Experimental and numerical thermo-mechanical analysis of friction stir welding of high-strength alluminium alloy

Veljic, M Darko; Sedmak, Aleksandar; Rakin, P Marko; Bajic, S.; Medjo, Bojan; Bajić, Darko; Grabulov, K Vencislav

doi:10.2298/tsci130512171v

Cited by 19 publications

(19 citation statements)

References 10 publications

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“…There are many different ways to evaluate heat input during FSW, including analytical ones, as shown in [3]. Also used for numerical evaluation of temperature distribution, as shown in [4,5]. Regarding experimental investigations, the maximum temperature has been recorded, as the measure of heat input, which also makes sense from material science point of view, because eventual defects are direct consequence of temperature changes.…”

Section: Introductionmentioning

confidence: 99%

Heat input effect of friction stir welding on aluminium alloy AA 6061-T6 welded joint

Sedmak¹,

Kumar²,

Chattopadhyaya³

et al. 2016

Therm sci

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The paper deals with the heat input and maximum temperature developed during friction stir welding with different parameters. Aluminum alloy (AA 6061-T6) has been used for experimental and numerical analysis. Experimental analysis is based on temperature measurements by using infrared camera, whereas numerical analysis was based on empirical expressions and finite element method. Different types of defects have been observed in respect to different levels of heat input.

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Section: Introductionmentioning

confidence: 99%

Heat input effect of friction stir welding on aluminium alloy AA 6061-T6 welded joint

Sedmak¹,

Kumar²,

Chattopadhyaya³

et al. 2016

Therm sci

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“…3 (there is no mesh on analytical rigid bodies, i. e. the tool and the backing plate). More details about the model can be found in [7,26].…”

Section: Finite Element Modelmentioning

confidence: 99%

Temperature fields in linear stage of friction stir welding: Effect of different material properties

Veljic

Rakin²,

Medjo³

et al. 2019

THERM SCI

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Friction stir welding is one of the procedures for joining the parts in solid state. Thermo-mechanical simulation of the friction stir welding of high-strength aluminium alloys 2024 T3 and 2024 T351 is considered in this work. Numerical models corresponding to the linear welding stage are developed in Abaqus software package. The material behaviour is modelled by Johnson-Cook law (which relates the yield stress with temperature, strain and strain rate), and the Arbitrary Lagrangian-Eulerian technique is applied. The difference in thermo-mechanical behaviour between the two materials has been analysed and commented. The main quantities which are considered are the temperature in the weld area, plastic strain, as well as the rate of heat generation during the welding process.

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“…The value of the heat transfer coefficient at the bottom surface of the workpiece is 3000 W/m 2°C , [29,30], this value corresponds to the heat transfer through the backing plate. Heat convection coefficient on the other surfaces of the workpiece are h = 10 W/m 2°C [24,30]. These surfaces are in the contact with the ambient (air), and the ambient temperature is 25 °C.…”

Section: Heat Transfer Modelmentioning

confidence: 99%

Analysis of the tool plunge in friction stir welding - comparison of aluminium alloys 2024 T3 and 2024 T351

et al. 2016

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Temperature, plastic strain and heat generation during the plunge stage of the friction stir welding of high-strength aluminum alloys 2024 T3 and 2024 T351 are considered in this work. The plunging of the tool into the material is done at different rotating speeds. A 3-D finite element model for thermomechanical simulation is developed. It is based on arbitrary Lagrangian-Eulerian formulation, and Johnson-Cook material law is used for modelling of material behaviour. From comparison of the numerical results for alloys 2024 T3 and 2024 T351, it can be seen that the former has more intensive heat generation from the plastic deformation, due to its higher strength. Friction heat generation is only slightly different for the two alloys. Therefore, temperatures in the working plate are higher in the alloy 2024 T3 for the same parameters of the plunge stage. Equivalent plastic strain is higher for 2024 T351 alloy, and the highest values are determined under the tool shoulder and around the tool pin. For the alloy 2024 T3, equivalent plastic strain is the highest in the influence zone of the tool pin.

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Experimental and numerical thermo-mechanical analysis of friction stir welding of high-strength alluminium alloy

Cited by 19 publications

References 10 publications

Heat input effect of friction stir welding on aluminium alloy AA 6061-T6 welded joint

Heat input effect of friction stir welding on aluminium alloy AA 6061-T6 welded joint

Temperature fields in linear stage of friction stir welding: Effect of different material properties

Analysis of the tool plunge in friction stir welding - comparison of aluminium alloys 2024 T3 and 2024 T351

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