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Behaviour of joints in high temperature materials

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Published by Applied Science, Sole distributor in the USA and Canada Elsevier Science Pub. in London, New York, New York, NY, USA .
Written in English

Subjects:

  • Heat resistant materials -- Congresses.,
  • Joints (Engineering) -- Congresses.

Book details:

Edition Notes

Statementedited by T.G. Gooch ... [et al.].
SeriesEUR ;, 8021, EUR (Series) ;, 8021.
ContributionsGooch, T. G., Commission of the European Communities. Joint Research Centre. Petten Establishment., European Council for Cooperation in Welding., European Symposium on the Behaviour of Joints in High Temperature Materials (1982 : Petten, Netherlands)
Classifications
LC ClassificationsTA418.26 .B44 1982
The Physical Object
Paginationix, 272 p. :
Number of Pages272
ID Numbers
Open LibraryOL2888446M
ISBN 100853341877
LC Control Number84113272

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Even at room temperature, solder joints exhibit both creep and fatigue behavior that is strongly dependent on solder joint configuration, the thermal environment, and the solder alloy properties. The microstructures of solder joints with up to 25 years of aging have been studied using SEM/EDS and metallographic techniques.   Specifically, AC joints under the temperature of 60 and  °C presented higher level of displacement, mainly due to the fact that higher temperature resulted in more ductility behavior of adhesive layer and epoxy resin. Moreover, peak load and energy absorption exhibited different levels for joints with different combinations of substrates. After a brief introduction of high temperature effects in concrete, we present the behavior of fly ash-based concrete at elevated temperatures Samples were heated up to °C to evaluate strength. A material that obeys Hooke’s Law (Eqn. ) is called Hookean. Such a material iselastic accordingtothedescription ofelasticity given earlier (immediate response,fullrecovery), andit is also linear in its relation between stress and strain (or equivalently, force and deformation).

(). Investigation on microstructure, mechanical properties and corrosion behavior of AISI L stainless steel to ASTM AP11 low alloy steel dissimilar welding joints. Materials at High Temperatures: Vol. 32, No. 6, pp. Measurements done in wide temperature range have shown that the exponential form of the joint closure curve results from gradual closure of initially non-parallel surfaces. The stress needed to close the joint was found to be proportional to the material stiffness. HIGH-TEMPERATURE MATERIALS ANDINDUSTRIAL APPLICATIONS by M. H. VANDE VOORDE Comission of the European Communities Joint Research Centre - Petten Establishment Material Division 1. INTRODUCTION During the last decade there has been increasing economic pressure on productive industry throughout the world, and in Western Europe in. This second part of the work on creep modeling offers readers essential guidance on practical computational simulation and analysis. Drawing on constitutive equations for creep in structural materials under multi-axial stress states, it applies these equations, which are developed in detail in part 1 of the work, to a diverse range of examples.