Thermomechanical Analysis of a Pressurized Pipe Under Plant Conditions-Reference-Cited by-同舟云学术

Thermomechanical Analysis of a Pressurized Pipe Under Plant Conditions

Published:2012-12-05 Issue:1 Volume:135 Page:
ISSN:0094-9930
Container-title:Journal of Pressure Vessel Technology
language:en
Short-container-title:

Author:

Farragher T. P.¹,Scully S.²,O'Dowd N. P.³,Leen S. B.¹

Affiliation:

1. Mechanical and Biomedical Engineering College of Engineering and Informatics NUI Galway Galway, Ireland

2. ESB Energy International ESB Head Office 27 FitzWilliam St. Dublin 2, Ireland

3. Department of Mechanical Aeronautical and Biomedical Engineering Materials and Surface Science Institute University of Limerick Limerick, Ireland

Abstract

This paper is concerned with the development of a methodology for thermomechanical analysis of high temperature, steam-pressurized P91 pipes in electrical power generation plant under realistic (measured) temperature and pressure cycles. In particular, these data encompass key thermal events, such as “load-following” temperature variations and sudden, significant fluctuations in steam temperatures associated with attemperation events and “trips” (sudden plant shut-down), likely to induce thermomechanical fatigue damage. An anisothermal elastic-plastic-creep material model for cyclic behavior of P91 is employed in the transient finite element (FE) model to predict the stress–strain-temperature cycles and the associated strain-rates. The results permit characterization of the behavior of pressurized P91 pipes for identification of the thermomechanical loading histories relevant to such components, for realistic, customized testing. This type of capability is relevant to design and analysis with respect to the evolving nature of power plant operating cycles, e.g., associated with more flexible operation of fossil fuel plant.

Publisher

ASME International

Subject

Mechanical Engineering,Mechanics of Materials,Safety, Risk, Reliability and Quality

Link

http://asmedigitalcollection.asme.org/pressurevesseltech/article-pdf/doi/10.1115/1.4007287/6311606/pvt_135_1_011204.pdf

Reference17 articles.

1. U.S. Program on Materials Technology for Ultra-Supercritical Coal Power Plants;J. Mater. Eng. Perform.,2005

2. Creep-Fatigue-Oxidation Interactions in a 9Cr-1Mo Martensitic Steel. Part I: Effect of Tensile Holding Period on Fatigue Lifetime;Int. J. Fatigue,2008

3. Saad A. A. , HydeC. J., SunW., HydeT. H., 2010, “Thermal-Mechanical Fatigue Simulation of a P91 Steel in a Temperature Range of 400–600 °C,” ASME PVP Conference.

4. Investigation of Ratcheting Characteristics of Modified 9Cr-1Mo Steel by Using the Chaboche Constitutive Model;Int. J. Pressure Vessels Piping,2007

5. Experimental and Numerical Characterisation of the Cyclic Thermomechanical Behaviour of a High Temperature Forming Tool Alloy;ASME J. Manuf. Sci. Eng.,2010

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