Materials

Plastics

What are Plastics

• Polymer– “Poly” – many– “mer” – unit– Many Units

• Carbon based, high molecular weight, versatile synthetic materials that are built up from monomeric units

How plastics are made

• Addition or Condensation Reaction

• Addition– A simple combining of molecules without

generating byproducts– Vinyls

• PE

• PP

• PS

Addition Reaction - Polyethylene

How plastics are made

• Condensation– Involves removing certain atoms from each

molecule, allowing the molecules to combine– Byproducts are generated that must be removed– Nylons– PC

Condensation Reaction - Polycarbonate

Types of Plastics

• Thermoplastic– Soften with heated, then solidify when cooled– Only physical changes

• Thermoset– Polymers that chemically react when heated to

form a cross-linked polymer chain network– Not reformable with heating

Thermoplastics

• Amorphous– Random Structure– Tg

– Polystyrene, Polycarbonate

• Semi-Crystalline– Organized Molecular Arrangement– Tg, Tm

– Polyethylene, Polypropylene

Crystallinity

Semi-crystalline Amorphous

Thermoplastics

• The ability of plastics to form crystals is largely dependent on the structure of the plastic molecule– Linear plastics with small side groups can form

crystalline regions– HDPE, LDPE, Acetals, Nylon and PET

Structure Property Relationship

• The Property of a Plastic Material formulation can be tailored to meet most end use applications

• The properties are dependent on– The chemical composition of the polymer– Additives

Structure Property Relationship

• Chemical Composition varies by– Structure of the repeat unit– Average molecular weight– Molecular weight distribution– Linear, branched or cross-linked

Structure Property Relationship

• PMMA and PS are very different in behavior and properties because their repeat units are different

Molecular Distribution

Structure Property Relationship

• Number-Average Molecular Weight (Mn)

– Mn = NiMi Ni

• where Ni is the number of molecules of the ith species of molecular weight Mi.

– Measured from colligative properties such as:• freezing point depression for low molecular weight

• osmotic pressure for higher molecular weight

• gel permeation or size exclusion chromatography

Structure Property Relationship

• Weight-Average Molecular Weight (MW)

– MW= NiMi2NiMi

• where Ni is the number of molecules of the ith species of molecular weight Mi.

– Measured using techniques such as:• light scattering

• gel permeation or size exclusion chromatography.

Structure Property Relationship

• Polydispersity(MWD) = MW / Mn

– A measure of the distribution of molecular weights of polymer chains.

Effect of Mw on Viscosity

• Low shear – lots of entanglements, Mw has direct effect on viscosity

• Medium shear – reduced entanglements Mw has less effect on viscosity

• High shear – few entanglements, Mw has no effect on viscosity

Low Shear

Medium Shear

High Shear

Log shear rate

Log

Log

Effects of MWD on Viscosity

Narrow MWD

Broad MWD

Viscosity

Shear Rate

Structure Property Relationship

• Additives– Used to enhance specific properties

• Combustion modifiers

• Release agents

• Blowing Agents

• UV stabilizers

• Fillers

• Reinforcements

• Colors

– Additives are like medications, they have side effects

Plastics Behavior and Properties

• Mechanical Behavior• Flow Behavior• Short Term Mechanical Properties• Long Term Mechanical Properties• Thermal Properties• Electrical Properties• Environmental Properties• Other Properties

Mechanical Behavior

• Viscoelasticity

• Creep

• Stress Relaxation

• Recovery

• Loading Rate

Viscoelasticity

• Elastic– The material returns to original shape after the load has been

removed– Linear stress strain response

• Viscous– The material will deform or flow under load– Nonlinear stress-strain response

• Plastics show both responses– Short term load

• elastic

– Long term load• viscous

Creep

• One of the most important results of plastics’ viscoelastic behavior

• Deformation over time when a material is subjected to a constant stress

• The polymer chains slip past one another

• Some of the slippage is permanent

Creep

Stress Relaxation

• Gradual decrease in stress at constant strain

• Same polymer chain slippage as in creep

Recovery

• The degree to which a plastic returns to its original shape after a load is removed

Temperature and Loading Rate Effects

• Loading Rate– The rate at which the part is stressed or strained

• Thermoplastics become stiffer and fail at smaller strain levels as the strain rate increases

• At higher temperatures plastics lose their stiffness and become more ductile

Temperature and Loading Rate Effects

Flow

Types of Flow

• Drag Flow

– Caused by the relative motion of one boundary with respect to the other boundary that contains the fluid

– Two major boundaries in injection unit are the barrel and screw surfaces

– Since the screw is rotating in a stationary barrel, one boundary is moving relative to the other boundary

– This causes drag flow to occur

Types of Flow

• Pressure Flow– Caused by the presence of pressure gradients– Pressure flow is what occurs downstream of the

injection unit• Sprue, runner, gate and cavity

– Flow occurs because the pressure is higher at the injection unit discharge than in the mold

Types of Flow

• For the overall system – The injection unit uses drag flow to move the

material and build pressure– This pressure buildup at the discharge of the

injection unit results in pressure flow through the mold

Shear Flow Induced by Drag Flow

• Different layers of plastics move at different velocities with the maximum velocity being at the moving boundary and zero velocity at the wall

H

velocity

Force

Shear Flow Induced by Pressure Flow

• Different layers of plastics move at different velocities with the maximum velocity being at the centerline of flow and zero velocity at the walls

velocity

pressure diameter

Shear Rate

• Difference in velocity per normal distance• The change in shear strain with time• Units of seconds-1

• Drag Flow

• Pressure Flow

H

V

2/D

V

Shear Stress

• The stress required to achieve a shearing type flow

• Force divided by the area over which it acts

• Units of Pascal or psi

• Drag Flow

• Pressure FlowA

F

pressure

Shear Viscosity

• Internal resistance to shear flow

• Ratio of shear stress to shear rate

• Units of poise or Pa-sec

Shear Heat

• Viscous heat generation

• Heat generated due to shear flow

• Conversion of mechanical energy to heat through friction

• Amount is equal to the product of the viscosity and the shear rate squared

2*

Q

Effect of Temperature on Viscosity

Temperature

Viscosity

Types of Fluids

• Newtonian– A fluid whose viscosity is independent of shear rate

• Shear thinning(pseudo-plastic)– A fluid whose viscosity decreases with increasing shear

rate

• Shear thickening(dilatants)– A fluid whose viscosity increases with increasing shear

rate

Flow Behavior

Power law Fluids

• Polymer melts are shear thinning fluids

• The fact that the viscosity reduces with shear rate is of great importance in the injection molding process

• Important to know the extent of the change of viscosity with shear rate– m is the consistency index

– n is the power law index 1)(*

nm

Mechanical Properties

• Important in all applications– Stiffness– Hardness– Toughness– Impact Strength– The ability to support loads

Mechanical Properties

• Mechanical property data is used to– Select materials– Estimate part performance– Predict deformation and stresses from applied

loads

Mechanical Properties

• Most data have been derived from laboratory tests and may not directly apply to your application

• Data should be used for comparison purposes only because– Difference between testing and end use conditions

– Material and processing variability

– Unforeseen environmental or loading conditions

Types of Forces

• There are four fundamental forces we deal with in the testing of mechanical properties of plastics– Tensile

– Compressive

– Shear

– Torsion

• These forces are tested alone and in combinations

Tension and Compression Forces

• Tension– Pulling force

• Compression– Pushing force

Shear and Torsion Force

• Shear– Opposing forces at the

same point

• Torsional Force– Turning force

Stress and Strain

• Stress is the force per area that is applied to the specimen

– Units of psi or Pa

• Strain is the change is dimension divided by the original dimension

– No units

A

F

L

L

Stress-Strain

Terms and Definitions

• Proportional Limit– The end of the region

where the plastic shows linear stress-strain behavior

• Elastic Limit– The point after which the

plastic will permanently deform

– Applications that cannot tolerate permanent deformations must stay under the elastic limit

Terms and Definitions

• Yield Point– Marks the beginning of the

region in which the ductile plastic continues to deform without a corresponding increase in stress

– Elongation at yield gives the upper limit for application that can tolerate a small deformation

Terms and Definitions

• Break Point– Shows the strain value

at which the test bar breaks

• Ultimate Strength– Measures the highest

stress value

– Used for general strength comparisons

Terms and Definitions

• Elastic Modulus– The slope of the linear

region of the stress-strain curve

– Ratio of stress-strain response

– Used to compare materials and make structural calculations

– Units of psi or Pa

Short Term Mechanical Test

• Tensile

• Flexural

• Compressive

• Impact

• Hardness

• Coefficient of Friction

Tensile Tester

• Measures a plastics stiffness

• After the test bar is clamped in the jaw, the jaws then move at a constant rate of separation

• The force required for movement is recorded

Tensile Test Data

• Tensile Modulus measure a plastics stiffness– Used for comparisons and structural

calculations– The higher the modulus the greater the stiffness

• Tensile stress at yield establishes an upper limit for applications that can tolerate a small permanent deformation

Tensile Test Data

• Elongation at yield is the strain value at the yield point– Determines the upper limit for application that

can tolerate small permanent deformations

• Tensile Stress at Break is the stress applied at the time of fracture– Establishes an upper limit for

• One time use applications that fail due to fracture• Parts that can still function with large deformations

Tensile Test Data

• Elongation at Break measures the strain at fracture as a percentage of elongation– Useful for applications that fail by fracture

• Ultimate Strength measures the highest stress value during the tensile test– Useful for comparing general strengths between

plastics

• Ultimate Elongation is the elongation at the breaking point

Stress Strain Curves

Stress Strain Curves

Poisson’s Ratio

• Parts subjected to tensile or compressive stress deform in two directions

• Poisson’s Ratio measures the lateral to longitudinal strains

Poisson’s Ratio

• Usually between 0.35 to 0.42 for plastics

• Required for many structural analysis calculations

Flexural Tester

Flexural Test Data

• Flexural Modulus is the ratio of stress to strain in the elastic region of the stress strain curve– Measures the plastics stiffness in bending– Compressive and tensile forces are both

measured as a result of bending– Used in bending structural calculations– Test values for tensile modulus correspond well

with flexural modulus for solid plastics

Flexural Test Data

• Ultimate Flexural Stress is the highest value of stress on the stress-strain curve– Measures the level after which severe

deformation or failure will occur

Flexural Properties

Compressive Tester

• Measures a materials hardness

• The test specimen is compressed at a constant strain rate between two parallel platens until it ruptures or deforms by a certain percentage

Compressive Test Data

• Shows a materials hardness and load capabilities

• Compressive Strength measures the maximum compressive stress recorded during the test– Useful in structural calculations for load

bearing applications

Compressive Properties

Shear Strength

• Measures the shearing force required to make holes or tears in the plastic

• Useful in structural calculations for parts that may fail in shear

• Data does not account for stress concentrations or mold-in stresses

Tear Strength

• The force required to rip the plastic divided by the thickness

• Provides relative data for comparing materials

Impact Tester

Impact Test

• Impact Strength measures a plastics ability to absorb and dissipate energy

• Hard to relate at actual part performance– Part geometry– Temperature– Stress concentrations– Molding stresses– Impact speed

Impact Tests

• Izod is most widely used– Uses horizontally notched sample to

concentrate impact

• Charpy uses a vertically notched sample

• Use for comparing materials relative impact strength

Tensile and Impact

• Impact Strength and Tensile Modulus provide insight into a plastics mechanical nature– High impact strength and large tensile modulus

suggest a tough material– High impact strength and small tensile modulus

indicates a ductile, flexible material– Low Impact strength and a large tensile

modulus typify a brittle material

Hardness Tester

• A load is applied to an indentor, which presses against the plastic

Hardness Data

Abrasion Resistance

• Abrasion Resistance is measured by applying a Taber Abrader with 250gr weight and a CS 10-F textured abrader to a test specimen for a set number of cycles– Then measuring the changes in volume and

transparency

Abrasion Resistance Data

Coefficients of Friction

• Ratio of the friction force, the force needed to initiate sliding, to the normal force, the force perpendicular to the contact surface

Coefficients of Friction (Static) Rangesfor Various Materials

Long Term Mechanical Properties

• Creep

• Stress Relaxation

• Fatigue

Creep

• Short Term testing gives us data for periodic loading

• It is not unusual for plastic parts to be subjected to continuous loading or loads that last a long time

• The viscous nature of plastics make these long term loading to be of interest even if small

• Creep is the deformation or strain due to viscous or cold flow

• To design parts that are subjected to long term loading, the designer must utilize creep data

Examples of Creep

Creep

• The time and temperature dependent creep modulus of a polymer is

• Manufacturers generate creep data by subjecting molded test specimen to varying stress level and measuring the change in dimension over time

),(),( 0

TtTtEc

Creep Data

Creep Sample Problem

How much would the material be strained after 1000 hours at a constant stress of 2800 psi?

013.0

2800102.2 5

psipsix

E

Stress Relaxation

• Stress relaxation data is used for applications where strain levels remain constant over a long period of time

• When plastics are stretched, compressed, bent or sheared to a fixed value of strain, the stress value decrease with time due to the viscous effects(molecular relaxation)

Stress Relaxation Examples

Stress Relaxation

• The time and temperature dependent relaxation modulus of a polymer is

• Stress relaxation data is generated by applying a fixed strain to molded samples and measuring the gradual decrease in stress with time

0

),(),(

Tt

TtEr

Stress Relaxation Data

Stress Relaxation Sample Problem

• What is the stress of the polycarbonate after 104 hours at a 2% constant strain?

psi4000

Fatigue

• Fatigue properties are used when designing parts that are subjected to repeated or cyclic loadings

• Tests are ran in bending, torsion and tension

Fatigue Curves

Fatigue Example Problem

• What is the amount of stress that will lead to failure after 1 million cycles for – Tensile = 34N/m2

– Bending = 38N/m2

Thermal Properties

• Glass Transition Temperature

• Melting Temperature

• Coefficient of Thermal Expansion

• Deflection Under Load

• Thermal Conductivity

• Specific Heat

• Vicat Softening Temperature

Glass Transition and Melting Temperature

• Specific volume vs temperature provides

o Tm = melting temperature

• Tg = glass transition temperature

Melting Temperature

• While cooling the melt, the specific volume of the melt sharply drops at a temperature which is termed as Tm.

• This is due to the crystalline regions forming

• Only for semi-crystalline plastics

Glass Transition Temperature

• While cooling non-crystalline polymer melt there is no sharp drop in specific volume and the melt becomes highly viscous and it appears like solid.

• Since the glass behaves in this manner the temperature at which the specific volume curve changes its slope is called Tg- glass transition temperature.

Glass Transition Temperature

• Polymer becomes :– hard, stiff and brittle

below Tg – highly viscous but

solid at Tg

– rubbery, flexible and softer above Tg

• Both amorphous and semi-crystalline plastics have Tg

Coefficient Of Linear Thermal Expansion

• Measures the change in length per unit length of a material per unit change in temperature

• Expressed in in/in/°F or cm/cm/°C• Used to calculate the dimensional change

resulting from thermal expansion• Very important when components of an

assembly are made of different materials

Heat Deflection Under Load

• Used to compare elevated temperature performance of plastics under load

• Temperature requirements often limit plastics choice more than any other factor

• Does not represent the upper temperature limit

• Molding factors, sample preparation and thickness significantly affects the values

Heat Deflection Under Load

• The test bar is loaded on a support, the temperature raises until the applied load causes the bar to deflect

Vicat Softening Temperature

• Ranks the thermal performance of plastics according to the temperature that causes a specified penetration by a lightly loaded probe

• Used as a general indicator of short term, high temperature performance

• Less sensitive to sample thickness and molding effects

• Often used as the ejection temperature

Vicat Softening Temperature

• A flat ended probe contacts a plastic specimen submerged in a heated oil bath

• A specified load is applied and the temperature is increased

• Temperature of the oil bath when penetration takes place

Thermal Conductivity

• Indicates a materials ability to conduct heat energy

• Measured in Btu*in/(hr*ft2*°F) or W/(°K*m)

• Used to calculate heating and cooling requirements in mold filling, thermal insulation or heat dissipation analysis

Thermal Conductivity Data

Specific Heat

• Reflects the heat required to cause a one degree temperature change in a unit mass of material

• Measured in Btu/lb/°F or KJ/kg/°C

• Used in heat transfer calculations from mold filling and cooling analysis

Electrical Properties

• Resistivity

• Dielectric

• Dissipation

• Arc Resistance

Resistivity

• Measure of a plastics electrical insulating properties

• Used to compare plastics as electrical insulators

• Indicates current leakage through an insulating body

• Should be at least 108 ohm*cm to be considered an insulating material

Volume Resistivity Data

Dielectric Strength and Constant

• Dielectric Strength measures the voltage an insulating material can withstand before electrical breakdown occurs– Best indicator of a material’s insulating

capabilities– Measured in volts per mil of thickness– Higher values indicate better insulating

characteristics

Dielectric Strength Data

Dielectric Strength and Constant

• The Dielectric Constant is the ratio of the capacitance of a plate electrode system to a test specimen– Lower values indicated better insulating

characteristics

Dissipation Factor

• Measures a plastics tendency to convert current into heat

• Important in applications such as radar and microwave equipment that run at high frequencies

• Lower values indicate less power loss and heat generation

Arc Resistance

• Measures the number of seconds a plastics surface will resist forming a continuous conductive path while being exposed to high voltage electric arc

• Plastics with higher values are used in closely spaced conductors, circuit breaker and distributor cap applications

Environmental Properties

• Pay close attention to the environment to which the part will be exposed during– Processing– Secondary Operations– Assembly– End Use

• Chemical exposure and weather conditions may determine which plastic you choose

Environmental Properties

• Water Absorption

• Hydrolytic Degradation

• Chemical Resistance

• Weatherability

• Gas Permeability

Water Absorption

• Plastics absorb water to varying degrees, depending on their molecular structure, fillers and additives

• Adversely affects both mechanical and electrical properties and causes swelling

• Measures the amount of water absorbed as a percent of total weight

Hydrolytic Degradation

• Exposing plastics to moisture at elevated temperature can lead to hydrolysis– A chemical process that severs polymer chains by

reacting with water

– Reduces the molecular weight and degrades the plastic

• Degree of degradation depends on– Exposure time

– Temperature

– Stress levels

Chemical Resistance• Chemical Resistance of a plastic depends on

– The chemical– Exposure time and temperature– Stress level

• Type of chemical attack varies with the plastic and the chemical– Degradation– Stress cracking– Swelling

• Consider all substances a part will encounter– Manufacturing– Assemble– Storage– End Use

Weatherability

• Plastics in outdoor use are exposed to weather that can affect the performance of the part

• Ultraviolet radiation can cause embrittlement, fading and surface cracking

• Actual and accelerated testing• Additives and higher molecular weight can

improve stability

Gas Permeability

• Measures the amount of gas that can pass through a plastic in a given time

• Used in packaging and medical applications, where the plastic forms a barrier

Other Properties

• Density

• Specific Gravity

• Specific Volume

• Transmittance

• Refractive Index

• Flammability

Density

• Mass per unit volume

• Useful in converting volume into part weight and cost calculations

• Expressed in lb/ft3 or Kg/m3

Specific Gravity

• The ratio of a material's density to the density of water

• Used in a variety of calculations and comparisons when relative weight matters

Specific Volume

• The reciprocal of density

• Measured in ft3/lb or m3/Kg

Density and Specific Volume Data

Transmittance

• Measures a material’s transparency

• Haze is the percentage of transmitted light passing through a plastic that is scattered

• Luminous transmittance is the ratio of transmitted light to incident light

Transmittance Data

Refractive Index

• Ratio of light’s velocity in a vacuum to its velocity as it passes through a plastic

• Important in optical lens and light-pipe calculations

Refractive Index Data

Flammability

• Most Plastics need an additive to meet flame resistance ratings– Oxygen Index measures the percentage of

oxygen need to support flame in a plastic sample

– UL 94 Classes• Established by Underwriter Laboratories to classify

the burning behavior of plastics