© 1991

Designing with Structural Ceramics

  • R. W. Davidge
  • M. H. Van de Voorde

Table of contents

  1. Front Matter
    Pages i-viii
  2. Introduction

  3. Engineering Properties

    1. G. De Portu, G. N. Babini
      Pages 21-49
    2. D. Munz
      Pages 50-75
    3. L. Dortmans, G. de With
      Pages 76-81
    4. J. T. van Konijnenburg, C. A. M. Siskens, S. Sinnema
      Pages 98-110
  4. Ceramic Matric Composites

    1. G. Ziegler
      Pages 111-131
    2. J. L. Baptista, R. N. Correia, J. M. Vieira
      Pages 132-156
  5. Technological Aspects

    1. E. Lugscheider, M. Boretius, W. Tillmann
      Pages 201-223
    2. R. J. Brook
      Pages 243-250
  6. Industrial Applications

    1. P. Lamicq, C. Bonnet, S. Chateigner
      Pages 251-257
    2. J. Wortmann
      Pages 258-272
    3. C. Razim, C. Kaniut
      Pages 273-295
    4. F. Forlani
      Pages 296-311
    5. H. J. Veringa, R. A. Terpstra, A. P. Philipse
      Pages 312-320
  7. Industrial Applications

    1. D. G. Brandon, M. Farkash
      Pages 321-328

About this book


The last 30 years have seen a steady development in the range of ceramic materials with potential for high temperature engineering applications: in the 60s, self-bonded silicon carbide and reaction-bonded silicon nitride; in the 70s, improved aluminas, sintered silicon carbide and silicon nitrides (including sialons); in the 80s, various toughened Zr0 materials, ceramic matrix composites reinforced with silicon 2 carbide continuous fibres or whiskers. Design methodologies were evolved in the 70s, incorporating the principles of fracture mechanics and the statistical variation and time dependence of strength. These have been used successfully to predict the engineering behaviour of ceramics in the lower range of temperature. In spite of the above, and the underlying thermodynamic arguments for operations at higher temperatures, there has been a disappointing uptake of these materials in industry for high temperature usc. Most of the successful applications are for low to moderate temperatures such as seals and bearings, and metal cutting and shaping. The reasons have been very well documented and include: • Poor predictability and reliability at high temperature. • High costs relative to competing materials. • Variable reproducibility of manufacturing processes. • Lack of sufficiently sensitive non-destructive techniques. With this as background, a Europhysics Industrial Workshop sponsored by the European Physical Society (EPS) was organised by the Netherlands Energy Research Foundation (ECN) and the Institute for Advanced Materials of the Joint Research Centre (JRC) of the EC, at Petten, North Holland, in April 1990 to consider the status of thermomechanical applications of engineering ceramics.


cement ceramics composite composite materials mechanical properties

Editors and affiliations

  • R. W. Davidge
    • 1
  • M. H. Van de Voorde
    • 2
  1. 1.Wantage, OxonUK
  2. 2.CEC Joint Research CentreInstitute for Advanced MaterialsPettenThe Netherlands

Bibliographic information

  • Book Title Designing with Structural Ceramics
  • Editors R.W. Davidge
    M.H. Van de Voorde
  • DOI
  • Copyright Information Springer Science+Business Media B.V. 1991
  • Publisher Name Springer, Dordrecht
  • eBook Packages Springer Book Archive
  • Hardcover ISBN 978-1-85166-740-6
  • Softcover ISBN 978-94-010-5634-2
  • eBook ISBN 978-94-011-3678-5
  • Edition Number 1
  • Number of Pages VIII, 343
  • Number of Illustrations 0 b/w illustrations, 0 illustrations in colour
  • Topics Ceramics, Glass, Composites, Natural Materials
  • Buy this book on publisher's site
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