Residual stress in 7449 aluminium alloy forgings

Robinson, J. S.; Hossain, S; Truman, Christopher E; Paradowska, Anna; Hughes, Darren J.; Wimpory, Robert C.; Fox, Matthew E.

doi:10.1016/j.msea.2009.12.022

Cited by 83 publications

(67 citation statements)

References 10 publications

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“…Therefore the selection of a stress-free d 0 sample is critical in obtaining a reliable residual stress result using the neutron diffraction technique. Robinson et al [19] by re-analysing stress-free d 0 sample obtained a higher ND measured residual stresses which correlated better with their FEA predictions. Figures 16 and 17 show respectively a comparison of L and LT residual stress distributions measured using different techniques including the ND technique, the conventional DHD technique and the incremental DHD technique.…”

Section: Resultsmentioning

confidence: 60%

“…For the same sample two different residual stress distributions are obtained. Two possible explanations for the discrepancy include (i) the effect of stressfree (d 0 ) reference sample; a cube extracted from the corner of the block was used as the reference sample and was unable to account for any microstructural variation [19] and (ii) natural ageing of the specimen at room temperature; the measurement using the SALSA instrument was at a later date. Figure 14 compares the ENGIN-X measured residual stress distributions with corresponding initial FEA predicted.…”

Section: Resultsmentioning

confidence: 99%

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Application of multiple analysis methods in optimising complex residual stress characterisation

Hossain

Zheng²,

Truman³

et al. 2017

Exp Tech

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An accurate characterisation of residual stress plays an important role in the structural integrity assessment of an engineering component. Several techniques and tools are available for measuring and predicting residual stresses. For example, neutron diffraction (ND) and X-ray diffraction (XRD) are non-destructive techniques used for measuring through-thickness and surface residual stresses respectively, while the deep-hole drilling (DHD) and the incremental centre-hole drilling (ICHD) are semi-destructive techniques and measure through-thickness and sub-surface residual stress respectively. In most open literature, a more favoured method is traditionally used over others, with some degree of validation using finite element analysis (FEA) predictive tool. In this paper it will be shown that the different methods and tools available are not contradicting or more superior to the others, but rather, the use of more than one available technique complementary to each other can improve the quality and the confidence in the characterisation of the residual stress state in an engineering component. In particular, the accurate knowledge of the residual stress field for a safety critical component plays a vital role for subsequent structural integrity assessment.

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Section: Resultsmentioning

confidence: 60%

Section: Resultsmentioning

confidence: 99%

Application of multiple analysis methods in optimising complex residual stress characterisation

Hossain

Zheng²,

Truman³

et al. 2017

Exp Tech

Self Cite

View full text Add to dashboard Cite

show abstract

“…The surface and subsurface compressive residual stresses in an as-quenched (before stress relief treatment) aluminium alloy forgings have been reported to be in the range -200 MPa -250 MPa [4]. The mechanical stress relief treatment by cold compression (forgings) or stretching (rolled plate) that follows, aims to relieve (or reduce) the severity of the bulk residual stresses existed in the asquenched state in the component.…”

Section: Introductionmentioning

confidence: 99%

“…The mechanical stress relief treatment by cold compression (forgings) or stretching (rolled plate) that follows, aims to relieve (or reduce) the severity of the bulk residual stresses existed in the asquenched state in the component. However, cold compression stress relief in die forged components do not always fully relieve the complex 3 D bulk residual stresses, and the unrelieved residual stresses may be of sufficient magnitude to cause distortion in machined components [4][5][6]. Moreover, the three dimensional residual stress distribution in the stress relieved aluminium die forging varied…”

Section: Introductionmentioning

confidence: 99%

“…The presence of process related bulk residual stresses results in: a) part distortion during machining which is a cost driver and b) high degree of scatter and/or variability in fatigue crack growth rate [2], which is a performance driver affecting the durability and damage tolerance of the component. The residual stresses in an aluminium 7050-T7452 forged block that caused distortion during machining was reported to be a major cost driver for a commercial aircraft manufacturer, as a result of excess manufacturing time, schedule overruns, and part rejection and scrapped material [3].The surface and subsurface compressive residual stresses in an as-quenched (before stress relief treatment) aluminium alloy forgings have been reported to be in the range -200 MPa -250 MPa [4]. The mechanical stress relief treatment by cold compression (forgings) or stretching (rolled plate) that follows, aims to relieve (or reduce) the severity of the bulk residual stresses existed in the asquenched state in the component.…”

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confidence: 99%

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Through Thickness Residual Stress and Microstructural Mapping of AA7085-T7452 Die Forging

Walker

Shekhter

Sharp

et al. 2016

Residual Stresses 2016

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Abstract. Significant weight savings and reductions in manufacturing costs have motivated the drive towards the use of unitised structures such as large die forgings in modern aircraft. However, detrimental bulk tensile residual stresses, present in these thick forgings can impact the durability and structural integrity of the primary aerospace structure. Residual stresses can lead to distortion during component machining, and part rejection. In addition, failure to account for the residual stress effects in the fatigue crack growth characteristics of the component in design and in performance could impact the structural integrity. Therefore, there is a need to measure and analyse the residual stresses present in the forged components, and examine the residual stress-microstructure, including grain structure/flow relationship for the forging, if such a relationship could be developed. The preliminary results of this experimental program have shown a link between the measured residual stress and hardness, along with changes in the grain structures through the thickness. IntroductionStructural unitisation of components is being actively pursued by the aerospace industry with the primary aim of weight reduction and cost savings. Large aluminium forgings and thick section rolled products make a significant contribution towards unitisation of critical, primary airframe components, such as wing-carry-through bulkheads. Inherent with the thick section wrought product forms, and particularly in die forged components, is the built-in bulk residual stresses on a macro scale [1], arising from the thermal gradients in the thermo-mechanical processing and the postsolution treatment rapid quenching. The presence of process related bulk residual stresses results in: a) part distortion during machining which is a cost driver and b) high degree of scatter and/or variability in fatigue crack growth rate [2], which is a performance driver affecting the durability and damage tolerance of the component. The residual stresses in an aluminium 7050-T7452 forged block that caused distortion during machining was reported to be a major cost driver for a commercial aircraft manufacturer, as a result of excess manufacturing time, schedule overruns, and part rejection and scrapped material [3].The surface and subsurface compressive residual stresses in an as-quenched (before stress relief treatment) aluminium alloy forgings have been reported to be in the range -200 MPa -250 MPa [4]. The mechanical stress relief treatment by cold compression (forgings) or stretching (rolled plate) that follows, aims to relieve (or reduce) the severity of the bulk residual stresses existed in the asquenched state in the component. However, cold compression stress relief in die forged components do not always fully relieve the complex 3 D bulk residual stresses, and the unrelieved residual stresses may be of sufficient magnitude to cause distortion in machined components [4][5][6]. Moreover, the three dimensional residual stress distribution in the stress reli...

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Internal Stress Generation during Quenching of Thick Heat Treatable Aluminium Alloys

Drezet¹,

Chobaut²,

Schloth³

et al. 2013

EPD Congress 2013

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In the current trend toward thicker aluminium plates, a major concern is the stress build-up during quenching which causes distortions during machining. Indeed, cooling rates are not high enough, especially at the core of such thick plates, to prevent any precipitation and quench induced precipitates lower the hardening potential. Multi-scale modelling is required when predicting macro-scale stresses after quenching for thick heat treatable aluminium components. The reason is the instantaneous strong coupling between phase precipitation at the nano-scale and material hardening due to precipitation or softening owing to solute depletion at the microscale. For thick parts, quenching intensities decrease when going from the skin to the core of the component, thus introducing a gradient of nanostructure and consequently a gradient of mechanical properties. In addition, large thermally induced deformations lead to high macroscale residual stresses although part of them is relaxed by plastic deformation. These stresses have been measured in water quenched thick plates of 7040 and 7449 aluminium alloys using neutron diffraction and layer removal techniques and the results when compared with a thermomechanical finite element model of quenching highlight the influence of precipitation.

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Residual stress in 7449 aluminium alloy forgings

Cited by 83 publications

References 10 publications

Application of multiple analysis methods in optimising complex residual stress characterisation

Application of multiple analysis methods in optimising complex residual stress characterisation

Through Thickness Residual Stress and Microstructural Mapping of AA7085-T7452 Die Forging

Internal Stress Generation during Quenching of Thick Heat Treatable Aluminium Alloys

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