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Full Screen- TITLE
- DEDICATION
- CERTIFICATE-1
- CERTIFICATE-2
- DECLARATION
- ACKNOWLEDGEMENT
- GLOSSARY OF TERMS
- CONTENTS
- PREFACE
- 1. Introduction
- I l Reasons for blending
- 1.2 Methods of blending
- 1.3 Types of blends
- 1.3.1 Based on miscibility
- 1 3 2 Based on constituents
- 1.4 Thermoplastic elastomers from rubber / plastic blends
- l.5 Problems with immiscible blends
- I.6 Compatibilisation
- 1.7 Role of compatibilisers in blending processes
- 1.8 Strategies for compatiblisation of polymer blends
- I.8. I Addition of premade grafted and block copolymers
- 1 8.2 Reactive compatibilisation
- 1.8.2. I Comparison of reactive versus physical blending
- 1.8.2.2 Addition of end reactive polymer generating block copolymers
- 1.8.2.3 Addition of end reactive polymers generating:; rafted copolymers
- l 8 2.4 Addition of polymers carrying pendant reactive groups as precursors of grafted copolymers
- 1.8.2.5 Addition of polymers carrying pendant reactive groups as precursors of branched copolymers
- 1.8.3 Addition of low molecular weight chemicals
- 1.8.4 Interchange reactions
- 1.8.5 Dynamic vulcanisation
- 1.8.6 Addition of ionomers
- 1.8.7 Addition of a third polymer partially miscible with all blend phases
- 1.8.8 Miscellaneous route
- 1.8.8.1 Common solvent method
- 1.8.8.2 Addition of reactive fillers as compatibilisers.
- 1.9 Effect of reactive blending on phase morphology
- 1.9.1 Phase morphology development in reactive blending
- 1.9.2 Effect of reactive blending on phase stabilisation in the melt
- 1.9.3 Effect of reactive blending on phase con-continuity
- 1.10 Rheology of reactively compatibilised polymer blends
- 1.11 Theories of compatiblisation
- 1.12 Thermoplastic elastomers resulting from NBR based binary blends
- 1.13 Scope and objectives of the work
- 1.1 3.1 Optimisation of mixing parameters
- 1.13.2 Correlation between morphology and mechanical properties of binary blends
- 1.13.3 Evaluation of the effectiveness of each compatiblisation technique based on phase morphology
- 1.13.4 Prediction of blend miscibility based on dynamic mechanical analysis
- 1.13.5 Examination of the processibility
- 1.13.6 Evaluation of the thermal stability
- 1.13.7 Analysis of dielectric properties
- 1 13.8 Examination of the resistance of the blend towards agressive enviornment
- 1.14 References
- 2. Experimental
- 2.1 Materials
- 2.1.1 Polymers
- 2.1.2 Compactibilisers
- 2.1.3 Chemicals
- 2.1.4 Fillers
- 2.1.5 Solvents
- 2.2 Prucedure
- 2.2.1 Blending
- 2. 2.2 Dynamic vulcanisation
- 2.2.3 Incorporation of fillers
- 2.3 Moulding
- 2.4 Phase morphology
- 2.5 Mechanical properties
- 2.6 Dynamic mechanical analysis
- 2.7 Melt flow measurements
- 2.8 Die swell measurements
- 2.9 Principal normal stresses
- 2.10 Extrudate morphology
- 2.11 Cross link density determination
- 2.12 Differential scanning calorimetry
- 2.13 Thermogravimetric analysis
- 2.14 Dielectric measurements
- 2.15 Sorption experiments
- 2.16 References
- 3. Optimisation of Mixing Parameters, Morphology and Mechanical Properties of HDPE/NBR Blends
- 3.1 Introduction
- 3.2 Results and discussion
- 3.2.1 Optimisation of mixing parameters
- 3.2.2 Effect of blend ratio on morphology and mechanical properties
- 3.2.3 Theoretical modelling
- 3.3 Conclusion
- 3.4 References
- 4. Compactibilisation by the Addition of Modified Polyethylene
- 4.1 Introduction
- 4.2 Results and discussion
- 4.2.1 Effect of compatibilisers on morphology
- 4.2.2 Effect of compatibilisers on mechanical properties.
- 4.2.3 lR spectra of modified polyethylenes
- 4.2.4 Mechanism of grafting
- 4.3 Conclusion
- 4.4 References
- 5. Compatibilisation by Dynamic Vulcanisation
- 5.1 Introduction
- 5.2 Results and discussion
- 5.2. I Brabender curves
- 5.2.2 Mechanical properties
- 5.2.3 Theoretical modelling
- 5.3 Conclusion
- 5.4 References
- 6. Dynamic Mechanical Analysis
- 6.1 Introduction
- 6.2 Results and discussion
- 6.2.I Effect of blend ratio
- 6.2.2 Effect of compatibilisers
- 6.2.3 Effect of dynamic vulcanisation
- 6.2.4 Effect of filler
- 6.2.5 Theoretical modelling
- 6.3 Conclusion
- 6.4 References
- 7. Melt Rheology
- 7.1 Introduction
- 7.2 Results and discussion
- 7 2. I Melt viscosity of binary blends
- 7.2.2 Effect of dynamic vulcanisation
- 7.2.3 Effect of compatibiliser on melt viscosity
- 7.2.4 Effect of blend ratio on morphology
- 7.2.5 Effect of extrusion rate on morphology
- 7.2.6 Effect of compatibiliser loading or morphology
- 7.2.7 Effect of annealing on morphology
- 7.2.8 Effect of temperature on viscosity
- 7.2.9 Shear rate temperature superposition curve
- 7.2.10 Flow behaviour index (n)
- 7.2.1 1 Melt elasticity
- 7.2.12 Extrudate behaviour
- 7.3 Conclusion
- 7.4 References
- 8. Thermal and Crystallisation Studies
- 8.1 Introduction
- 8.2 Results and discussion
- 8.2.1 Melting and crystallisation behaviour of the blends.
- 8.2.2 Effect of compatibilisation
- 8.2.3 Effect of dynamic vulcanisation
- 8.2.4 Effect of filler
- 8.2.5 Thermogravimetric analysis
- 8.3 Conclusion
- 8.4 References
- 9. Electrical Properties
- 9.1 Introduction
- 9.2 Results and discussion
- 9.2.1 Effect of blend ratio
- 9.2.2 Effect of dynamic vulcanisation
- 9.2.3 Effect of filler
- 9.3 Conclusion
- 9.4 References
- 10. Transport Properties
- 10.1 Introduction
- 10.2 Results and discussion
- 10.2. I Effect of DCP on mixing torque
- 10. 2.2 transport properties
- 10. 2.3 Mechanism of diffusion
- 10. 3 Conclusion,
- 10.4 References
- 11. Conclusion and Future Scope
- 11.1 Conclusion
- 11. 2 Future scope of the work
- 11.2.1 Compatibiisation efficiency by interfacial characterisation
- 11.2.2 Free volume measurement
- 11.2.3 Determination of extent of cross linking
- 11. 2.4 Crystallisation studies
- 11.2.5 Oil absorption studies
- 11. 2.6 Fabrication of useful products
- APPENDICES
- CURRICULUM VITAE
- List of Publications