The Paton Welding Journal, 2024, #8, 18-25 pages
Mathematical modelling of distortions at welding of large vessels of aluminium alloy
B.R. Tsaryk, O.V. Makhnenko
E.O. Paton Electric Welding Institute of the NASU.
11 Kazymyr Malevych Str., 03150, Kyiv, Ukraine. E-mail: makhnenko@paton.kiev.ua
Abstract
The problem of calculation prediction of the overall distortions of a large vessel made of aluminium alloy during friction stir
welding (FSW) is considered. A mathematical model was developed using numerical methods of thermoplasticity analysis for
determining the stress-strain state during FSW, by means of which it is possible to obtain residual plastic strains (the inherent
strain function parameters) for both types of welded vessel joints (longitudinal and circumferential). This makes it possible to
predict the overall distortions of a large cylindrical vessel with a great number of welded joints by the approximated method
of inherent strains within the limits of the theory of elasticity. The reliability of the mathematical model for determination of
the residual stresses and strains at FSW of aluminium alloy is confirmed by the agreement of the calculated distribution of
the residual longitudinal stresses with the data of experimental measurements. This can contribute to ensuring the necessary
accuracy of predicting the overall distortions of large vessels. The developed mathematical models and calculation algorithms
can be effectively used for in-process prediction of the stress-strain state during assembly welding of large cylindrical vessels
made of aluminium alloys.
Keywords:welded vessels, aluminium alloy, friction stir welding, plastic strains, residual stresses, mathematical modelling
Received: 01.07.2024
Received in revised form: 31.07.2024
Accepted: 30.08.2024
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Suggested Citation
B.R. Tsaryk, O.V. Makhnenko (2024) Mathematical modelling of distortions at welding of large vessels of aluminium alloy.
The Paton Welding J., 08, 18-25.