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A novel creep test rig to study the effects of long-range residual stress, elastic follow-up and applied load

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Abstract

One of the many challenges in the behaviour of structures is to understand if the presence of residual stress plays an important role in contributing to failure of a structure operating at high temperature. Assessments of the high-temperature integrity of practical structures are based on experiments carried out using standard laboratory-scale creep test specimens tested under either load- or displacement-controlled conditions. In practice, structures are subjected to combinations of residual and applied stresses which in turn lead to mixed boundary conditions. Conventional laboratory creep tests do not represent these circumstances. The purpose of this paper is to describe the design of a novel test rig to introduce long-range residual stresses at high temperature. The concept of rig is based on three-bar structure with an initial misfit introduced into the central bar to represent a long-range residual stress and could be characterised easily without using time-consuming residual stress measurement techniques. Initial results demonstrated that the magnitude and the interaction of the residual stress with the applied loading is a function of the initial misfit displacements and the relative stiffness of the components of the system. Additionally, the subsequent behaviour of the system, with and without the application of additional loading, is governed by (a) the degree to which the misfit is accommodated by plastic and creep strain and (b) the elastic follow-up provided by the system. The paper describes the design of a test rig and laboratory tests conducted to validate the concept.

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Abbreviations

K in :

Middle bar stiffness other than specimen

K out :

Side bar stiffness

K s :

C(T) specimen stiffness

Z eff :

Elastic follow-up for bars in parallel

Z :

Overall elastic follow-up

σ ref :

Reference stress

P :

Applied load

E :

Young’s modulus of material

a 0 :

Initial crack length of C(T) specimen

B :

Gross section thickness of C(T) specimen

B n :

Net section thickness of C(T) specimen

W :

Width of C(T) specimen

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Acknowledgements

The authors gratefully acknowledge EDF Energy for providing financial support for this work. David Smith is also supported by the Royal Academy of Engineering, EDF-Energy and Rolls-Royce plc.

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Authors and Affiliations

  1. Department of Mechanical Engineering, Jain College of Engineering, Belagavi, India

    A. M. Shirahatti

  2. Solid Mechanics Group, Department of Mechanical Engineering, University of Bristol, Bristol, BS8 1TR, UK

    D. J. Smith

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  1. A. M. Shirahatti
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  2. D. J. Smith
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Correspondence to A. M. Shirahatti.

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Technical Editor: Paulo de Tarso Rocha de Mendonça, Ph.D.

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Shirahatti, A.M., Smith, D.J. A novel creep test rig to study the effects of long-range residual stress, elastic follow-up and applied load. J Braz. Soc. Mech. Sci. Eng. 41, 230 (2019). https://doi.org/10.1007/s40430-019-1730-y

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  • DOI: https://doi.org/10.1007/s40430-019-1730-y

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