An investigation into the residual stresses in an aluminium 2024 test weld

R.V. Preston; S.D. Smith; H.R. Shercliff; P.J. Withers

An investigation into the residual stresses in an aluminium 2024 test weld

R.V. Preston, S.D. Smith, H.R. Shercliff, P.J. Withers

Materials Engineering

Research output: Chapter in Book/Conference proceeding › Conference contribution

Abstract

This paper uses finite element (FE) analysis to examine the residual stresses generated during the TIG welding of aluminium aerospace alloys. It also looks at whether such an approach could be useful for evaluating the effectiveness of various residual stress control techniques. However, such simulations cannot be founded in a vacuum. They require accurate measurements to refine and validate them. The unique aspect of this work is that two powerful engineering techniques are combined: FE modelling and neutron diffraction. Weld trials were performed and the direct measurement of residual strain made using the ENGIN neutron diffraction strain scanning facility. The predicted results show an excellent agreement with experimental values. Finally this model is used to simulate a weld made using a "Low Stress No Distortion" (LSND) technique. Although the stress reduction predicted is only moderate, the study suggests the approach to be a quick and efficient means of optimising such techniques.

Original language	English
Title of host publication	Fracture Fatigue and Weld Residual Stress
Subtitle of host publication	Presented at the 1999 Asme Pressure Vessels and Piping Conference: Boston, Massachusetts, August 1-5, 1999
Editors	J. Pan
Publisher	American Society of Mechanical Engineers
Pages	265-277
Number of pages	13
ISBN (Print)	9780791816271
Publication status	Published - 1999

Publication series

Name	Pressure Vessels and Piping Division
Publisher	American Society of Mechanical Engineers
Volume	393
ISSN (Print)	0277-027X

Cite this

Preston, R. V., Smith, S. D., Shercliff, H. R., & Withers, P. J. (1999). An investigation into the residual stresses in an aluminium 2024 test weld. In J. Pan (Ed.), Fracture Fatigue and Weld Residual Stress: Presented at the 1999 Asme Pressure Vessels and Piping Conference: Boston, Massachusetts, August 1-5, 1999 (pp. 265-277). (Pressure Vessels and Piping Division; Vol. 393). American Society of Mechanical Engineers.

Preston, R.V. ; Smith, S.D. ; Shercliff, H.R. et al. / An investigation into the residual stresses in an aluminium 2024 test weld. Fracture Fatigue and Weld Residual Stress: Presented at the 1999 Asme Pressure Vessels and Piping Conference: Boston, Massachusetts, August 1-5, 1999. editor / J. Pan. American Society of Mechanical Engineers, 1999. pp. 265-277 (Pressure Vessels and Piping Division).

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abstract = "This paper uses finite element (FE) analysis to examine the residual stresses generated during the TIG welding of aluminium aerospace alloys. It also looks at whether such an approach could be useful for evaluating the effectiveness of various residual stress control techniques. However, such simulations cannot be founded in a vacuum. They require accurate measurements to refine and validate them. The unique aspect of this work is that two powerful engineering techniques are combined: FE modelling and neutron diffraction. Weld trials were performed and the direct measurement of residual strain made using the ENGIN neutron diffraction strain scanning facility. The predicted results show an excellent agreement with experimental values. Finally this model is used to simulate a weld made using a {"}Low Stress No Distortion{"} (LSND) technique. Although the stress reduction predicted is only moderate, the study suggests the approach to be a quick and efficient means of optimising such techniques.",

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Preston, RV, Smith, SD, Shercliff, HR & Withers, PJ 1999, An investigation into the residual stresses in an aluminium 2024 test weld. in J Pan (ed.), Fracture Fatigue and Weld Residual Stress: Presented at the 1999 Asme Pressure Vessels and Piping Conference: Boston, Massachusetts, August 1-5, 1999. Pressure Vessels and Piping Division, vol. 393, American Society of Mechanical Engineers, pp. 265-277.

An investigation into the residual stresses in an aluminium 2024 test weld. / Preston, R.V.; Smith, S.D.; Shercliff, H.R. et al.
Fracture Fatigue and Weld Residual Stress: Presented at the 1999 Asme Pressure Vessels and Piping Conference: Boston, Massachusetts, August 1-5, 1999. ed. / J. Pan. American Society of Mechanical Engineers, 1999. p. 265-277 (Pressure Vessels and Piping Division; Vol. 393).

Research output: Chapter in Book/Conference proceeding › Conference contribution

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T1 - An investigation into the residual stresses in an aluminium 2024 test weld

AU - Preston, R.V.

AU - Smith, S.D.

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N2 - This paper uses finite element (FE) analysis to examine the residual stresses generated during the TIG welding of aluminium aerospace alloys. It also looks at whether such an approach could be useful for evaluating the effectiveness of various residual stress control techniques. However, such simulations cannot be founded in a vacuum. They require accurate measurements to refine and validate them. The unique aspect of this work is that two powerful engineering techniques are combined: FE modelling and neutron diffraction. Weld trials were performed and the direct measurement of residual strain made using the ENGIN neutron diffraction strain scanning facility. The predicted results show an excellent agreement with experimental values. Finally this model is used to simulate a weld made using a "Low Stress No Distortion" (LSND) technique. Although the stress reduction predicted is only moderate, the study suggests the approach to be a quick and efficient means of optimising such techniques.

AB - This paper uses finite element (FE) analysis to examine the residual stresses generated during the TIG welding of aluminium aerospace alloys. It also looks at whether such an approach could be useful for evaluating the effectiveness of various residual stress control techniques. However, such simulations cannot be founded in a vacuum. They require accurate measurements to refine and validate them. The unique aspect of this work is that two powerful engineering techniques are combined: FE modelling and neutron diffraction. Weld trials were performed and the direct measurement of residual strain made using the ENGIN neutron diffraction strain scanning facility. The predicted results show an excellent agreement with experimental values. Finally this model is used to simulate a weld made using a "Low Stress No Distortion" (LSND) technique. Although the stress reduction predicted is only moderate, the study suggests the approach to be a quick and efficient means of optimising such techniques.

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Preston RV, Smith SD, Shercliff HR, Withers PJ. An investigation into the residual stresses in an aluminium 2024 test weld. In Pan J, editor, Fracture Fatigue and Weld Residual Stress: Presented at the 1999 Asme Pressure Vessels and Piping Conference: Boston, Massachusetts, August 1-5, 1999. American Society of Mechanical Engineers. 1999. p. 265-277. (Pressure Vessels and Piping Division).

An investigation into the residual stresses in an aluminium 2024 test weld

Abstract

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