Compositional and Failure Analysis of Polymers A Practical Approach,9780471625728

Compositional and Failure Analysis of Polymers A Practical Approach

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Edition: 1st
ISBN13: 9780471625728
ISBN10: 0471625728
Format: Paperback
Pub. Date: 2000-10-03
Publisher(s): WILEY
List Price: $318.01

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Summary

Intended as a practical guide for polymer technologists, engineers and analysts in the plastics, composites and rubber fields, this title describes a range of techniques and strategies for compositional and failure analysis of polymeric materials and products. Numerous examples illustrate the application of analytical methods for solving commonly encountered problems in the polymer industry. The reader is guided towards the most appropriate method of analysis and measurement and the most likely reasons for the failure. Areas covered include: * Migration and interaction of additives * Mechanical stress and stress cracking * Crazing and fracture * Residual stress and weld lines * Contamination and discoloration Numerous pedagogical methods, illustrative flow diagrams, figures and tables are used throughout the text to make it an invaluable guide to all analysts and polymer engineers in industrial or academic laboratories.

Author Biography

John Scheirs <I>ExcelPlas, Australia</I>

Table of Contents

Preface xxxi
About the Author xxxiii
Acknowledgements xxxv
Glossary xxxvii
A Methodology for Solving Polymer Problems
1(20)
Introduction
1(3)
Flow Diagram for Solving Polymer Problems
4(8)
Accurately Identify and Characterize the Failure
4(4)
Are the Cause(s) Obvious and Few in Number?
8(1)
Has this `Same' Product been Successfully Produced Previously?
9(1)
Is there a Pattern to the Failure Location?
9(1)
Is there a Trend in the Timing of the Problem?
10(1)
Is this a Recurring Problem?
10(2)
Are there Relationships between the Type of Failure and other Factors?
12(1)
What Changes could have Affected the Failed Product When Compared to a Reference Sample?
12(1)
Dealing with Special Problem Classes
12(3)
Elusive Problems
12(2)
Complex Problems
14(1)
Subtle Problems
14(1)
Initial Production Problems
14(1)
Recurring Problems
14(1)
Catastrophic or Major Problems
14(1)
Product Life Cycle
15(2)
Checklist and Worksheet for Organizing the Problem-Solving Process
17(4)
References
20(1)
Sampling and Sample Preparation
21(16)
Introduction
21(1)
Sampling
22(1)
Sample Storage
23(1)
Sample Conditioning
23(1)
Sample Preparation
24(13)
Grinding
27(1)
Dissolution/Precipitation
27(1)
Preparation of Polymer Films
28(1)
Preparing Films for IR Analysis
29(1)
Preparing Films for DSC/TG Analysis
29(1)
Melt Pressing of Films
29(1)
Film Casting
30(2)
Introduction
32(1)
Solvent
32(1)
Film removal
33(1)
Artifacts of solvent casting
33(1)
Microtoming
33(1)
Miscellaneous Sample Types
34(1)
Intractable Samples
35(1)
Brittle Thermoset Samples
35(1)
Viscous Samples
35(1)
Paints
35(1)
Thin Films
35(1)
Rubbers
36(1)
Case Study
36(1)
References
36(1)
Microscopy of Polymers
37(34)
Optical Microscopy Techniques
37(18)
Introduction
37(1)
Sample Illumination
37(1)
Transmitted Illumination
38(1)
Near-vertical Illumination
38(1)
Incident Illumination
39(1)
Grazing Incident Illumination
39(1)
Coaxial Illumination
40(1)
Dark-Field Illumination
40(1)
Phase Contrast
40(1)
Polarized Optical Microscopy
40(7)
Sample Preparation
47(1)
Microtoming
47(1)
Microtome knife selection
47(1)
Glass knives
48(1)
General microtoming hints
49(1)
Microtoming artifacts
49(1)
Selection and preparation of the sample to be microtomed
49(1)
Problem samples (irregular shaped and soft samples)
50(1)
Problems encountered during microtoming
51(1)
Trouble-shooting microtoming problems
52(1)
Polishing
52(1)
Hints for the polishing of samples
53(1)
Polishing versus microtoming
53(1)
Preparation of composites
54(1)
Electron Microscopy
55(5)
Scanning Electron Microscopy
55(1)
Mounting SEM Samples
56(1)
Charge Neutralization
57(1)
Low-Voltage SEM
57(1)
Transmission Electron Microscopy
58(1)
Sample Preparation for TEM
59(1)
Electron-Beam Damage
59(1)
Special Microscopic Techniques
60(5)
Thermomicroscopy
61(1)
UV Microscopy
62(1)
Atomic Force Microscopy
63(2)
Practical Examples of the Uses of Microscopy in Polymer Analysis
65(6)
Identification of Inhomogeneous Melts during Processing
65(1)
Investigating Mould-Temperature Effects
65(2)
Evaluation of the Extent of In-Mould Orientation
67(1)
Examination of Fracture Surfaces
67(1)
Identifying Crack-Initiation Sites
67(1)
Examination of Rubber-Modified Polymers
68(1)
Assessment of Oxidized Polymers
68(1)
Microscopy of Fibres
68(1)
Fibre Finish
68(1)
Internal Texture of Fibres
68(1)
Failure Analysis of Fibres
69(1)
Microvoids in Aramid Fibres
69(1)
PET Fibres
70(1)
Beam-Induced Heating
70(1)
Study of Residual Stresses
70(1)
References
70(1)
Fourier-Transform Infrared Spectroscopic Analysis Methods for Polymers
71(36)
Introduction
71(2)
IR Artifacts
72(1)
Contaminant Peaks
72(1)
Interference Fringes
72(1)
Spectral Subtraction
73(1)
FTIR Techniques
73(11)
Transmission Analysis
73(1)
ATR Analysis
73(5)
Diffuse Reflectance IR (DRIFT)
78(3)
Reflectance-Absorption FTIR
81(1)
Photoacoustic FTIR
81(1)
FTIR Microspectroscopy
81(1)
Introduction
81(2)
Embedding Media
83(1)
FTIR Mapping Techniques
83(1)
Reflectance ETIR Microscopy
84(1)
Thermomicroscopy-FTIR
84(1)
Special IR Techniques
84(3)
NIR Analysis
84(2)
Raman-FTIR
86(1)
Sample Preparation
87(6)
Compression Moulding of Thin Films
87(3)
KBr Preparation
90(1)
Sample Supports
90(2)
Pellets
92(1)
Abrasion Method
92(1)
FTIR Analysis of Difficult Sample Forms
93(8)
Ground Polymers or Inorganic Ash
93(1)
Polymer Fibres
94(1)
Carbon-Filled Samples
94(1)
Thin Films on Reflective Substrates
95(1)
Irregularly Shaped Samples
96(1)
Polymer Foams
97(1)
Polymer Composites
97(1)
Clear, Highly Elastomeric Samples
98(2)
Thick Viscous Samples
100(1)
Microsamples
100(1)
Paints
100(1)
Samples with Suspected Surface Contamination
101(1)
Multilayer Samples
101(1)
Interpreting and Validating FTIR Data
101(4)
Introduction
101(2)
Steps Involved in PVC and PVDC Identification
103(1)
IR Identification of Styrenics
104(1)
Distinguishing between Polyamides and Polyurethanes
104(1)
Nylon Analysis
104(1)
Derivatization Techniques
105(2)
An Example of Derivatization
105(1)
References
106(1)
Thermal Analysis of Polymers
107(40)
Introduction
107(1)
Differential Scanning Calorimetry
108(21)
Introduction
108(1)
Representative Sampling
109(1)
Sample Preparation for DSC
109(1)
Effect of Sample Mass and Heating Rate
110(1)
Advanced DSC Techniques
110(1)
Information that can be Obtained by DSC Analysis
110(1)
Thermal History
110(2)
Melting Point
112(1)
Glass Transition Temperature
113(2)
Polymer Crystallinity
115(1)
Crystallization Behaviour
116(1)
Crystallization Kinetics
117(1)
Cooling Rate of a Polymer Component
117(1)
Physical Ageing
117(2)
Detecting the Presence of Regrind
119(1)
Evaluating Heat Ageing of Semicrystalline Polymers
119(2)
Evaluating Heat Ageing of Amorphous Polymers
121(1)
Evaluating Effects of Solvents on Amorphous Polymers
122(1)
Unusual DSC Features
122(1)
Cold Crystallization
123(1)
Water-Related Phenomena
124(1)
Secondary Melting Peaks
124(3)
Unexpected Exothermic Deviations
127(1)
DSC Behaviour of Common Polymers
127(1)
Amorphous Polymers
127(1)
PET
127(1)
PPS
128(1)
PBT
128(1)
Nylon 6
128(1)
Dynamic Mechanical Thermal Analysis
129(2)
Dynamic Mechanical Rheological Testing
131(1)
Thermomechanical Analysis
132(1)
Glass Transition Temperature and its Determination
133(5)
Introduction
133(1)
Determining Tg
133(5)
Thermogravimetry
138(7)
Introduction
138(1)
Isothermal TG
138(1)
Important Experimental Factors
139(2)
High-Resolution TG
141(1)
TG---FTIR
141(3)
Limitations of TG-FTIR
144(1)
TG MS
144(1)
Thermal Volatilization Analysis
145(2)
References
145(2)
Identification and Analysis of Polymers
147(46)
Introduction
147(6)
Density Measurement
147(2)
Flammability Testing
149(1)
Thermal Analysis and FTIR Spectroscopic Methods
150(1)
Chemical Equivalency
151(1)
Solubility Testing
151(1)
Structural Information on Polymers
151(2)
Molecular Weight Measurement
153(1)
Examples of Analytical Techniques used for Common Polymers
153(40)
ABS Analysis
153(1)
Introduction
153(1)
Determining the Rubber Content of ABS
154(1)
Analysis of Weathered ABS
155(1)
Epoxy Analysis
156(1)
Introduction
156(1)
FTIR and NMR Spectroscopies
157(1)
High Performance Liquid Chromatography
157(1)
UV Analysis
157(1)
EVA Analysis
158(1)
FTIR Spectroscopy
158(1)
Thermogravimetry
158(1)
TG-Titrimetry
159(2)
TG MS
161(1)
Thermal Volatilization Analysis
161(1)
UV Spectrophotometry
161(1)
Fluoropolymer Analysis
161(1)
HIPS Analysis
162(1)
Determining the Polybutadiene Content of HIPS
163(2)
Liquid Crystal Polymer Analysis
165(1)
Nylon Analysis
165(1)
FTIR Spectroscopy
165(1)
DSC
166(1)
PBT Analysis
166(1)
DSC
166(1)
MW Determination
167(1)
Polycarbonate Analysis
167(1)
PE Analysis
168(1)
FTIR Spectroscopy
168(1)
Fractionation
169(1)
PEEK Analysis
170(1)
DSC
170(1)
Determining Crystallinity
170(1)
Crystallization Behaviour
171(1)
Determining the Glass Transition
172(1)
Thermal Degradation of PEEK
172(1)
PET Analysis
172(1)
Phenolic Resin Analysis
173(1)
FTIR Spectroscopy
173(1)
Chromatographic Techniques
174(1)
Pyrolysis-GC-MS
174(1)
TG-MS
174(1)
PMMA Analysis
175(1)
Polysulfone Analysis
175(1)
PP Analysis
175(1)
FTIR Spectroscopy
175(1)
DSC
176(1)
MW Fractionation
176(1)
Analysing PP Copolymers
176(1)
PPO Analysis
177(1)
PPS analysis
177(2)
PU Analysis
179(1)
Introduction
179(1)
Compositional Analysis of PUs by FTIR Spectroscopy
180(2)
Sample Preparation for FTIR Spectroscopy
182(1)
Identifying the Acid in the Ester Portion of PU
182(1)
Determing NCO Content
182(1)
Analysis of Hydrolytic Breakdown Products
183(1)
DSC Analysis
184(1)
Pyrolysis Methods
184(1)
PVC Analysis
184(1)
FTIR Spectroscopy
184(1)
Analysis of Plasticizers
185(1)
Determination of Impact Modifiers
185(1)
MW Determination
186(1)
Determination of Crystallinity
186(1)
Determining the Glass Transition Temperature
187(1)
Degree of Fusion of PVC
187(1)
Degradation of PVC
187(1)
SAN Analysis
188(1)
Silicone Rubber Analysis
188(1)
Thermoplastic PU Elastomer Analysis
188(1)
Unsaturated Polyester Resin Analysis
189(1)
References
189(4)
Analysis of Blends, Copolymers and Oligomers
193(22)
Polymer Blends
193(8)
Introduction
193(1)
Miscibility of Blends
194(1)
Immiscible Blends
195(1)
Compatibilization
196(1)
Interpenetrating Networks
196(1)
Determination of the Blend Miscibility and Blend Ratio
196(1)
Analysis of Phase Dispersion in Polymer Blends
196(2)
Examples of Techniques for Determining Blend Composition
198(1)
Composition of LLDPE/LDPE Blends by DSC
198(1)
Composition of Nory1™ Blends by DSC
199(1)
Composition of Nory1™ Blends by Pyrolysis-Gas Chromatography
200(1)
Copolymers
201(5)
Introduction
201(2)
Copolymer Analysis
203(1)
Analysis of Block Copolymers
203(2)
Microscopy of Copolymers
205(1)
FTIR Spectroscopic Analysis of Copolymers
205(1)
Oligomers
206(9)
Introduction
206(1)
Analysis Methods
207(1)
HPLC
207(1)
Supercritical Fluid Chromatography
208(1)
Laser-Desorption/Fourier-Transform Mass Spectrometry
208(1)
Oligomers in HDPE
208(2)
Oligomers in PET
210(2)
Oligomers in Silicone Polymers
212(1)
Oligomers in PMMA
213(1)
References
213(2)
Identification and Analysis of Thermoset Elastomers
215(15)
Thermogravimeny
215(7)
FTIR Spectroscopic Analysis of Carbon-Filled Rubbers
222(1)
Sample Preparation for FTIR Spectroscopy
222(1)
Rubber Identification by Pyrolysis Methods
223(1)
Pyrolysis-IR Spectroscopy
223(1)
Pyrolysis-GC
223(1)
Pyrolysis-GC-MS
223(1)
Pyrolysis-MS
224(1)
Analysis of Specific Rubber Types
224(6)
SBR Analysis
224(1)
PB Analysis
225(1)
NBR Analysis
225(1)
Polychloroprene Analysis
226(1)
EPDM Analysis
226(2)
Thermoplastic Elastomer Analysis
228(1)
References
228(2)
Analysis of `Difficult' or Intractable Polymer Samples
230(10)
Introduction
230(1)
FTIR Spectroscopic Techniques for Difficult Samples
230(3)
DRIFT Analysis of Intractable Materials
231(1)
Abrasion-DRIFT Analysis
231(1)
Photoacoustic FTIR Spectroscopy
232(1)
Pyrolysis of Intractable Samples
233(3)
Pyrolysis of Small Samples
233(1)
Manipulation of Pyrolytic Oils
234(1)
Pyrolysis-IR Spectroscopy
234(1)
Pyrolysis-GC-FTIR Spectroscopy
234(1)
Rubber Pyrolysis
234(2)
Vacuum Pyrolysis
236(1)
Pyrolysis in the MS Ion Source
236(1)
Thermogravimetry
236(1)
Laser-Desorption Fourier-Transform Mass Spectrometry
237(3)
References
239(1)
Analysis of Additives in Polymers and Elastomers
240(30)
Introduction
240(1)
Grinding
241(1)
Additive Extraction
242(6)
Soxhlet Extraction
243(1)
Soxtec™ Extraction
243(1)
Reflux Extraction
243(1)
Solvent Extraction of Polymer Films
244(1)
Ultrasonic Extraction
244(1)
Microwave-Assisted Extraction
245(1)
Supercritical Fluid Extraction
246(2)
Analysis Methods
248(11)
UV Spectroscopic Analysis of Additives
248(1)
IR Spectroscopic Analysis of Additives
248(1)
GC Analysis of Additives
249(1)
HPLC Analysis of Additives
249(2)
GC-MS Analysis of Additives
251(1)
SEC-GC-MS Analysis of Additives
252(1)
Supercritical Fluid Chromatography Analysis of Additives
252(2)
SFC-FTIR Spectroscopic Analysis of Additives
254(1)
In situ Additive Detection in Polymers
254(1)
XRF Analysis
254(2)
Examples of the Use of XRF for Additive Analysis
256(1)
Common elements
256(1)
Uncommon elements
257(1)
Specific element combinations
257(1)
Important Considerations in XRF Analysis
258(1)
Sample preparation
258(1)
Experimental technique
258(1)
Spectral interference
259(1)
In situ Additive Analysis in Rubbers
259(1)
Miscellaneous Examples of Additive Analysis Methods
260(10)
Unknown Additive Analysis
260(1)
Antistatic Additive Analysis
261(1)
Thioester Additive Analysis
261(1)
Oligomeric (`Non-Extractable') Additive Analysis
261(1)
Carbon Black Determination
262(2)
Filler Analysis
264(1)
Furnace Ashing
264(2)
Filler Content Quantification
266(1)
Filler/Pigment Content Determination of Polyamides and Polyesters
266(1)
Ash Analysis by FTIR Spectroscopy
267(1)
Determination of Fibre Content and Distribution in Glass-Reinforced Composites
268(1)
References
268(2)
Analysis of Contaminants and Inclusions in Polymers
270(34)
Introduction
270(1)
Classes of Typical Contamination
271(9)
Black Specks
271(4)
Cellulosic Contamination
275(1)
Metal Contamination
275(2)
Polymeric Contamination
277(1)
Additive Contamination
278(1)
Contamination From Storage and Shipping Containers
279(1)
Chemical Contamination
279(1)
Miscellaneous Sources of Contamination
280(1)
Techniques for Analysis of Contamination
280(8)
Optical Microscopy
280(1)
FTIR Microscopy
281(1)
EDAX (X-Ray Microanalysis)
282(1)
ESCA
283(1)
Micro-XRF
283(1)
Pyrolysis-GC
283(1)
Thermogravimetry
284(1)
TG-GC-MS
284(1)
TP-SIP-MS
285(1)
TOF-SIMS
285(1)
Screening Polymer Batches for Contamination
286(2)
Gel Particles and other Inclusions
288(16)
Introduction
288(3)
Gels in PE
291(2)
Gels in PP
293(1)
Gels in PVC
294(1)
Oxidized Particles in Polymers
294(1)
Gels due to Additives
295(1)
Contamination-Related Gels
295(1)
Foreign Polymer Gels
296(1)
Analysis of Gel Imperfections
296(1)
Polarized-Light Examination
296(1)
Hot-Stage Microscopy
296(2)
FTIR Microscopy
298(2)
DSC Analysis
300(1)
Micro-Ashing
300(2)
Quantitying Gel Defects
302(1)
References
302(2)
Mechanical Failure Mechanisms of Polymers
304(59)
Introduction
304(6)
Tensile Failure
310(1)
Shear Failure
310(1)
Compressive Failure
311(1)
Crazing
311(2)
Introduction
311(1)
Crazing in Rubber-Modified Polymers
311(1)
Analysis of Crazing
312(1)
Shear Banding
313(2)
Introduction
313(1)
Analysis of Shear Banding
314(1)
Shear Deformation (Banding) versus Crazing
314(1)
Creep
315(2)
Introduction
315(1)
Measuring Creep
316(1)
Fatigue Failure
317(7)
Introduction
317(3)
Measuring Fatigue Resistance
320(1)
Examples of Fatigue Behavior in Different Polymers
321(1)
Fatigue of Polyacetal
321(1)
Fatigue of Toughened Styrenic Polymers
321(1)
Fatigue of Rubbers
321(1)
Fatigue of Nylon
322(1)
Fatigue of Short-Fibre-Reinforced Plastics
322(1)
Fatigue of Continuous-Fibre Composites
322(1)
Analysing Fatigue Fracture
323(1)
Impact Fracture
324(6)
Introduction
324(1)
Measuring Impact Strength
325(2)
Notch-Sensitivity
327(1)
Temperature Sensitivity
328(2)
Physical Ageing
330(3)
Introduction
330(2)
Common Polymers which Undergo Physical Ageing
332(1)
PVC
332(1)
PET
332(1)
PPO
332(1)
Physical Ageing of Rubber-Modified Glassy Polymers
333(1)
Analysis of Physical Ageing
333(1)
Failure Due to Temperature Effects
333(3)
Maximum- and Minimum-Use Temperatures
333(2)
Temperature Sensitivity of Creep Modulus
335(1)
Thermal Shock
335(1)
Failure Due to Improper Processing
336(3)
Problems due to Excessive in-Mould Orientation
336(1)
Melting and Moulding Temperatures
336(1)
Was the Correct Mould Temperature Used?
337(1)
Use of Regrind
338(1)
General Examples of Polymer Failure
339(13)
PVC
339(1)
Brittle Failure in PVC
339(2)
Thermal Degradation of PVC
341(1)
Physical Ageing of PVC
341(1)
Annealing
342(1)
Impact Strength
342(1)
Strain-Rate Effects on PVC
343(1)
Embrittlement of PVC by Loss of Plasticizer
343(1)
Stress Concentrations
344(1)
Polycarbonate
344(1)
Introduction
344(1)
MW Reduction
345(1)
Processing Conditions
345(1)
Solvent-Induced Crystallization
346(1)
Structural Flaws and Surface Stresses
347(1)
Nylon
347(1)
PET
347(1)
PBT
348(1)
PPS
348(1)
Polyacetal
349(1)
Impact-Modified Polymers
349(1)
Epoxy Resins
350(1)
Unsaturated Polyesters
350(1)
Polyetherimide
350(1)
Polysulfones
350(1)
Thermoplastic Polyurethanes
351(1)
PTFE
351(1)
Failure of Short-Fibre-Glass-Reinforced Thermoplastics
351(1)
Failure of Medical Plastics
352(1)
Failure of Polymers and Elastomers by Explosive Decompression
352(7)
Polymers Susceptible to ED Damage
355(1)
Nature of ED Damage
356(3)
Failure Analysis by Fractography
359(4)
References
361(2)
Chemical Attack of Polymers
363(34)
Introduction
363(2)
Factors Determining Chemical Resistance
365(1)
Types of Chemical Attack
365(26)
Hydrolytic Degradation of Polymers
365(1)
Introduction
365(2)
Hydrolysis of Poly(ethylene Terephthalate)
367(1)
Hydrolysis of Polycarbonate
368(1)
Hydrolysis of Polyacetals
369(3)
Hydrolysis of Polyurethanes
372(1)
Hydrolysis of Polyethersulfones
372(1)
Hydrolysis of Thermosets
372(1)
Hydrothermal Degradation of Composites
373(1)
Hydrolysis During Steam Autoclaving of Polymers
373(1)
Acid and Alkaline Attack
374(1)
Introduction
374(1)
Additives and Residues from Manufacturing Operations
374(1)
Environmental Exposure
374(1)
In vivo Situations
375(1)
By-Products of Degradation
375(1)
Service Use
375(3)
Analysing for Acid Attack
378(1)
Acid-Catalysed Hydrolysis
379(2)
Alkaline Attack
381(1)
Chemical Degradation by Strong Oxidizing Liquids
381(1)
Ester-Interchange and Transesterification Reactions
382(1)
Aminolysis
382(3)
Rubber Degradation by Chloramines
385(1)
Solvent Attack
385(2)
Solvation
387(1)
Salt Solutions
388(1)
Catalysed Chemical Degradation
388(1)
Microbial Chemical Degradation
389(2)
Analysis Methods for Assessing Chemical Degradation
391(4)
Introduction
391(1)
Mechanical Tests
392(1)
Swelling Tests
392(1)
DMTA
393(1)
Headspace Analysis
393(1)
FTIR Spectroscopic Analysis
393(1)
EDAX
394(1)
Case Study
395(2)
References
395(2)
Oxidative Degradation of Polymers
397(52)
Introduction
397(13)
Factors Affecting Polymer Oxidation
401(1)
Temperature
401(1)
Branching (Tertiary Hydrogen Atoms)
402(1)
Oxygen Diffusion
402(1)
Polymer Unsaturation
403(1)
Catalyst Residues
403(1)
Stress
404(1)
Effect of Oxidation on Polymer Properties
404(1)
Molecular Weight
404(1)
Mechanical Properties
405(1)
Other Properties
406(1)
Heterogeneous Oxidation
406(1)
Metal-Catalysed Oxidation
406(2)
Processing Degradation
408(2)
Accelerated Ageing Techniques
410(4)
Oven Ageing
411(1)
Assessing Processing Degradation by Multipass Extrusion
411(1)
Extrapolation of Oxidative Ageing Data
412(1)
Some Problems with Arrhenius Extrapolations
412(1)
Discontinuities in extrapolation plots due to polymer transitions
412(1)
Temperature fluctuations in ovens used for accelerated ageing
413(1)
Changes in `cage' effect with temperature
413(1)
Sample non-uniformity
413(1)
Differences in antioxidant solubility below and above the polymer Tm
413(1)
Stress relaxation
413(1)
Testing Methods
414(35)
Melt-Flow Index
414(1)
Residence-Time Melt-Flow Index
415(1)
IR Spectroscopic Methods
416(1)
Carbonyl Index
417(1)
Limitations of Carbonyl Measurements
417(1)
Derivation of Carbonyl and Hydroxyl Groups
418(1)
Differential Scanning Calorimetry
419(1)
Oxidative Induction Time (OIT)
420(1)
Introduction
420(2)
Limitations of the OIT Method
422(2)
Extrapolation of OIT Data
424(1)
Thermogravimetric Analysis
424(1)
Gel Content of Oxidized Polymers
424(2)
ESR Spectroscopy
426(1)
XPS
426(1)
Oxygen Uptake
426(1)
Introduction
426(1)
Shape of Oxygen-Uptake Curve
427(1)
Constant-Volume and Constant-Pressure Instruments
428(1)
Manometers/Manual Apparatus
428(2)
Limitations of Oxygen Uptake
430(1)
Hydroperoxide Detection
431(1)
Introduction
431(1)
Iodometric Method
432(2)
Ferric Thiocyanate Method
434(1)
Infrared Spectroscopic Methods
435(1)
Chemiluminescence (CL)
435(3)
Hydroperoxide Concentration by CL
438(1)
Staining Techniques
439(4)
References
443(6)
Failure of Fibre-Reinforced Composites
449(33)
Introduction
449(3)
Fibre Adhesion in Composites
452(2)
Analysis of Fibre Adhesion in Composites
453(1)
Failure of Composites due to Manufacturing and Cure-Related Factors
454(4)
Impurities in Commercial Thermosetting Resins
454(2)
Advancement of Prepreg Resin During Storage
456(1)
Distribution of Curing Agents
456(1)
Premature Curing
456(1)
Incomplete Curing
457(1)
Cure Progression
458(1)
Failure Behaviour of Composites
458(13)
Types of Failure Mechanisms of Composites
459(1)
De-bonding
459(1)
Interlaminar Failure
459(2)
Fibre Buckling
461(1)
Fibre Pull-Out
461(1)
Fibre Breakage
461(1)
Cracking of Composites
462(1)
Micro-cracking of Composites
462(1)
Types of Loading Modes to which Composites are Subjected
463(1)
Tensile Loading Failures
463(1)
Compressive Loading Failures
464(2)
Shear Loading Failures
466(1)
Stress Rupture of Composites
467(1)
Impact Damage of Composites
467(2)
Fatigue Failure of Composites
469(2)
Heat generation during fatigue
471(1)
Creep of Composites
471(1)
Failure of Composites due to Thermal Effects
471(2)
Effects of Moisture on Composites
473(1)
Hygrothermal Degradation of Composites
473(1)
Analysis of Hygrothermal Degradation Problems
474(1)
Chemical Attack on Composites
474(1)
Environmental Stress Cracking
474(1)
Oxidative Degradation
475(1)
Photo-Oxidative Degradation of Fibre Reinforcements
475(1)
Radiation Degradation of Composites
476(1)
Failure Testing of Composites
476(1)
Detecting Cracking in Composites
476(1)
Fractography of Composites
477(5)
Introduction
477(1)
Specific Fractographic Examples
478(1)
Tensile Failure
478(1)
Mode-I Tension
479(1)
Mode-II Shear
479(1)
Quantifying the Fracture Surface
480(1)
References
480(2)
Problems Related to Additive in Polymers
482(36)
Introduction
482(1)
Blooming
482(5)
Analysis
486(1)
Sublimation
487(1)
Analysis
488(1)
Plateout
488(1)
Analysis
489(1)
Die Drool
489(1)
Bleeding
490(1)
Analysis
490(1)
Additive Migration
491(1)
Analysis
492(1)
Additive Interactions
492(4)
Antagonistic Additive Interactions
492(3)
Physical Adsorption of Additives
495(1)
Additive Decomposition
496(6)
Thermal Decomposition of Nucleating Agents
496(1)
Slip-Additive Degradation
497(1)
Flame Retardants
497(1)
Hindered-Amine Light Stabilizers
498(1)
Pigments
498(1)
Thermal Stability and Photostability of Pigments
498(2)
Analysis of Pigments
500(1)
Loss of Water of Hydration and Volatiles Formation
500(1)
Pigment-Polymer Reactions
501(1)
Additive-Induced Polymer Decomposition
502(5)
Thermal Oxidation
502(2)
Analysis
504(1)
Photo-Oxidation
504(1)
Analysis to Determine Catalytic Activity of TiO2 Pigments
505(2)
Chain Cleavage by Nucleating Agents
507(1)
Additive Dispersion Problems
507(7)
Analysis
514(1)
Effect of Additives on the Polymers Mechanical Properties
514(1)
Pigment-Induced Distortion
515(1)
Abrasion
516(2)
References
516(2)
Weathering of Polymers
518(28)
Introduction
518(4)
Preliminary Investigations
522(1)
Detail the Problem
522(1)
Sample Selection
522(1)
Visual/Microscopic Inspection
523(1)
Polymer Identification
523(1)
Case Studies
523(13)
PVC Window Frames and Sidings
523(1)
Background
523(3)
Decision Tree and Testing
526(1)
Impact strength
526(1)
FTIR spectroscopic analysis
527(3)
Miscellaneous tests
530(1)
Polyolefin Garden Furniture and Milk Crates
530(1)
Background
530(1)
Decision Tree and PP Testing
531(5)
Decision Tree and HDPE Testing
536(1)
Problems with Other Polymer Types and Applications
536(5)
PP/EPDM Fenders
536(1)
PMMA Glazing
537(1)
PS
537(1)
Acrylonitrile-Butadiene-Styrene Housings
538(1)
Styrene-Acrylonitrile Car Grillls
539(1)
Polyester/Glass Composite (`Fibreglass') Sheeting
539(1)
Acrylic Surface Coatings
540(1)
Polymer Weatherability Assessment (Accelerated Weathering)
541(5)
Xenon-Arc Devices
542(1)
The QUV Weathering Chamber
543(1)
The SEPAP Weathering Chamber
543(1)
Pitfalls in Accelerated Weathering Testing
544(1)
References
545(1)
Environmental Stress Cracking of Polymers
546(41)
Introduction
546(3)
ESC Mechanisms
549(5)
Amorphous Plastics
549(1)
Semicrystalline Polymers
550(1)
The Stress Factor
550(1)
Stress-Cracking Agents
550(1)
Direct Stress Cracking (by Sorption)
551(1)
Indirect Stress Cracking (by Desorption)
552(2)
Degradative Stress Cracking
554(1)
Special Applications where ESC is likely to Occur
554(2)
Adhesive Bonding and Solvent Welding
554(1)
Contact between Dissimilar Polymers
554(1)
Welded Assemblies
555(1)
Metal Inserts
555(1)
Lubricated/Moving Parts
556(1)
Testing Methods to Determine ESC Resistance
556(5)
Constant-Deformation Test
556(1)
Ball-Indentation Test (ISO-4600)
556(1)
Bent-Strip Test Method (ISO-4599)
557(1)
Polyolefin Bent-Strip Test (ASTM-D1693)
558(1)
Constant-Load Test (ASTM-5397)
559(1)
Spiral-Cone Method
560(1)
Bottle ESCR Test
561(1)
Surface-Tension and Solubility-Parameter Effects
561(2)
Predicting ESC based on Solubility Parameters
562(1)
Predicting ESC based on Weight Change
562(1)
ESC Behaviour of Particular Polymers
563(15)
Polycarbonate
563(2)
Plasticizer Migration
565(1)
Solvents
565(1)
Fracture-Surface Analysis
566(2)
Illustrative Case Studies for Stress Cracking of Polycarbonate
568(1)
Case Study 1
568(1)
Case Study 2
569(1)
Case Study 3
569(1)
Case Study 4
569(1)
Case Study 5
569(1)
Assessing the Stress-Cracking Resistance of PC
570(1)
Styrenics
570(1)
SAN
571(1)
ABS
571(1)
HIPS
571(1)
Polyethylenes
572(2)
Polypropylene
574(1)
PMMA
574(1)
Polyurethanes
575(1)
PET
576(1)
Nylons
576(1)
PVC
576(2)
PPO
578(1)
Investigating an ESC Failure
578(3)
Introduction
578(1)
Measuring Residual Stress Levels in Moulded Parts
579(1)
Fractography
580(1)
Analytical Methods
581(1)
ESC Case Study
581(6)
References
585(2)
Residual Stresses and Weld Lines in Polymers
587(35)
Introduction
597
Protocol for Problem-Solving Processing Defects
587(3)
Residual Stresses and Molecular Orientation
590(17)
Introduction
590(1)
Residual Stresses
590(1)
Residual Strain near Sprue
590(1)
Wall-thickness Variations
591(1)
Molecular Orientation
592(1)
Frozen-In Strain in Skin Layer
592(1)
Determination of Residual Stresses
593(1)
Layer-Removal Procedure for Flat Mouldings
593(1)
Residual Stresses in Pipe Walls
594(1)
Semi-Quantitative and Non-Quantitative Methods
594(1)
Determination of Molecular Orientation
595(1)
Heat Reversion
595(1)
Solvent Immersion
596(1)
Clear Mouldings
596(1)
Microscopy
597(1)
Birefringence Measurements
597(2)
Chemical Stress-Cracking Agents
599(2)
Case studies involving stress-cracking agents
601(3)
Control of Residual Stresses and Molecular Orientation
604(1)
Ageing Effects
604(1)
Effects of Residual Stresses and Molecular Orientation on Properties
605(1)
Practical Examples of Failures related to Residual Stress and/or Molecular Orientation
606(1)
Weldlines
607(10)
Introduction
607(1)
Classification of Weldlines
608(1)
Weldlines in Polyolefins
609(1)
Weldlines in Caps and Cylindrical Mouldings
609(1)
Flow Weldlines in Thin-Walled Containers
609(1)
Appearance and Location of Weldlines
610(1)
Strength of Weldlines
611(1)
Factors Affecting Weldline Characteristics
611(1)
Mould Design Aspects
611(2)
Processing Variables
613(1)
Effect of Additives on Weldline Strength
613(1)
Effect of Polymer Type on Weldline Strength
613(1)
Assessing the Contribution of Weldlines to Part Failure
614(1)
Practical Examples of Weldline-Related Failures
614(3)
Shrinkage and Warpage
617(5)
Introduction
617(1)
Factors Affecting Shrinkage and Warpage
617(1)
Determination of Shrinkage and Warpage
618(1)
References
619(3)
Odour, Tainting and Outgassing Problems with Polymers
622(25)
Odour Problems in Polymers
622(10)
Introduction
622(2)
Origins of Odour-Causing Compounds
624(1)
Manufacturing Processes
624(1)
Polyethylenes
624(1)
Polyurethanes
625(1)
Residual Monomer
626(1)
Processing
626(1)
Additives
627(1)
Initiators
627(1)
Chain-transfer agents
627(1)
Plasticizers
628(1)
Pigments
629(1)
Stabilizers
629(1)
Lubricants
629(1)
Slip agents
629(1)
Nucleating agents
630(1)
Cross linking agents
630(1)
Blowing agents
631(1)
Curing
631(1)
Use of Odour Adsorbers
631(1)
Analysis Methods
631(1)
Taste and Off-Flavours
632(4)
Tainting of Plastic Containers
633(1)
PET Bottles
633(1)
HDPE Bottles
633(1)
Adventitious additives
634(1)
LDPE Bottles and Pouches
634(1)
Taste Testing
635(1)
Analytical Analysis of Off-Flavours
635(1)
Out-Gassing
636(4)
Introduction
636(1)
Common Types of Out-Gassing
637(1)
Formaldehyde Vapours
637(1)
Emissions from Car Interiors
637(1)
Outgassing from Synthetic Carpets
638(1)
Process Solvents
639(1)
Residual Monomer
639(1)
Analysis of Organic Vapours Emitted from Polymers
640(1)
Volatiles in Polymers and Their Detection
640(7)
Volatiles
640(1)
Analysis Methods
640(1)
GC-MS
641(1)
Head-Space Analysis
641(1)
Evolved-Gas Analysis
642(1)
TG-MS
642(1)
Thermolysis-MS
643(1)
Sample Handling
643(1)
Simple-Trapping Methods
644(1)
Comparison of Trapping Materials for Volatiles
644(1)
Advanced Techniques
645(1)
References
645(2)
Adhesion Problems with Polymers and Interfaces
647(23)
Introduction
647(2)
Case Studies
649(11)
Polyolefins
649(1)
Surface Contamination of Polyolefins
650(1)
Interfacial Adhesion in Composites
651(2)
Investigation of the Adhesion Interface in Composites
653(1)
Topography of the Interface
653(1)
Weak Surface Layers
654(1)
Chemical Nature of Reinforcement Surface
654(1)
Detecting Residual Sizing Agent
654(1)
Determining the Presence of Coupling Agents or Surface Treatment Materials
655(1)
Moisture Diffusion in Composites
655(1)
Analysis of Fibre-Matrix Adhesion
655(1)
Sealant Failure
656(1)
Chemical Attack of Silicones
657(1)
Hydrolytic Deterioration of Silicone Sealants
657(2)
Modes of Sealant Failure
659(1)
Common Classes of Polymeric Adhesives
660(2)
Epoxies
660(1)
Polyurethanes
660(1)
Cyanoacrylates
661(1)
Silicone Sealants
661(1)
Solvent Adhesives
661(1)
Common Causes of Adhesive Failure
662(8)
Topography
662(1)
Weak Surface Layers
663(1)
Oxidative Degradation
664(1)
Chemical Attack
665(1)
Cure-Related Factors
665(2)
Gap-Filling Problems
667(1)
Thermal Mismatch
667(1)
Water Penetration
667(1)
Entrapped Solvent
668(1)
Stress
668(1)
References
668(2)
Voids, Blisters and Surface Defects
670(22)
Voids
670(13)
Introduction
670(2)
Voids in Injection-Moulded Products
672(3)
Voids in Rotomoulded Products
675(2)
Voids due to Volatiles
677(2)
Voids due to Welding
679(1)
Voids in Composites
679(1)
Voids in Two-Part Thermosetting Polymers
680(1)
Voids in Sintered Components
680(1)
Voids in Cable Insulation
681(1)
Methodology for Problem Solving
681(2)
Blisters
683(6)
Introduction
683(2)
Blisters due to Vapour Permeation
685(1)
Blisters in Polymeric Surface Coatings (Paints)
686(2)
Blisters in Polymer Composites
688(1)
Surface Defects
689(3)
Surface Blemishes
689(1)
Weldline Surface Defects
689(1)
Lenses in Films
690(1)
Melt Fracture
690(1)
Pin-Holing
690(1)
Other Surface Defects
690(1)
References
691(1)
Discoloration of Polymers
692(49)
Introduction
692(5)
Steps for Polymer Discoloration Problem Solving
693(3)
Some Difficulties in Studying Discoloration
696(1)
Classification of Polymer Discoloration
696(1)
Polyolefins
697(19)
Antioxidant Conversion Products
698(3)
General Analysis for AO Conversion Products
701(5)
Antioxidant-Metal Ion Interactions
706(2)
General Analysis for AO-Metal Ion Complexes
708(1)
Antioxidant-TiO2 Interactions
709(2)
Antioxidant-Acid Interactions
711(1)
Storage Yellowing
711(1)
Fabric Discoloration
712(1)
General Analysis for NOx Yellowing
713(1)
Cardboard Yellowing
713(1)
Discoloration due to Amine-Based Additives
714(1)
Aromatic Amines
714(1)
Hindered-Amine Light Stabilizers
715(1)
Antistatic Agents
715(1)
Aromatic Polymers Containing Ph--O or Ph--N Linkages
716(5)
Polycarbonate
716(1)
Polyurethanes
717(1)
Poly(Phenylene Oxide)
718(2)
Unsaturated Polyesters
720(1)
Polysulfones
720(1)
Aromatic Polymers containing Ph-C=O or Ph-S Linkages
721(5)
Poly(Ethylene Terephthalate)
721(2)
Aliphatic Polyamides (Nylons)
723(1)
Aromatic Polyamides (Aramids)
724(1)
Poly(Phenylene Sulfide)
725(1)
Nitrile Polymers
726(3)
Polyacrylonitrile
726(1)
Poly(Styrene-co-Acrylonitrile)
727(1)
Acrylonitrile-Butadiene-Styrene
728(1)
Vinyl Polymers
729(4)
Poly(Vinyl Chloride)
729(2)
Ethylene-Vinyl Acetate Copolymers
731(2)
Poly(Vinylidene Fluoride)
733(1)
Miscellaneous Polymers
733(3)
Polystyrene
733(1)
High-Impact Polystyrene
734(1)
Poly(Methyl Methacrylate) and Photocured Acrylates
735(1)
Polyoxymethylene
735(1)
Radiation Yellowing
736(5)
References
738(3)
Index 741

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