This important new handbook provides comprehensive coverage of how high performance fibres are designed and manufactured and covers their capabilities and applications. The high-modulus, high-tenacity (HM-HT) fibres fall naturally into three groups - polymer fibres such as aramids and polyethylene fibres; carbon fibres such as Kevlar; and inorganic fibres based on glass and ceramic fibres.
The books shows how high performance fibres are being increasingly used for a wide range of applications including goetextiles and geomembranes and for construction and civil engineering projects as well as in specialist fibres within composite materials where their ability to fulfil demanding roles makes them an effective choice for the engineer and materials scientist.
Provides a comprehensive overview of how high performance fibres are designed and manufactured and covers their capabilities and applicationsExplains how high performance fibres are being increasingly used for a wide range of applications, including geotextiles and geomembranes and construction and civil engineering projects

Texturing is increasingly important in textile production, not only in yarns for weaving and knitting fashion products, but also for carpets, furnishing fabrics and a variety of technical textiles. This book covers all the major techniques including twist-texturing, jet-screeen texturing, false-twist process, BCF processes and air-jet texturingare in detail. Combining a comprehensive review of the physics and chemistry of texturing with a thorough, illustrated description of current practice, this book is invaluable for yarn and fabric manufacturers, textile scientists and students on textile science and technology courses.

Due to their complexity and diversity, understanding the structure of textile fibres is of key importance. This authoritative two-volume collection provides a comprehensive review of the structure of an extensive range of textile fibres.
Volume 1 begins with an introductory set of chapters on fibre structure and methods to characterise fibres. The second part of the book covers the structure of manufactured polymer fibres such as polyester, polyamides, polyolefin, elastomeric and aramid fibres as well as high-modulus, high-tenacity polymer fibres. Chapters discuss fibre formation during processing and how this affects fibre structure and mechanical properties. A companion volume reviews natural, regenerated, inorganic and specialist fibres.
Edited by leading authorities on the subject and with a team of international authors, the two volumes of the Handbook of textile fibre structure is an essential reference for textile technologists, fibre scientists, textile engineers and those in academia.
The first title of a authoritative two-volume collection that provides a comprehensive review of the structure of a range of textile fibresProvides an overview of the development of fibre structure and methods to characterise fibresExamines the structure of both traditional and new fibres and natural and manufactured fibres

First published in 1962, and now in its fourth edition, Physical properties of textile fibres has become a classic, providing the standard reference on key aspects of fibre performance. The new edition has been substantially reorganised and revised to reflect new research.
After introductory chapters on fibre structure, testing and sampling, the book reviews key fibre properties, their technical significance, factors affecting these properties and measurement issues. Each chapter covers both natural and synthetic fibres, including high-performance fibres. The book first reviews properties such as fineness, length and density. It then considers thermal properties and reaction to moisture. A further group of chapters then reviews tensile properties, thermo-mechanical responses, fibre breakage and fatigue. Finally, the book discusses dielectric properties, electrical resistance and static, optical properties and fibre friction.
Written by one of the world s leading authorities, the fourth edition of Physical properties of textile fibres consolidates its reputation as a standard work both for those working in the textile industry and those teaching and studying textile science.
A standard reference on key aspects of fibre performanceAn essential read and reference for textile technologists, fibre scientists, textile engineers and those in academiaProvides substantial updated material on fibre structure and new test methods, data and theories regarding properties of textile fibres"

The field of fibre rope technology has witnessed incredible change and technological advance over the last few decades. At the forefront of this change has been the development of synthetic fibres and modern types of rope construction. This handbook updates the history and structural mechanics of fibre rope technology and describes the types and properties of modern rope-making materials and constructions.
Following an introduction to fibre ropes, the Handbook of fibre rope technology takes a comprehensive look at rope-making materials, rope structures, properties and mechanics and covers rope production, focusing on laid strand, braided, low-twist and parallel yarn ropes. Terminations are also introduced and the many uses of rope are illustrated. The key issues surrounding the inspection and retirement of rope are identified and rope testing is thoroughly examined. The final two chapters review rope markets, distribution and liability and provide case studies from the many environments in which fibre rope is used.
The Handbook of fibre rope technology is an essential reference for everyone assisting in the design, selection, use, inspection and testing of fibre rope.
A comprehensive look at rope-making materials and structures, properties and mechanicsCovers rope production including laid strand, braided, low-twist and parallel yarn ropes and rope terminationsRope testing is examined in depth, as well as the key issues surrounding rope retirement

Continued and systematic analysis of the mechanics of flexible fibre assemblies dates from about 1945, although the growth of research into textiles after 1920 had included studies of fabric structure and the measurement of mechanical properties. The subject is thus a young one, although this NATO Advanced Study Institute is a sign of developing maturity. However there is an earlier tradition. Relevant, even if somewhat loosely connected, quotations can be found in the works of the engineers of the ancient civilisations, recurring during the llenaissance with Leonardo da Vinci and Galileo. But the glorious libk is with Euler and the Bernoulli family, with their theories of the mechanics of flexible slender rods. While mathematicians have admired the beauty of this work, the invention of elliptic integrals, and the grace of the different classes of planar elastica, it is in the technology of textile materials, composed of flexible fibres and yarns, that the subject has found its more direct application. All this, and much more such as Max Born's doctoral thesis, was brought to our attention in a delightful discourse by Milos Konopasek, who is not only fascinated by the mathematics of Euler and the modern movement of the solutions of bending curves from two dimensions into three by the use of the computer, but also feels a personal link through having lived and studied within sight of the scene of Euler's triumphs in St. Petersburg.

Due to their complexity and diversity, understanding the structure of textile fibers is of key importance. This authoritative collection provides a comprehensive review of the structure of an extensive range of textile fibers.
After an introductory set of chapters on fiber structure and methods to characterize fibers, the book is classified into three main fiber groups. The second part of the book includes chapters that review the structure of natural cellulosic and protein fibers, including cotton, silk, and wool. Part three covers the structure of manufactured polymer fibers, for example polyester, polyamides, elastomeric fibers, and high-modulus, high-tenacity polymer fibers. The concluding part of the book discusses the structure of a variety of other textile fibers such as glass, carbon and optical fibers.
Edited by leading authorities on the subject and with a team of international authors, the Handbook of Textile Fiber Structure is an essential reference for textile technologists, fiber scientists, textile engineers, and those in academia.