?
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
PM Materials –
Elemental Powders
A pure metal in particulate form
Common elemental powders:
Iron
Aluminum
Copper
Elemental powders can be mixed with other metal
powders to produce alloys that are difficult to
formulate by conventional methods
Example: tool steels
PM Materials –
Elemental Powders
A pure metal in particulate form
Common elemental powders:
Iron
Aluminum
Copper
Elemental powders can be mixed with other metal
powders to produce alloys that are difficult to
formulate by conventional methods
Example: tool steels
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
PM Materials –
Pre-Alloyed Powders
Each particle is an alloy comprised of the desired
chemical composition
Common pre-alloyed powders:
Stainless steels
Certain copper alloys
High speed steel
PM Materials –
Pre-Alloyed Powders
Each particle is an alloy comprised of the desired
chemical composition
Common pre-alloyed powders:
Stainless steels
Certain copper alloys
High speed steel
©2013 John Wiley & Sons, Inc. M P Groover, Principles of Modern Manufacturing 5/e
PM Products
Gears, bearings, sprockets, fasteners, electrical
contacts, cutting tools, and various machinery parts
Advantage of PM: parts can be made to near net
shape or net shape
When produced in large quantities, gears and bearings
are ideal for PM because:
Their geometries are defined in two dimensions
There is a need for porosity in the part to serve as
a reservoir for lubricant
PM Products
Gears, bearings, sprockets, fasteners, electrical
contacts, cutting tools, and various machinery parts
Advantage of PM: parts can be made to near net
shape or net shape
When produced in large quantities, gears and bearings
are ideal for PM because:
Their geometries are defined in two dimensions
There is a need for porosity in the part to serve as
a reservoir for lubricant
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