UID:
(DE-602)edoccha_9960073313302883
Umfang:
1 online resource (380 p.)
ISBN:
1-85573-747-7
Serie:
Woodhead Publishing Series in Composites Science and Engineering
Inhalt:
The purpose of aligning short fibres in a fibre-reinforced material is to improve the mechanical properties of the resulting composite. Aligning the fibres, generally in a preferred direction, allows them to contribute as much as possible to reinforcing the material.Flow induced alignment in composite materials details, in a single volume, the science, processing, applications, characterisation and properties of composite materials reinforced with short fibres that have been orientated in a preferred direction by flows arising during processing. The topics discussed include fibre align
Anmerkung:
Description based upon print version of record.
,
Front Cover; Flow-Induced Alignment in Composite Materials; Copyright Page; Table of Contents; Preface; List of Authors; Chapter 1. Flow-induced alignment in composite materials: current applications and future prospects; 1.1 A brief survey of composites; 1.2 Flow processes for producing aligned-fiber polymer matrix composites; 1.3 Flow processes for producing aligned-fiber metal-matrix composites; 1.4 Flow processes for producing aligned-fiber ceramic-matrix composites; 1.5 Future prospects; References
,
Chapter 2. Fiber-fiber and fiber-waII interactions during the flow of non-dilute suspensions2.1 Introduction; 2.2 Single fiber motion; 2.3 Orientation characterization; 2.4 Fiber-fiber interactions; 2.5 Concentrated suspensions; 2.6 Fiber-wall interactions; 2.7 Summary and outlook; References; Chapter 3. Macroscopic modelling of the evolution of fibre orientation during flow; 3.1 Introduction; 3.2 Theory; 3.3 Numerical methods; 3.4 Applications; 3.5 Conclusions; Acknowledgement; References; Chapter 4. Flow-induced alignment in injection molding of fiber-reinforced polymer composites
,
4.1 Introduction4.2 The injection molding process; 4.3 Experimental observations of fiber orientation in injection molding; 4.4 Prediction of fiber orientation in injection molding; 4.5 Conclusion; References; Chapter 5. Control and manipulation of fibre orientation in large-scale processing; 5.1 Introduction; 5.2 Application of SCORIM for weldline strength enhancement; 5.3 Application of SCORIM for physical property enhancement; 5.4 Control of porosity in thick-section mouldings; 5.5 Control of fibre orientation in a selection of mould geometries
,
5.6 Extensions of the shear controlled orientation conceptReferences; Chapter 6. Theory and simulation of shear flow-induced microstructure in liquid crystalline polymers; 6.1 Introduction; 6.2 Shear flow-induced orientation phenomena in rod-like nematic polymers; 6.3 Shear flow-induced molecular alignment phenomena in rod-like nematic polymers; 6.4 Conclusions; Acknowledgments; References; Chapter 7. Mesostructural characterisation of aligned fibre cornposites; 7.1 Introduction; 7.2 Optical reflection microscopy; 7.3 Confocal laser scanning microscopy
,
7.4 Measurement errors in optical microscopy7.5 Characterisation studies of fibre reinforced composites; 7.6 Future developments; Acknowledgements; References; Chapter 8. Materials property modelling and design of short fibre composites; 8.1 Introduction; 8.2 Modelling the stiffness of fully aligned materials; 8.3 Effect of fibre aspect ratio on stiffness; 8.4 Effect of constituent properties on stiffness; 8.5 Modelling the effect of fibre orientation; 8.6 Application in design and some results; 8.7 Conclusions; References
,
Chapter 9. MicromechanicaI modeIing in aIigned-fiber composites: prediction of stiffness and permeability using the boundary element method
,
English
Weitere Ausg.:
ISBN 1-85573-254-8
Sprache:
Englisch
Bookmarklink