thermal and mechanical analysis

Thermal and Mechanical Analysis

CNMR – Athlone Institute of Technology

Alan Murphy

IntroductionPlastic materials are tested throughout their life:

Monomer / Reactants Polymer / Raw Material & Additives Product / Design Product / Research & Development Processing / Quality Control Product / Service Product / End of Life


IntroductionA knowledge of available test methods is useful to:

Identify Research & Development requirements Control incoming raw material quality Quantify product specifications Understand material data sheets Correct manufacturing problems Investigate customer complaints Continuously improve the product


Introduction Raw Material Testing

Control of raw material helps to assure consistent processing and end product characteristics.

Melt Flow Rate and Density are the most common raw material tests but other raw material tests may be specified if warranted by the product.

Eg.1 Impact test for safety glasses.Eg.2 GPC for molecular weight controlEg 3. TGA to measure % glass content


Introduction Testing during processing

QC tests, such as weight or moisture content

Troubleshooting tests, such as investigating :

Why a component is cracking during assembly Why an extruded tube is shrinking after

manufacture Where contamination is coming from & what

type


Introduction Testing during service

Research and Development tests, such as comparison of alternative materials or property loss with time.

Customer complaints.eg Why has the product failed after 3 months use ?

Why has the product embrittled ?Why has discolouration occurred ?


Thermal Analysis

ANALYTICAL TECHNIQUES

Differential Scanning Calorimetry (DSC)

Dynamic Mechanical Thermal Analysis (DMTA)

Thermogravimetric Analysis (TGA)

Melt Flow Rheology (MFI)

Gel Permeation Chromatography (GPC)


Thermal AnalysisDifferential Scanning Calorimetry (DSC)DSC is a thermal method of analysis to study the thermal behaviour and thermal properties of materials (typically polymers). The material is sealed in a sample pan and subjected to a controlled temperature programme.

The resulting thermograph can yield much valuable information about the properties of the material analysed. Main use of DSC: Material Identification (Tm and

Hf) based on IS EN ISO 3146:2000; Method C2


Thermal AnalysisDifferential Scanning Calorimetry (DSC)


Thermal AnalysisDifferential Scanning Calorimetry (DSC)Other uses of DSC:% Crystallinity determination by DSC (based on IS EN ISO 3146:2000; Method C2).

Purity and Polymorphism analysis by DSC.

Thermal Stability of materials (e.g. – oxidative induction time (OiT) of materials) by DSC.


Thermal AnalysisDifferential Scanning Calorimetry (DSC)


Thermal Analysis

Dynamic Mechanical Thermal Analysis (DMTA)


Dynamic Mechanical Thermal Analysis (DMTA) records the temperature-dependent visco-elastic properties and determines the modulus of elasticity and the damping values by applying an oscillating force to the sample.

Thermal method of analysis used to determine thermo-mechanical properties of materials (i.e. – Glass Transition Temperature – Tg). Used as an alternative to DSC which is typically estimating Tg.

Used to more accurately determine the Tg value, strength and temperature-dependant elongation of a material. in several modes

Thermal AnalysisThermogravimetric Analysis (TGA)

TGA measures the weight of a substance heated at a controlled rate as a function of temperature or time.

All materials ultimately decompose on heating, and the decomposition temperature and profile is a characteristic property of each material. Main use of TGA: Inorganic Content of Material


Thermal Analysis



Other uses of TGA:

Material Thermal Stability.

Moisture and Volatiles Content (TG-IR).

Composition of Multi-Component Systems.

Shelf-Life Studies and Decomposition Kinetics.




% Polymer = 64.4%

% Carbon Black = 3.4%

% Glass Fibre = 32.2%

Rheological AnalysisMelt Flow Rate (MFR) to ISO 1133.

Grams of material that flow through a simple die in 10 minutes using a loaded piston and a set temperature.

Is a measure of Shear Viscosity and is directly proportional to the average molecular weight.

Uses: Raw material control; processing quality; regrind studies; useful troubleshooting test



Rheological Analysis

Capillary Rheometry: uses motor driven pistons to produce high pressures and two barrels with dies to measure shear viscosity and elongational viscosity.

Mimics processing conditions; gives information on average molecular weight and molecular weight distribution.

Uses: mould and die design; new material validation; troubleshooting; raw material control


Mechanical AnalysisTensile Testing to ISO 527

Measures the strength of a material and its flexibility (elongation).

Also used to measure peel strength, bond strength, weld strength.

Carried out on dumbbell specimens or actual product.

Uses: QC control for material or product


Impact Analysis

Izod and Charpy Impact Testing to ISO 179/180.

These are pendulum impact tests generally done on test bars but can be adapted for small products.

Usually notched, testing can be done at ambient or sub-zero temperatures.

Uses: QC test, material comparison, notch sensitivity


Aging StudiesUse of elevated temperatures to accelerate the aging process of plastic products.

Based on a 10ºC rise in environmental temperature produces a twofold increase in the degradation rate.

Humidity can be applied too if considered a factor.

Uses: shelf-life studies; product data; regrind analysis and the affect of other influences on product lifespan

Chemical AnalysisGel Permeation Chromatography (GPC)

GPC causes separation by various pore sizes in the column packing material, separating on the basis of molecular size, not molecular weight.

Main use of GPC (or SEC): Measuring average molecular weight (Mp) and molecular weight distribution (Mw) of a material.

Typical Detection methods used are UV-vis and Refractive Index.


Chemical AnalysisGel Permeation Chromatography (GPC)


Case Study AContamination Issue:The client sent one sample of their product with particulate on the bottom of the container.How was it

resolved?

FTIR and DSC were applied to determine the material types


Specimens were isolated and cleaned in Class 100 Cabinet

Case Study AContamination Issue:


4000.0 3000 2000 1500 1000 650.01/cm

%T

Isolated White Particulate Matter: FTIR – Polytetrafluoroethylene (PTFE)

Case Study AContamination Issue:


Isolated White Particulate Matter: DSC – Tm = 329oC

Case Study AOutcome:


The client checked their materials list and equipment associated with this product.

The PTFE Source was determined to have come from a stirring bar used during manufacture of the solution.

Case Study B


A batch of parts were cracking in service after normal pressure was put on the end of the part.

Processing Issue:

How was it resolved?

GPC was used to compare both ‘good’ and ‘bad’ samples.

Case Study B


Therefore we looked at the process and decided to look at the moisture content of the pre-processed material:

Processing Issue:

Using Karl Fischer Coulometry we determined that the material had not been dried sufficiently.

This then led to the materials’ molecular weight being affected during processing causing the material in the part to be weakened.

Case Study C


A manufacturer using regrind polyethylene material experienced difficulties with contamination of screen plates within an extruder.

The problem was thought to be caused by contamination of the regrind feedstock. CNMR were requested to:(1) Identify the contaminant;(2) Determine the source of contamination if possible;

Recycling Issue:

Case Study C


Debris from the screen plates was examined under an optical microscope. It was determined that the contamination was not compatible with the matrix and could be removed easily.

Recycling Issue:

FTIR determined that the materials present were PET-based.

PET

Case Study C


DSC confirmed that the contamination had a Tm at ca. 250oC. This is typical of the melting characteristics demonstrated by PET.

Recycling Issue:

Material from two silos were analysed. The granules were separated simply according to density.

Only one material from one of the silos was found to contain dense particles.

These particles had the same thermal characteristics as the contaminant.

THANK YOU...



Contact Details

Mr. Mark Atterbury Mr. Alan MurphySenior Research Officer Senior Research OfficerTel: 00353 9064 83070 00353 9064 42575Email: [email protected] [email protected]

thermal and mechanical analysis

Documents

thermal method of analysis

common raw material

thermal stability of

thermal behaviour

material identification

polymorphism analysis

development tests

processingqc tests