Chemical Composition Effect on Microstructures and Mechanical Properties in Friction Stir Additive Manufacturing

doi:10.1007/s40195-022-01406-6

Abstract

Abstract:

The variation of chemical compositions can affect the mechanical property of friction stir additive manufacturing (FSAM). Quantitative characterization of the relationship between the chemical composition and the mechanical property of FSAM components is key to control the quality of FSAM components. The effect of chemical composition on the mechanical property of 6xxx series aluminum alloy FSAM joint was studied by both experimental and numerical methods. A moving heat source model was established to simulate the heat transfer in FSAM process. The average grain size was calculated by Monte Carlo model, and the precipitate evolution model was used to calculate the hardness and constitutive stress-strain relationship. The validity of the numerical model was verified by experiments. Results indicate that the hardness and yield stress of 6xxx series aluminum alloy FSAW joint can be enhanced by increasing silicon or magnesium contents. By increasing the content of magnesium (silicon), the volume fraction and the mean radius of Mg₂Si can be increased when the content of silicon (magnesium) is excessive. With the decrease in volume fraction, the average grain size can be increased. By changing the weight percentage of magnesium and silicon in different layers, the hardness and yield stress along the build direction can be controlled.

Key words: Friction stir additive manufacturing, Chemical composition, Mechanical property, Microstructure, Numerical model

Jian-Yu Li, Shi-Ning Kong, Chi-Kun Liu, Bin-Bin Wang, Zhao Zhang. Chemical Composition Effect on Microstructures and Mechanical Properties in Friction Stir Additive Manufacturing[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(9): 1494-1508.

Figures/Tables 17

Table 1 Chemical composition of materials (wt%)

Mg	Si	Cu	Mn	Fe	Al
0.93	0.52	0.26	0.13	0.16	97.62

Fig. 1 FSAM experiment and the schematic diagrams: a experiment of FSAM, b first-pass FSAM, c second-pass FSAM, d third-pass FSAM, e fourth-pass FSAM

Fig. 2 Dimension of the tensile specimen

Fig. 3 Finite element model of friction stir additive manufacturing

Fig. 4 Flowchart of the numerical model: a temperature distribution, b temperature history, c precipitate evolution model, d particle number density, e grain morphology of first layer

Fig. 5 Temperature distribution during FSAM: a temperature measured by IRT system, b comparison of numerical and experimental results, c temperature distribution calculated by finite element model

Fig. 6 Validation of precipitates evolution model: a comparison of hardness between experimental and numerical results, b comparison of stress-strain curves between experimental and numerical results

Fig. 7 Comparison of grain morphologies in SEM b, d, f, h and numerical model a, c, e, g in different additive layers a, b 4th layer, c, d 3rd layer, e, f 2nd layer, g, h 1st layer

Fig. 8 Variations of precipitate hardening and particle number density a, particle number density and mean radius b in 4th additive layer

Fig. 9 Effect of magnesium content on hardness a and constitutive relation b-e in different layers (the first additive layer—b, the second additive layer—c, the third additive layer—d, the fourth additive layer—e)

Fig. 10 Particle number density distribution of different additive layers: a the first additive layer, b the second additive layer, c the third additive layer, d the fourth additive layer

Fig. 11 Effect of magnesium content on volume fraction and average grain size: a the first additive layer, b the second additive layer, c the third additive layer, d the fourth additive layer

Fig. 12 Variation of precipitate hardening and solute hardening a, particle number density and mean radius b

Fig. 13 Effect of silicon content on hardness a and constitutive relation b-e in different layers (the first additive layer—b, the second additive layer—c, the third additive layer—d, the fourth additive layer—e)

Fig. 14 Precipitate number density distribution of different additive layers: a the first additive layer, b the second additive layer, c the third additive layer, d the fourth additive layer

Fig. 15 Effect of silicon content on volume fraction and average grain size: a the first additive layer, b the second additive layer, c the third additive layer, d the fourth additive layer

Fig. 16 Effect of magnesium a and silicon b contents change on mechanical properties of different additive layers

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