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    Comparison Between Linear and Nonlinear Fracture Mechanics Analysis of Experimental Data for the Ductile Superalloy Haynes 230

    Source: Journal of Engineering for Gas Turbines and Power:;2016:;volume( 138 ):;issue: 006::page 62101
    Author:
    Ewest, Daniel
    ,
    Almroth, Per
    ,
    Sjأ¶din, Bjأ¶rn
    ,
    Leidermark, Daniel
    ,
    Simonsson, Kjell
    DOI: 10.1115/1.4031712
    Publisher: The American Society of Mechanical Engineers (ASME)
    Abstract: With increasing use of renewable energy sources, an industrial gas turbine is often a competitive solution to balance the power grid. However, life robustness approaches for gas turbine components operating under increasingly cyclic conditions are a challenging task. Ductile superalloys, as Haynes 230, are often used in stationary gas turbine hot parts such as combustors. The main load for such components is due to nonhomogeneous thermal expansion within or between parts. As the material is ductile, there is considerable redistribution of stresses and strains due to inelastic deformations during the crack initiation phase. Therefore, the subsequent crack growth occurs through a material with significant residual stresses and strains. In this work, fatigue crack propagation experiments, including the initiation phase, have been performed on a single edge notched specimen under strain controlled conditions. The test results are compared to fracture mechanics analyses using the linear خ”K and the nonlinear خ”J approaches, and an attempt to quantify the difference in terms of a life prediction is made. For the tested notched geometry, material, and strain ranges, the difference in the results using خ”Keff or خ”Jeff is larger than the scatter seen when fitting the model to the experimental data. The largest differences can be found for short crack lengths, when the cyclic plastic work is the largest. The خ”J approach clearly shows better agreement with the experimental results in this regime.
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      Comparison Between Linear and Nonlinear Fracture Mechanics Analysis of Experimental Data for the Ductile Superalloy Haynes 230

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    http://yetl.yabesh.ir/yetl1/handle/yetl/161096
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    contributor authorEwest, Daniel
    contributor authorAlmroth, Per
    contributor authorSjأ¶din, Bjأ¶rn
    contributor authorLeidermark, Daniel
    contributor authorSimonsson, Kjell
    date accessioned2017-05-09T01:28:30Z
    date available2017-05-09T01:28:30Z
    date issued2016
    identifier issn1528-8919
    identifier othergtp_138_06_062101.pdf
    identifier urihttp://yetl.yabesh.ir/yetl/handle/yetl/161096
    description abstractWith increasing use of renewable energy sources, an industrial gas turbine is often a competitive solution to balance the power grid. However, life robustness approaches for gas turbine components operating under increasingly cyclic conditions are a challenging task. Ductile superalloys, as Haynes 230, are often used in stationary gas turbine hot parts such as combustors. The main load for such components is due to nonhomogeneous thermal expansion within or between parts. As the material is ductile, there is considerable redistribution of stresses and strains due to inelastic deformations during the crack initiation phase. Therefore, the subsequent crack growth occurs through a material with significant residual stresses and strains. In this work, fatigue crack propagation experiments, including the initiation phase, have been performed on a single edge notched specimen under strain controlled conditions. The test results are compared to fracture mechanics analyses using the linear خ”K and the nonlinear خ”J approaches, and an attempt to quantify the difference in terms of a life prediction is made. For the tested notched geometry, material, and strain ranges, the difference in the results using خ”Keff or خ”Jeff is larger than the scatter seen when fitting the model to the experimental data. The largest differences can be found for short crack lengths, when the cyclic plastic work is the largest. The خ”J approach clearly shows better agreement with the experimental results in this regime.
    publisherThe American Society of Mechanical Engineers (ASME)
    titleComparison Between Linear and Nonlinear Fracture Mechanics Analysis of Experimental Data for the Ductile Superalloy Haynes 230
    typeJournal Paper
    journal volume138
    journal issue6
    journal titleJournal of Engineering for Gas Turbines and Power
    identifier doi10.1115/1.4031712
    journal fristpage62101
    journal lastpage62101
    identifier eissn0742-4795
    treeJournal of Engineering for Gas Turbines and Power:;2016:;volume( 138 ):;issue: 006
    contenttypeFulltext
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