Lecture-Polymeric and Composite materials.ppt
HafizMudaserAhmad
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Nov 30, 2022
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About This Presentation
This is complete lecture containing topics related to the polymers and polymer composites
Slide Content
Polymeric and Composite
Materials
Materials
POLYMERS AND
COMPOSITE MATERIALS
1.Fundamentals of Polymer Technology
2.Thermoplastic Polymers
3.Thermosetting Polymers
4.Elastomers
5.Composites--Technology and Classification
6.Composite Materials
7.Guide to the Processing of Polymers and Composite
Materials
COMPOSITE MATERIALS
1.Fundamentals of Polymer Technology
2.Thermoplastic Polymers
3.Thermosetting Polymers
4.Elastomers
5.Composites--Technology and Classification
6.Composite Materials
7.Guide to the Processing of Polymers and Composite
Materials
Polymer
A compound consisting of long-chain molecules, each
molecule made up of repeating units connected
together
There may be thousands, even millions of units in a
single polymer molecule
The word polymeris derived from the Greek words
poly, meaning many, and meros(reduced to mer),
meaning part
Most polymers are based on carbon and are
therefore considered organic chemicals
A compound consisting of long-chain molecules, each
molecule made up of repeating units connected
together
There may be thousands, even millions of units in a
single polymer molecule
The word polymeris derived from the Greek words
poly, meaning many, and meros(reduced to mer),
meaning part
Most polymers are based on carbon and are
therefore considered organic chemicals
Types of Polymers
Polymers can be separated into plastics and rubbers
As engineering materials, it is appropriate to divide
them into the following three categories:
1.Thermoplastic polymers
2.Thermosetting polymers
3.Elastomers
where (1) and (2) are plastics and (3) are rubbers
Polymers can be separated into plastics and rubbers
As engineering materials, it is appropriate to divide
them into the following three categories:
1.Thermoplastic polymers
2.Thermosetting polymers
3.Elastomers
where (1) and (2) are plastics and (3) are rubbers
Thermoplastic Polymers -Thermoplastics
Solid materials at room temperature but viscous liquids
when heated to temperatures of only a few hundred
degrees
This characteristic allows them to be easily and
economically shaped into products
They can be subjected to heating and cooling cycles
repeatedly without significant degradation
Symbolized by TP
Solid materials at room temperature but viscous liquids
when heated to temperatures of only a few hundred
degrees
This characteristic allows them to be easily and
economically shaped into products
They can be subjected to heating and cooling cycles
repeatedly without significant degradation
Symbolized by TP
Thermosetting Polymers -Thermosets
Cannot tolerate repeated heating cycles as
thermoplastics can
When initially heated, they soften and flow for
molding
Elevated temperatures also produce a chemical
reaction that hardens the material into an
infusible solid
If reheated, thermosets degrade and char rather
than soften
Symbolized by TS
Cannot tolerate repeated heating cycles as
thermoplastics can
When initially heated, they soften and flow for
molding
Elevated temperatures also produce a chemical
reaction that hardens the material into an
infusible solid
If reheated, thermosets degrade and char rather
than soften
Symbolized by TS
Elastomers (Rubbers)
Polymers that exhibit extreme elastic extensibility when
subjected to relatively low mechanical stress
Some elastomers can be stretched by a factor of 10
and yet completely recover to their original shape
Although their properties are quite different from
thermosets, they share a similar molecular structure
that is different from the thermoplastics
Polymers that exhibit extreme elastic extensibility when
subjected to relatively low mechanical stress
Some elastomers can be stretched by a factor of 10
and yet completely recover to their original shape
Although their properties are quite different from
thermosets, they share a similar molecular structure
that is different from the thermoplastics
Market Shares
Thermoplastics are commercially the most important
of the three types
About 70% of the tonnage of all synthetic
polymers produced
Thermosets and elastomers share the remaining
30%
On a volumetric basis, the current annual usage of
polymers exceeds that of metals
Thermoplastics are commercially the most important
of the three types
About 70% of the tonnage of all synthetic
polymers produced
Thermosets and elastomers share the remaining
30%
On a volumetric basis, the current annual usage of
polymers exceeds that of metals
Examples of Polymers
Thermoplastics:
Polyethylene, polyvinylchloride, polypropylene,
polystyrene, and nylon
Thermosets:
Phenolics, epoxies, and certain polyesters
Elastomers:
Natural rubber (vulcanized)
Synthetic rubbers, which exceed the tonnage of
natural rubber
Thermoplastics:
Polyethylene, polyvinylchloride, polypropylene,
polystyrene, and nylon
Thermosets:
Phenolics, epoxies, and certain polyesters
Elastomers:
Natural rubber (vulcanized)
Synthetic rubbers, which exceed the tonnage of
natural rubber
Reasons Why Polymers are Important
Plastics can be molded into intricate part shapes,
usually with no further processing
Very compatible with net shapeprocessing
On a volumetric basis, polymers:
Are cost competitive with metals
Generally, require less energy to produce than
metals
Certain plastics are transparent, which makes them
competitive with glass in some applications
Plastics can be molded into intricate part shapes,
usually with no further processing
Very compatible with net shapeprocessing
On a volumetric basis, polymers:
Are cost competitive with metals
Generally, require less energy to produce than
metals
Certain plastics are transparent, which makes them
competitive with glass in some applications
General Properties of Polymers
Low density relative to metals and ceramics
Good strength-to-weight ratios for certain (but not all)
polymers
High corrosion resistance
Low electrical and thermal conductivity
Low density relative to metals and ceramics
Good strength-to-weight ratios for certain (but not all)
polymers
High corrosion resistance
Low electrical and thermal conductivity
Limitations of Polymers
Low strength relative to metals and ceramics
Low modulus of elasticity (stiffness)
Service temperatures are limited to only a few
hundred degrees
Viscoelastic properties, which can be a distinct
limitation in load-bearing applications
Some polymers degrade when subjected to sunlight
and other forms of radiation
Low strength relative to metals and ceramics
Low modulus of elasticity (stiffness)
Service temperatures are limited to only a few
hundred degrees
Viscoelastic properties, which can be a distinct
limitation in load-bearing applications
Some polymers degrade when subjected to sunlight
and other forms of radiation
Synthesis of Polymers
Nearly all polymers used in engineering are synthetic
They are made by chemical processing
Polymers are synthesized by joining many small
molecules together into very large molecules, called
macromolecules, that possess a chain-like structure
The small units, called monomers, are generally
simple unsaturated organic molecules such as
ethylene C
2
H
4
Nearly all polymers used in engineering are synthetic
They are made by chemical processing
Polymers are synthesized by joining many small
molecules together into very large molecules, called
macromolecules, that possess a chain-like structure
The small units, called monomers, are generally
simple unsaturated organic molecules such as
ethylene C
2
H
4
Polyethylene
Synthesis of polyethylene from ethylene monomers:
(1) n ethylene monomers, (2a) polyethylene of chain
length n; (2b) concise notation for depicting polymer
structure of chain length n
Synthesis of polyethylene from ethylene monomers:
(1) n ethylene monomers, (2a) polyethylene of chain
length n; (2b) concise notation for depicting polymer
structure of chain length n
Polymerization
As a chemical process, the synthesis of polymers
can occur by either of two methods:
1.Addition polymerization
2.Step polymerization
Production of a given polymer is generally
associated with one method or the other
As a chemical process, the synthesis of polymers
can occur by either of two methods:
1.Addition polymerization
2.Step polymerization
Production of a given polymer is generally
associated with one method or the other
Addition Polymerization
In this process, the double bonds between carbon
atoms in the ethylene monomers are induced to open
up so they can join with other monomer molecules
The connections occur on both ends of the
expanding macromolecule, developing long chains of
repeating mers
It is initiated using a chemical catalyst to open the
carbon double bond in some of the monomers
In this process, the double bonds between carbon
atoms in the ethylene monomers are induced to open
up so they can join with other monomer molecules
The connections occur on both ends of the
expanding macromolecule, developing long chains of
repeating mers
It is initiated using a chemical catalyst to open the
carbon double bond in some of the monomers
Addition Polymerization
Model of addition (chain) polymerization: (1) initiation,
(2) rapid addition of monomers, and (3) resulting long
chain polymer molecule with nmers at termination of
reaction
Model of addition (chain) polymerization: (1) initiation,
(2) rapid addition of monomers, and (3) resulting long
chain polymer molecule with nmers at termination of
reaction
Step Polymerization
In this form of polymerization, two reacting monomers
are brought together to form a new molecule of the
desired compound
As reaction continues, more reactant molecules
combine with the molecules first synthesized to form
polymers of length n= 2, then length n= 3, and so on
In addition, polymers of length n
1
and n
2
also
combine to form molecules of length n= n
1
+ n
2
, so
that two types of reactions are proceeding
simultaneously
In this form of polymerization, two reacting monomers
are brought together to form a new molecule of the
desired compound
As reaction continues, more reactant molecules
combine with the molecules first synthesized to form
polymers of length n= 2, then length n= 3, and so on
In addition, polymers of length n
1
and n
2
also
combine to form molecules of length n= n
1
+ n
2
, so
that two types of reactions are proceeding
simultaneously
Step Polymerization
Model of step polymerization showing the two types
of reactions occurring: (left) n-mer attaching a single
monomer to form a (n+1)-mer; and (right) n
1-mer
combining with n
2-mer to form a (n
1+n
2)-mer.
Model of step polymerization showing the two types
of reactions occurring: (left) n-mer attaching a single
monomer to form a (n+1)-mer; and (right) n
1-mer
combining with n
2-mer to form a (n
1+n
2)-mer.
Some Examples
Polymers produced by addition polymerization:
Polyethylene, polypropylene, polyvinylchloride,
polyisoprene
Polymers produced by step polymerization:
Nylon, polycarbonate, phenol formaldehyde
Polymers produced by addition polymerization:
Polyethylene, polypropylene, polyvinylchloride,
polyisoprene
Polymers produced by step polymerization:
Nylon, polycarbonate, phenol formaldehyde
Degree of Polymerization
Since molecules in a given batch of polymerized
material vary in length, nfor the batch is an average
The mean value of nis called the degree of
polymerization(DP) for the batch
DP affects the properties of the polymer
Higher DP increases mechanical strength but also
increases viscosity in the fluid state, which makes
processing more difficult
Since molecules in a given batch of polymerized
material vary in length, nfor the batch is an average
The mean value of nis called the degree of
polymerization(DP) for the batch
DP affects the properties of the polymer
Higher DP increases mechanical strength but also
increases viscosity in the fluid state, which makes
processing more difficult
Molecular Weight
The sum of the molecular weights of the monomers
in the molecule
MW = ntimes the molecular weight of each
repeating unit
Since nvaries for different molecules in a batch,
the molecular weight must be interpreted as an
average
The sum of the molecular weights of the monomers
in the molecule
MW = ntimes the molecular weight of each
repeating unit
Since nvaries for different molecules in a batch,
the molecular weight must be interpreted as an
average
Typical Values of DP and MW
Polymer
Polyethylene
Polyvinylchloride
Nylon
Polycarbonate
DP(n)
10,000
1,500
120
200
MW
300,000
100,000
15,000
40,000
Polymer
Polyethylene
Polyvinylchloride
Nylon
Polycarbonate
DP(n)
10,000
1,500
120
200
MW
300,000
100,000
15,000
40,000
Polymer Molecular Structures
Linear structure –chain-like structure
Characteristic of thermoplastic polymers
Branched structure –chain-like but with side
branches
Also found in thermoplastic polymers
Cross-linked structure
Loosely cross-linked, characteristic of
elastomers
Tightly cross-linked, characteristic of thermosets
Linear structure –chain-like structure
Characteristic of thermoplastic polymers
Branched structure –chain-like but with side
branches
Also found in thermoplastic polymers
Cross-linked structure
Loosely cross-linked, characteristic of
elastomers
Tightly cross-linked, characteristic of thermosets
Polymer Molecular Structures
Linear
Branched
Loosely cross-linked Tightly cross-linked
Linear
Branched
Loosely cross-linked Tightly cross-linked
Effect of Branching on Properties
Thermoplastic polymers always possess linear or
branched structures or a mixture of the two
Branches increases entanglement among the
molecules, which makes the polymer
Stronger in the solid state
More viscous at a given temperature in the
plastic or liquid state
Thermoplastic polymers always possess linear or
branched structures or a mixture of the two
Branches increases entanglement among the
molecules, which makes the polymer
Stronger in the solid state
More viscous at a given temperature in the
plastic or liquid state
Effect of Cross-Linking on Properties
Thermosets possess a high degree of cross-linking;
elastomers possess a low degree of cross-linking
Thermosets are hard and brittle, while elastomers are
elastic and resilient
Cross-linking causes the polymer to become
chemically set
The reaction cannot be reversed
The polymer structure is permanently changed;
if heated, it degrades or burns rather than melt
Thermosets possess a high degree of cross-linking;
elastomers possess a low degree of cross-linking
Thermosets are hard and brittle, while elastomers are
elastic and resilient
Cross-linking causes the polymer to become
chemically set
The reaction cannot be reversed
The polymer structure is permanently changed;
if heated, it degrades or burns rather than melt
Crystallinity in Polymers
Both amorphous and crystalline structures are
possible, although the tendency to crystallize is much
less than for metals or non-glass ceramics
Not all polymers can form crystals
For those that can, the degree of crystallinity(the
proportion of crystallized material in the mass) is
always less than 100%
Both amorphous and crystalline structures are
possible, although the tendency to crystallize is much
less than for metals or non-glass ceramics
Not all polymers can form crystals
For those that can, the degree of crystallinity(the
proportion of crystallized material in the mass) is
always less than 100%
Crystalline Polymer Structure
Crystallized regions in a polymer: (a) long molecules
forming crystals randomly mixed in with the
amorphous material; and (b) folded chain lamella, the
typical form of a crystallized region
Crystallized regions in a polymer: (a) long molecules
forming crystals randomly mixed in with the
amorphous material; and (b) folded chain lamella, the
typical form of a crystallized region
Crystallinity and Properties
As crystallinity is increased in a polymer
Density increases
Stiffness, strength, and toughness increases
Heat resistance increases
If the polymer is transparent in the amorphous
state, it becomes opaque when partially
crystallized
As crystallinity is increased in a polymer
Density increases
Stiffness, strength, and toughness increases
Heat resistance increases
If the polymer is transparent in the amorphous
state, it becomes opaque when partially
crystallized
Low Density & High-Density Polyethylene
Polyethylene type Low density High density
Degree of crystallinity 55% 92%
Specific gravity 0.92 0.96
Modulus of elasticity 140 MPa
(20,000 lb/in
2
)
700 MPa
(100,000 lb/in
2
)
Melting temperature 115C
(239F)
135C
(275F)
Polyethylene type Low density High density
Degree of crystallinity 55% 92%
Specific gravity 0.92 0.96
Modulus of elasticity 140 MPa
(20,000 lb/in
2
)
700 MPa
(100,000 lb/in
2
)
Melting temperature 115C
(239F)
135C
(275F)
Some Observations About Crystallization
Linear polymers consist of long molecules with
thousands of repeated mers
Crystallization involves folding back and forth of the
long chains upon themselves
The crystallized regions are called crystallites
Crystallites take the form of lamellae randomly mixed in
with amorphous material
A crystallized polymer is a two-phase system
Crystallites interspersed in an amorphous matrix
Linear polymers consist of long molecules with
thousands of repeated mers
Crystallization involves folding back and forth of the
long chains upon themselves
The crystallized regions are called crystallites
Crystallites take the form of lamellae randomly mixed in
with amorphous material
A crystallized polymer is a two-phase system
Crystallites interspersed in an amorphous matrix
Factors for Crystallization
Slower cooling promotes crystal formation and
growth
Mechanical deformation, as in the stretching of a
heated thermoplastic, tends to align the structure and
increase crystallization
Plasticizers (chemicals added to a polymer to soften
it) reduce crystallinity
Slower cooling promotes crystal formation and
growth
Mechanical deformation, as in the stretching of a
heated thermoplastic, tends to align the structure and
increase crystallization
Plasticizers (chemicals added to a polymer to soften
it) reduce crystallinity
Thermal Behavior of Polymers
Specific volume
(density)
-1
as a
function of
temperature
Specific volume
(density)
-1
as a
function of
temperature
Additives
Properties of a polymer can often be beneficially
changed by combining it with additives
Additives either alter the molecular structure or
Add a second phase, in effect transforming the
polymer into a composite material
Properties of a polymer can often be beneficially
changed by combining it with additives
Additives either alter the molecular structure or
Add a second phase, in effect transforming the
polymer into a composite material
Types of Additives by Function
Fillers –strengthen polymer or reduce cost
Plasticizers –soften polymer and improve flow
Colorants –pigments or dyes
Lubricants –reduce friction and improve flow
Flame retardents –reduce flammability of polymer
Cross-linking agents –for thermosets and elastomers
Ultraviolet light absorbers –reduce degradation from
sunlight
Antioxidants –reduce oxidation damage
Fillers –strengthen polymer or reduce cost
Plasticizers –soften polymer and improve flow
Colorants –pigments or dyes
Lubricants –reduce friction and improve flow
Flame retardents –reduce flammability of polymer
Cross-linking agents –for thermosets and elastomers
Ultraviolet light absorbers –reduce degradation from
sunlight
Antioxidants –reduce oxidation damage
Thermoplastic Polymers (TP)
Thermoplastic polymers can be heated from solid state
to viscous liquid and then cooled back down to solid
Heating and cooling can be repeated many times
without degrading the polymer
Reason: TP polymers consist of linear and/or
branched macromolecules that do not cross-link
upon heating
Thermosets and elastomers change chemically when
heated, which cross-links their molecules and
permanently sets these polymers
Thermoplastic polymers can be heated from solid state
to viscous liquid and then cooled back down to solid
Heating and cooling can be repeated many times
without degrading the polymer
Reason: TP polymers consist of linear and/or
branched macromolecules that do not cross-link
upon heating
Thermosets and elastomers change chemically when
heated, which cross-links their molecules and
permanently sets these polymers
Mechanical Properties of Thermoplastics
Low modulus of elasticity (stiffness)
Eis much lower than metals and ceramics
Low tensile strength
TSis about 10% of metal
Much lower hardness than metals or ceramics
Greater ductility on average
Tremendous range of values, from 1% elongation
for polystyrene to 500% or more for polypropylene
Low modulus of elasticity (stiffness)
Eis much lower than metals and ceramics
Low tensile strength
TSis about 10% of metal
Much lower hardness than metals or ceramics
Greater ductility on average
Tremendous range of values, from 1% elongation
for polystyrene to 500% or more for polypropylene
Strength vs. Temperature
Deformation
resistance
(strength) of
polymers as a
function of
temperature
Deformation
resistance
(strength) of
polymers as a
function of
temperature
Physical Properties of Thermoplastics
Lower densities than metals or ceramics
Typical specific gravity for polymers are 1.2
(compared to ceramics (~ 2.5) and metals (~ 7)
Much higher coefficient of thermal expansion
Roughly five times the value for metals and 10
times the value for ceramics
Much lower melting temperatures
Insulating electrical properties
Lower densities than metals or ceramics
Typical specific gravity for polymers are 1.2
(compared to ceramics (~ 2.5) and metals (~ 7)
Much higher coefficient of thermal expansion
Roughly five times the value for metals and 10
times the value for ceramics
Much lower melting temperatures
Insulating electrical properties
Commercial Thermoplastic
Products and Raw Materials
Thermoplastic products include
Molded and extruded items
Fibers and filaments
Films and sheets
Packaging materials
Paints and varnishes
Starting plastic materials are normally supplied to the
fabricator in the form of powders or pellets in bags,
drums, or larger loads by truck or rail car
Products and Raw Materials
Thermoplastic products include
Molded and extruded items
Fibers and filaments
Films and sheets
Packaging materials
Paints and varnishes
Starting plastic materials are normally supplied to the
fabricator in the form of powders or pellets in bags,
drums, or larger loads by truck or rail car
Thermosetting Polymers (TS)
TS polymers are distinguished by their highly
cross-linked three-dimensional, covalently-bonded
structure
Chemical reactions associated with cross-linking are
called curingor setting
In effect, formed part (e.g., pot handle, electrical
switch cover, etc.) becomes a large macromolecule
Always amorphous and exhibits no glass transition
temperature
TS polymers are distinguished by their highly
cross-linked three-dimensional, covalently-bonded
structure
Chemical reactions associated with cross-linking are
called curingor setting
In effect, formed part (e.g., pot handle, electrical
switch cover, etc.) becomes a large macromolecule
Always amorphous and exhibits no glass transition
temperature
General Properties of Thermosets
Rigid -modulus of elasticity is two to three times
greater than thermoplastics
Brittle, virtually no ductility
Less soluble in common solvents than thermoplastics
Capable of higher service temperatures than
thermoplastics
Cannot be remelted -instead they degrade or burn
Rigid -modulus of elasticity is two to three times
greater than thermoplastics
Brittle, virtually no ductility
Less soluble in common solvents than thermoplastics
Capable of higher service temperatures than
thermoplastics
Cannot be remelted -instead they degrade or burn
Cross-Linking in TS Polymers
Three categories:
1.Temperature-activated systems
2.Catalyst-activated systems
3.Mixing-activated systems
Curing is accomplished at the fabrication plants that
make the parts rather than the chemical plants that
supply the starting materials to the fabricator
Three categories:
1.Temperature-activated systems
2.Catalyst-activated systems
3.Mixing-activated systems
Curing is accomplished at the fabrication plants that
make the parts rather than the chemical plants that
supply the starting materials to the fabricator
Temperature-Activated Systems
Curing caused by heat supplied during part shaping
operation (e.g., molding)
Starting material is a linear polymer in granular form
supplied by the chemical plant
As heat is added, material softens for molding,
but continued heating causes cross-linking
Most common TS systems
The term “thermoset" applies best to these
polymers
Curing caused by heat supplied during part shaping
operation (e.g., molding)
Starting material is a linear polymer in granular form
supplied by the chemical plant
As heat is added, material softens for molding,
but continued heating causes cross-linking
Most common TS systems
The term “thermoset" applies best to these
polymers
Catalyst-Activated Systems
Cross-linking occurs when small amounts of a catalyst
are added to the polymer, which is in liquid form
Without the catalyst, the polymer remains stable and
liquid
Once combined with the catalyst it cures and
changes into solid form
Cross-linking occurs when small amounts of a catalyst
are added to the polymer, which is in liquid form
Without the catalyst, the polymer remains stable and
liquid
Once combined with the catalyst it cures and
changes into solid form
Mixing-Activated Systems
Mixing of two chemicals results in a reaction that forms
a cross-linked solid polymer
Elevated temperatures are sometimes used to
accelerate the reactions
Most epoxies are examples of these systems
Mixing of two chemicals results in a reaction that forms
a cross-linked solid polymer
Elevated temperatures are sometimes used to
accelerate the reactions
Most epoxies are examples of these systems
TS vs. TP Polymers
TS plastics are not as widely used as the TP
One reason is the added processing costs and
complications involved in curing
Largest market share of TS = phenolic resins with
6% of the total plastics market
Compare polyethylene with 35% market share
TS Products: countertops, plywood adhesives,
paints, molded parts, printed circuit boards and other
fiber reinforced plastics
TS plastics are not as widely used as the TP
One reason is the added processing costs and
complications involved in curing
Largest market share of TS = phenolic resins with
6% of the total plastics market
Compare polyethylene with 35% market share
TS Products: countertops, plywood adhesives,
paints, molded parts, printed circuit boards and other
fiber reinforced plastics
Elastomers
Polymers capable of large elastic deformation when
subjected to relatively low stresses
Some can be extended 500% or more and still
return to their original shape
Two categories:
1.Natural rubber -derived from biological plants
2.Synthetic polymers -produced by
polymerization processes like those used for
thermoplastic and thermosetting polymers
Polymers capable of large elastic deformation when
subjected to relatively low stresses
Some can be extended 500% or more and still
return to their original shape
Two categories:
1.Natural rubber -derived from biological plants
2.Synthetic polymers -produced by
polymerization processes like those used for
thermoplastic and thermosetting polymers
Characteristics of Elastomers
Elastomers consist of long-chain molecules that are
cross-linked (like thermosetting polymers)
They owe their impressive elastic properties to two
features:
1.Molecules are tightly kinked when unstretched
2.Degree of cross-linking is substantially less
than thermosets
Elastomers consist of long-chain molecules that are
cross-linked (like thermosetting polymers)
They owe their impressive elastic properties to two
features:
1.Molecules are tightly kinked when unstretched
2.Degree of cross-linking is substantially less
than thermosets
Elastomer Molecules
Model of long elastomer molecules, with low degree
of cross-linking: (left) unstretched, and (right) under
tensile stress
Model of long elastomer molecules, with low degree
of cross-linking: (left) unstretched, and (right) under
tensile stress
Elastic Behavior of Elastomer Molecule
When stretched, the molecules are forced to uncoil
and straighten
Natural resistance to uncoiling provides the initial
elastic modulus of the aggregate material
Under further strain, the covalent bonds of the
cross-linked molecules begin to play an increasing
role in the modulus, and stiffness increases
With greater cross-linking, the elastomer becomes
stiffer, and its modulus of elasticity is more linear
When stretched, the molecules are forced to uncoil
and straighten
Natural resistance to uncoiling provides the initial
elastic modulus of the aggregate material
Under further strain, the covalent bonds of the
cross-linked molecules begin to play an increasing
role in the modulus, and stiffness increases
With greater cross-linking, the elastomer becomes
stiffer, and its modulus of elasticity is more linear
Stiffness of Rubber
Increase in stiffness as a function of strain for three
grades of rubber: natural rubber, vulcanized rubber,
and hard rubber
Increase in stiffness as a function of strain for three
grades of rubber: natural rubber, vulcanized rubber,
and hard rubber
Vulcanization
Curing to cross-link most elastomers
Vulcanization= the term for curing in the context of
natural rubber (and certain synthetic rubbers)
Typical cross-linking in rubber is one to ten links per
hundred carbon atoms in the linear polymer chain,
depending on degree of stiffness desired
Considerably less than cross-linking in
thermosets
Curing to cross-link most elastomers
Vulcanization= the term for curing in the context of
natural rubber (and certain synthetic rubbers)
Typical cross-linking in rubber is one to ten links per
hundred carbon atoms in the linear polymer chain,
depending on degree of stiffness desired
Considerably less than cross-linking in
thermosets
Natural Rubber (NR)
NR = polyisoprene, a high molecular-weight polymer
of isoprene (C
5H
8)
It is derived from latex, a milky substance produced
by various plants, most important of which is the
rubber tree that grows in tropical climates
Latex is a water emulsion of polyisoprene (about 1/3
by weight), plus various other ingredients
Rubber is extracted from latex by various methods
that remove the water
NR = polyisoprene, a high molecular-weight polymer
of isoprene (C
5H
8)
It is derived from latex, a milky substance produced
by various plants, most important of which is the
rubber tree that grows in tropical climates
Latex is a water emulsion of polyisoprene (about 1/3
by weight), plus various other ingredients
Rubber is extracted from latex by various methods
that remove the water
Vulcanized Natural Rubber
Properties: High tensile strength, tear strength,
resilience (capacity to recover shape), and resistance
to wear and fatigue
Weaknesses: degrades when subjected to heat,
sunlight, oxygen, ozone, and oil
Some of these limitations can be reduced by
additives
Market share of NR 22% of total rubber volume
(natural plus synthetic)
Properties: High tensile strength, tear strength,
resilience (capacity to recover shape), and resistance
to wear and fatigue
Weaknesses: degrades when subjected to heat,
sunlight, oxygen, ozone, and oil
Some of these limitations can be reduced by
additives
Market share of NR 22% of total rubber volume
(natural plus synthetic)
Natural Rubber Products
Largest single market for NR is automotive tires
Other products: shoe soles, bushings, seals, and
shock absorbing components
In tires, carbon blackis an important additive
It reinforces the rubber, serving to increase tensile
strength and resistance to tear and abrasion
Other additives: clay, kaolin, silica, talc, and calcium
carbonate, as well as chemicals that accelerate and
promote vulcanization
Largest single market for NR is automotive tires
Other products: shoe soles, bushings, seals, and
shock absorbing components
In tires, carbon blackis an important additive
It reinforces the rubber, serving to increase tensile
strength and resistance to tear and abrasion
Other additives: clay, kaolin, silica, talc, and calcium
carbonate, as well as chemicals that accelerate and
promote vulcanization
Synthetic Rubbers
Development of synthetic rubbers was motivated
largely by world wars when NR was difficult to obtain
Tonnage of synthetic rubbers is now more than three
times that of NR
The most important synthetic rubber is
styrene-butadiene rubber (SBR), a copolymer of
butadiene (C
4H
6) and styrene (C
8H
8)
As with most other polymers, the main raw material
for synthetic rubbers is petroleum
Development of synthetic rubbers was motivated
largely by world wars when NR was difficult to obtain
Tonnage of synthetic rubbers is now more than three
times that of NR
The most important synthetic rubber is
styrene-butadiene rubber (SBR), a copolymer of
butadiene (C
4H
6) and styrene (C
8H
8)
As with most other polymers, the main raw material
for synthetic rubbers is petroleum
Thermoplastic Elastomers (TPE)
A thermoplastic that behaves like an elastomer
Elastomeric properties not from chemical cross-links,
but from physical connections between soft and hard
phases in the material
Cannot match conventional elastomers in elevated
temperature, strength and creep resistance
Products: footwear; rubber bands; extruded tubing,
wire coating; molded automotive parts, but no tires
A thermoplastic that behaves like an elastomer
Elastomeric properties not from chemical cross-links,
but from physical connections between soft and hard
phases in the material
Cannot match conventional elastomers in elevated
temperature, strength and creep resistance
Products: footwear; rubber bands; extruded tubing,
wire coating; molded automotive parts, but no tires
COMPOSITE MATERIALS
1.Technology and Classification of Composite
Materials
2.Metal Matrix Composites
3.Ceramic Matrix Composites
4.Polymer Matrix Composites
5.Guide to Processing Composite Materials
1.Technology and Classification of Composite
Materials
2.Metal Matrix Composites
3.Ceramic Matrix Composites
4.Polymer Matrix Composites
5.Guide to Processing Composite Materials
Composite Material Defined
A materials system composed of two or more distinct
phases whose combination produces aggregate
properties different from those of its constituents
Examples:
Cemented carbides
Plastic molding compounds with fillers
Rubber mixed with carbon black
Wood (a natural composite as distinguished from
a synthesized composite)
A materials system composed of two or more distinct
phases whose combination produces aggregate
properties different from those of its constituents
Examples:
Cemented carbides
Plastic molding compounds with fillers
Rubber mixed with carbon black
Wood (a natural composite as distinguished from
a synthesized composite)
Why Composites are Important
Composites can be very strong and stiff, yet very light in
weight
Strength-to-weight and stiffness-to-weight ratios
are several times greater than steel or aluminum
Fatigue properties are generally better than for common
engineering metals
Toughness is often greater
Possible to achieve combinations of properties not
attainable with metals, ceramics, or polymers alone
Composites can be very strong and stiff, yet very light in
weight
Strength-to-weight and stiffness-to-weight ratios
are several times greater than steel or aluminum
Fatigue properties are generally better than for common
engineering metals
Toughness is often greater
Possible to achieve combinations of properties not
attainable with metals, ceramics, or polymers alone
Disadvantages and Limitations
Properties of many important composites are
anisotropic
May be an advantage or a disadvantage
Many polymer-based composites are subject to attack
by chemicals or solvents
Just as the polymers themselves are susceptible
Composite materials are generally expensive
Manufacturing methods for shaping composite materials
are often slow and costly
Properties of many important composites are
anisotropic
May be an advantage or a disadvantage
Many polymer-based composites are subject to attack
by chemicals or solvents
Just as the polymers themselves are susceptible
Composite materials are generally expensive
Manufacturing methods for shaping composite materials
are often slow and costly
Possible Classification of Composites
1.Traditional composites –composite materials that
occur in nature or have been produced by
civilizations for many years
Examples: wood, concrete, asphalt
2.Synthetic composites -modern material systems
normally associated with the manufacturing
industries
Components are first produced separately and
then combined to achieve the desired
structure, properties, and part geometry
1.Traditional composites –composite materials that
occur in nature or have been produced by
civilizations for many years
Examples: wood, concrete, asphalt
2.Synthetic composites -modern material systems
normally associated with the manufacturing
industries
Components are first produced separately and
then combined to achieve the desired
structure, properties, and part geometry
Components in a Composite Material
Most composite materials consist of two phases:
1.Primary phase -forms the matrixwithin which the
secondary phase is imbedded
2.Secondary phase -imbedded phase sometimes
referred to as a reinforcingagent, because it usually
strengthens the composite material
The reinforcing phase may be in the form of
fibers, particles, or various other geometries
Most composite materials consist of two phases:
1.Primary phase -forms the matrixwithin which the
secondary phase is imbedded
2.Secondary phase -imbedded phase sometimes
referred to as a reinforcingagent, because it usually
strengthens the composite material
The reinforcing phase may be in the form of
fibers, particles, or various other geometries
Classification of Composite Materials
1.Metal Matrix Composites (MMCs) -mixtures of
ceramics and metals, such as cemented carbides
2.Ceramic Matrix Composites (CMCs) -Al
2O
3and SiC
imbedded with fibers to improve properties
3.Polymer Matrix Composites (PMCs) -polymer resins
imbedded with filler or reinforcing agent
Examples: epoxy and polyester with fiber
reinforcement, and phenolic with powders
1.Metal Matrix Composites (MMCs) -mixtures of
ceramics and metals, such as cemented carbides
2.Ceramic Matrix Composites (CMCs) -Al
2O
3and SiC
imbedded with fibers to improve properties
3.Polymer Matrix Composites (PMCs) -polymer resins
imbedded with filler or reinforcing agent
Examples: epoxy and polyester with fiber
reinforcement, and phenolic with powders
Functions of the Matrix Material
Primary phase provides the bulk form of the part or
product made of the composite material
Holds the imbedded phase in place, usually
enclosing and often concealing it
When a load is applied, the matrix shares the load
with the secondary phase, in some cases deforming
so that the stress is essentially born by the
reinforcing agent
Primary phase provides the bulk form of the part or
product made of the composite material
Holds the imbedded phase in place, usually
enclosing and often concealing it
When a load is applied, the matrix shares the load
with the secondary phase, in some cases deforming
so that the stress is essentially born by the
reinforcing agent
Reinforcing Phase
Function is to reinforce the primary phase
Reinforcing phase (imbedded in the matrix) is most
commonly one of the following shapes: fibers,
particles, or flakes
Function is to reinforce the primary phase
Reinforcing phase (imbedded in the matrix) is most
commonly one of the following shapes: fibers,
particles, or flakes
Physical Shapes of Imbedded Phase
Possible physical shapes of imbedded phases in
composite materials: (a) fiber, (b) particle, and (c)
flake
Possible physical shapes of imbedded phases in
composite materials: (a) fiber, (b) particle, and (c)
flake
Fibers
Filaments of reinforcing material, usually circular in
cross section
Diameters from ~ 0.0025 mm to about 0.13 mm
Filaments provide greatest opportunity for strength
enhancement of composites
Filament form of most materials is significantly
stronger than the bulk form
As diameter is reduced, the material becomes
oriented in the fiber axis direction and probability
of defects in the structure decreases significantly
Filaments of reinforcing material, usually circular in
cross section
Diameters from ~ 0.0025 mm to about 0.13 mm
Filaments provide greatest opportunity for strength
enhancement of composites
Filament form of most materials is significantly
stronger than the bulk form
As diameter is reduced, the material becomes
oriented in the fiber axis direction and probability
of defects in the structure decreases significantly
Continuous Fibers vs.
Discontinuous Fibers
Continuous fibers -very long; in theory, they offer a
continuous path by which a load can be carried by
the composite part
Discontinuous fibers (chopped sections of continuous
fibers) -short lengths (L/D = roughly 100)
Whiskers= discontinuous fibers of hair-like
single crystals with diameters down to about
0.001 mm (0.00004 in) and very high strength
Discontinuous Fibers
Continuous fibers -very long; in theory, they offer a
continuous path by which a load can be carried by
the composite part
Discontinuous fibers (chopped sections of continuous
fibers) -short lengths (L/D = roughly 100)
Whiskers= discontinuous fibers of hair-like
single crystals with diameters down to about
0.001 mm (0.00004 in) and very high strength
Fiber Orientation –Three Cases
One-dimensional reinforcement, in which maximum
strength and stiffness are obtained in the direction of
the fiber
Planar reinforcement, in some cases in the form of a
two-dimensional woven fabric
Random or three-dimensional in which the composite
material tends to possess isotropic properties
One-dimensional reinforcement, in which maximum
strength and stiffness are obtained in the direction of
the fiber
Planar reinforcement, in some cases in the form of a
two-dimensional woven fabric
Random or three-dimensional in which the composite
material tends to possess isotropic properties
Fiber Orientation
Fiber orientation in composite materials: (a)
one-dimensional, continuous fibers; (b) planar,
continuous fibers in the form of a woven fabric; and (c)
random, discontinuous fibers
Fiber orientation in composite materials: (a)
one-dimensional, continuous fibers; (b) planar,
continuous fibers in the form of a woven fabric; and (c)
random, discontinuous fibers
Materials for Fibers
Fiber materials in fiber-reinforced composites
Glass –most widely used filament
Carbon –high elastic modulus
Boron –very high elastic modulus
Polymers -Kevlar
Ceramics –SiC and Al
2O
3
Metals -steel
Most important commercial use of fibers is in polymer
composites
Fiber materials in fiber-reinforced composites
Glass –most widely used filament
Carbon –high elastic modulus
Boron –very high elastic modulus
Polymers -Kevlar
Ceramics –SiC and Al
2O
3
Metals -steel
Most important commercial use of fibers is in polymer
composites
Particles and Flakes
A second common shape of imbedded phase is
particulate, ranging in size from microscopic to
macroscopic
Flakesare basically two-dimensional
particles -small flat platelets
Distribution of particles in the matrix is random
Strength and other properties of the composite
material are usually isotropic
A second common shape of imbedded phase is
particulate, ranging in size from microscopic to
macroscopic
Flakesare basically two-dimensional
particles -small flat platelets
Distribution of particles in the matrix is random
Strength and other properties of the composite
material are usually isotropic
Interface between Constituent Phases in
Composite Material
For the composite to function, the phases must bond
where they join at the interface
Direct bonding between primary and secondary phases
Composite Material
For the composite to function, the phases must bond
where they join at the interface
Direct bonding between primary and secondary phases
Interphase
In some cases, a third ingredient must be added to
bond primary and secondary phases
Called an interphase, it is like an adhesive
In some cases, a third ingredient must be added to
bond primary and secondary phases
Called an interphase, it is like an adhesive
Alternative Interphase Form
Formation of an interphase consisting of a solution of
primary and secondary phases at their boundary
Formation of an interphase consisting of a solution of
primary and secondary phases at their boundary
Properties of
Composite Materials
In selecting a composite material, an optimum
combination of properties is often sought, rather than
one particular property
Example: fuselage and wings of an aircraft must
be lightweight, strong, stiff, and tough
Several fiber-reinforced polymers possess
these properties
Example: natural rubber alone is relatively weak
Adding carbon black increases its strength
Composite Materials
In selecting a composite material, an optimum
combination of properties is often sought, rather than
one particular property
Example: fuselage and wings of an aircraft must
be lightweight, strong, stiff, and tough
Several fiber-reinforced polymers possess
these properties
Example: natural rubber alone is relatively weak
Adding carbon black increases its strength
Three Factors that Determine Properties
1.Materials used as component phasesin the
composite
2.Geometric shapes of the constituents and resulting
structure of the composite system
3.How the phases interact with one another
1.Materials used as component phasesin the
composite
2.Geometric shapes of the constituents and resulting
structure of the composite system
3.How the phases interact with one another
Example: Fiber Reinforced Polymer
Model of fiber-reinforced
composite material
showing direction in
which elastic modulus is
being estimated by the
rule of mixtures
Model of fiber-reinforced
composite material
showing direction in
which elastic modulus is
being estimated by the
rule of mixtures
Example: Fiber Reinforced Polymer
(continued)
Stress-strain relationships
for the composite material
and its constituents
The fiber is stiff but brittle,
while the matrix
(commonly a polymer) is
soft but ductile
(continued)
Stress-strain relationships
for the composite material
and its constituents
The fiber is stiff but brittle,
while the matrix
(commonly a polymer) is
soft but ductile
Variations in Strength and Stiffness
Variation in elastic modulus and tensile strength as
function of direction relative to longitudinal axis of
carbon fiber-reinforced epoxy composite
Variation in elastic modulus and tensile strength as
function of direction relative to longitudinal axis of
carbon fiber-reinforced epoxy composite
Importance of Geometric Shape: Fibers
Most materials have tensile strengths several times
greater as fibers than as bulk materials
By imbedding the fibers in a polymer matrix, a
composite material is obtained that avoids the
problems of fibers but utilizes their strengths
Matrix provides the bulk shape to protect the fiber
surfaces and resist buckling
When a load is applied, the low-strength matrix
deforms and distributes the stress to the
high-strength fibers
Most materials have tensile strengths several times
greater as fibers than as bulk materials
By imbedding the fibers in a polymer matrix, a
composite material is obtained that avoids the
problems of fibers but utilizes their strengths
Matrix provides the bulk shape to protect the fiber
surfaces and resist buckling
When a load is applied, the low-strength matrix
deforms and distributes the stress to the
high-strength fibers
Other Composite Structures
Laminar composite structure –conventional
Sandwich structure
Honeycomb sandwich structure
Laminar composite structure –conventional
Sandwich structure
Honeycomb sandwich structure
Laminar Composite Structure
Conventional laminar
structure -two or more
layers bonded together
in an integral piece
Example: plywood, in
which layers are the
same wood, but grains
oriented differently to
increase overall strength
Conventional laminar
structure -two or more
layers bonded together
in an integral piece
Example: plywood, in
which layers are the
same wood, but grains
oriented differently to
increase overall strength
Sandwich Structure: Foam Core
Relatively thick core of
low-density foam
bonded on both faces to
thin sheets of a different
material
Relatively thick core of
low-density foam
bonded on both faces to
thin sheets of a different
material
Sandwich Structure:
Honeycomb Core
Alternative to foam
core
Foam or
honeycomb achieve
high ratios of
strength-to-weight
and
stiffness-to-weight
Honeycomb Core
Alternative to foam
core
Foam or
honeycomb achieve
high ratios of
strength-to-weight
and
stiffness-to-weight
Other Laminar Composite Structures
FRPs -multi-layered, fiber-reinforced plastic panels for
aircraft, boat hulls, other products
Printed circuit boards -layers of reinforced copper and
plastic for electrical conductivity and insulation,
respectively
Snow skis -layers of metals, particle board, and
phenolic plastic
Windshield glass -two layers of glass on either side of
a sheet of tough plastic
FRPs -multi-layered, fiber-reinforced plastic panels for
aircraft, boat hulls, other products
Printed circuit boards -layers of reinforced copper and
plastic for electrical conductivity and insulation,
respectively
Snow skis -layers of metals, particle board, and
phenolic plastic
Windshield glass -two layers of glass on either side of
a sheet of tough plastic
Metal Matrix Composites (MMCs)
Metal matrix reinforced by a second phase
Reinforcing phases:
1.Particles of ceramic
These MMCs are commonly called cermets
2.Fibers of various materials
Other metals, ceramics, carbon, and boron
Metal matrix reinforced by a second phase
Reinforcing phases:
1.Particles of ceramic
These MMCs are commonly called cermets
2.Fibers of various materials
Other metals, ceramics, carbon, and boron
Cermets
MMC with ceramic contained in a metallic matrix
The ceramic often dominates the mixture, sometimes
up to 96% by volume
Bonding can be enhanced by slight solubility between
phases at elevated temperatures used in processing
Cermetscan be subdivided into
1.Cemented carbides –most common
2.Oxide-based cermets–less common
MMC with ceramic contained in a metallic matrix
The ceramic often dominates the mixture, sometimes
up to 96% by volume
Bonding can be enhanced by slight solubility between
phases at elevated temperatures used in processing
Cermetscan be subdivided into
1.Cemented carbides –most common
2.Oxide-based cermets–less common
Cemented Carbides
One or more carbide compounds bonded in a metallic
matrix
Common cemented carbides are based on tungsten
carbide (WC), titanium carbide (TiC), and chromium
carbide (Cr
3C
2)
Tantalum carbide (TaC) and others are less
common
Metallic binders: usually cobalt (Co) or nickel (Ni)
One or more carbide compounds bonded in a metallic
matrix
Common cemented carbides are based on tungsten
carbide (WC), titanium carbide (TiC), and chromium
carbide (Cr
3C
2)
Tantalum carbide (TaC) and others are less
common
Metallic binders: usually cobalt (Co) or nickel (Ni)
Photomicrograph (about 1500X) of cemented carbide
with 85% WC and 15% Co (photo courtesty of
Kennametal Inc.)
Cemented Carbide
with 85% WC and 15% Co (photo courtesty of
Kennametal Inc.)
Cemented Carbide
Typical plot of
hardness and
transverse
rupture strength
as a function of
cobalt content
Cemented Carbide Properties
hardness and
transverse
rupture strength
as a function of
cobalt content
Cemented Carbide Properties
Applications of
Cemented Carbides
Tungsten carbide cermets(Co binder)
Cutting tools, wire drawing dies, rock drilling bits,
powder metal dies, indenters for hardness testers
Titanium carbide cermets(Ni binder)
Cutting tools; high temperature applications such as
gas-turbine nozzle vanes
Chromium carbide cermets(Ni binder)
Gage blocks, valve liners, spray nozzles
Cemented Carbides
Tungsten carbide cermets(Co binder)
Cutting tools, wire drawing dies, rock drilling bits,
powder metal dies, indenters for hardness testers
Titanium carbide cermets(Ni binder)
Cutting tools; high temperature applications such as
gas-turbine nozzle vanes
Chromium carbide cermets(Ni binder)
Gage blocks, valve liners, spray nozzles
Ceramic Matrix Composites (CMCs)
Ceramic primary phase imbedded with a secondary
phase, usually consisting of fibers
Attractive properties of ceramics: high stiffness,
hardness, hot hardness, and compressive strength;
and relatively low density
Weaknesses of ceramics: low toughness and bulk
tensile strength, susceptibility to thermal cracking
CMCs represent an attempt to retain the desirable
properties of ceramics while compensating for their
weaknesses
Ceramic primary phase imbedded with a secondary
phase, usually consisting of fibers
Attractive properties of ceramics: high stiffness,
hardness, hot hardness, and compressive strength;
and relatively low density
Weaknesses of ceramics: low toughness and bulk
tensile strength, susceptibility to thermal cracking
CMCs represent an attempt to retain the desirable
properties of ceramics while compensating for their
weaknesses
Ceramic Matrix Composite
Photomicrograph (about 3000X) of fracture surface of
SiC whisker reinforced Al
2O
3(photo courtesy of
Greenleaf Corp.)
Photomicrograph (about 3000X) of fracture surface of
SiC whisker reinforced Al
2O
3(photo courtesy of
Greenleaf Corp.)
Polymer Matrix Composites (PMCs)
Polymer primary phase in which a secondary phase is
imbedded as fibers, particles, or flakes
Commercially, PMCs are more important than MMCs
or CMCs
Examples: most plastic molding compounds,
rubber reinforced with carbon black, and
fiber-reinforced polymers (FRPs)
Polymer primary phase in which a secondary phase is
imbedded as fibers, particles, or flakes
Commercially, PMCs are more important than MMCs
or CMCs
Examples: most plastic molding compounds,
rubber reinforced with carbon black, and
fiber-reinforced polymers (FRPs)
Fiber-Reinforced Polymers (FRPs)
PMC consisting of a polymer matrix imbedded with
high-strength fibers
Polymer matrix materials:
Usually, a thermosetting plastic such as
unsaturated polyester or epoxy
Can also be thermoplastic, such as nylons
(polyamides), polycarbonate, polystyrene, and
polyvinylchloride
Fiber reinforcement is widely used in rubber
products such as tires and conveyor belts
PMC consisting of a polymer matrix imbedded with
high-strength fibers
Polymer matrix materials:
Usually, a thermosetting plastic such as
unsaturated polyester or epoxy
Can also be thermoplastic, such as nylons
(polyamides), polycarbonate, polystyrene, and
polyvinylchloride
Fiber reinforcement is widely used in rubber
products such as tires and conveyor belts
Fibers in PMCs
Various forms: discontinuous (chopped), continuous,
or woven as a fabric
Principal fiber materials in FRPs are glass, carbon,
and Kevlar 49
Less common fibers include boron, SiC, and
Al
2O
3, and steel
Glass (in particular E-glass) is the most common fiber
material in today's FRPs
Its use to reinforce plastics dates from around
1920
Various forms: discontinuous (chopped), continuous,
or woven as a fabric
Principal fiber materials in FRPs are glass, carbon,
and Kevlar 49
Less common fibers include boron, SiC, and
Al
2O
3, and steel
Glass (in particular E-glass) is the most common fiber
material in today's FRPs
Its use to reinforce plastics dates from around
1920
Common FRP Structures
Most widely used form of FRP is a laminar structure
Made by stacking and bonding thin layers of fiber
and polymer until desired thickness is obtained
By varying fiber orientation among layers, a
specified level of anisotropy in properties can be
achieved in the laminate
Applications: boat hulls, aircraft wing and fuselage
sections, automobile and truck body panels
Most widely used form of FRP is a laminar structure
Made by stacking and bonding thin layers of fiber
and polymer until desired thickness is obtained
By varying fiber orientation among layers, a
specified level of anisotropy in properties can be
achieved in the laminate
Applications: boat hulls, aircraft wing and fuselage
sections, automobile and truck body panels
FRP Properties
High strength-to-weight and modulus-to-weight ratios
A typical FRP weighs only about 1/5 as much as
steel
Yet strength and modulus are comparable in fiber
direction
Good fatigue strength
Good corrosion resistance, although polymers are
soluble in various chemicals
Low thermal expansion for many FRPs
High strength-to-weight and modulus-to-weight ratios
A typical FRP weighs only about 1/5 as much as
steel
Yet strength and modulus are comparable in fiber
direction
Good fatigue strength
Good corrosion resistance, although polymers are
soluble in various chemicals
Low thermal expansion for many FRPs
FRP Applications
Aerospace –much of the structural weight of today’s
airplanes and helicopters consist of advanced FRPs
Example: Boeing 787
Automotive –some body panels for cars and truck cabs
Low-carbon sheet steel still widely used due to its
low cost and ease of processing
Sports and recreation
FRPs used for boat hulls since 1940s
Fishing rods, tennis rackets, golf club shafts,
helmets, skis, bows and arrows
Aerospace –much of the structural weight of today’s
airplanes and helicopters consist of advanced FRPs
Example: Boeing 787
Automotive –some body panels for cars and truck cabs
Low-carbon sheet steel still widely used due to its
low cost and ease of processing
Sports and recreation
FRPs used for boat hulls since 1940s
Fishing rods, tennis rackets, golf club shafts,
helmets, skis, bows and arrows
Other Polymer Matrix Composites
Other PMCs contain particles, flakes, and short fibers
Called fillers when used in molding compounds
Two categories:
1.Reinforcing fillers –used to strengthen or
otherwise improve mechanical properties
2.Extenders –used to increase bulk strength and
reduce cost per unit weight, with little or no effect
on mechanical properties
Other PMCs contain particles, flakes, and short fibers
Called fillers when used in molding compounds
Two categories:
1.Reinforcing fillers –used to strengthen or
otherwise improve mechanical properties
2.Extenders –used to increase bulk strength and
reduce cost per unit weight, with little or no effect
on mechanical properties
Guide to Processing Composite Materials
The two phases are typically produced separately
before being combined into the composite part
Processing techniques to fabricate MMC and
CMC components are similar to those used for
powdered metals and ceramics
Molding processes are commonly used for
PMCs with particles and chopped fibers
Specialized processes have been developed for
FRPs
The two phases are typically produced separately
before being combined into the composite part
Processing techniques to fabricate MMC and
CMC components are similar to those used for
powdered metals and ceramics
Molding processes are commonly used for
PMCs with particles and chopped fibers
Specialized processes have been developed for
FRPs
Guide to the
Processing of Polymers
Polymers are nearly always shaped in a heated,
highly plastic state
Common operations are extrusion and molding
Molding of thermosets is more complicated because
of cross-linking
Thermoplastics are easier to mold, and a greater
variety of molding operations are available
Rubber processing has a longer history than plastics,
and rubber industries are traditionally separated from
plastics industry, even though processing is similar
Processing of Polymers
Polymers are nearly always shaped in a heated,
highly plastic state
Common operations are extrusion and molding
Molding of thermosets is more complicated because
of cross-linking
Thermoplastics are easier to mold, and a greater
variety of molding operations are available
Rubber processing has a longer history than plastics,
and rubber industries are traditionally separated from
plastics industry, even though processing is similar
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