Towards Friction Stir Remanufacturing of High-Strength Aluminum Components

doi:10.1007/s40195-022-01444-0

Abstract

Abstract:

Volumetric defects in high-strength aluminum alloy components were repaired via friction stir remanufacturing (FSR). Various consumable pins made of AA7075-T6 were designed. Top diameters of the consumable pins affected material flow, which ensured that the materials at the repairing interface were forged to metallurgical bonding. Conical angles determined load transfer besides material flow, which affected the fracture of the pins before the dwelling stage. Sound repaired components were achieved when the conical angle of the consumable pin was 1° larger than that of the volumetric defect. The ultimate tensile strength and elongation of the repaired components reached 445.9 MPa and 9.6%, respectively. The design criteria of the consumable pin in the FSR was established, which provided valuable references to repair volumetric defects in high-strength aluminum components.

Key words: Aluminum alloy:Defects, Friction stir welding, Interfaces, Microstructures, Mechanical properties

Xiangchen Meng, Yuming Xie, Xiaotian Ma, Mingyang Liang, Xiaoyang Peng, Shiwei Han, Lei Kan, Xin Wang, Sihao Chen, Yongxian Huang. Towards Friction Stir Remanufacturing of High-Strength Aluminum Components[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(1): 91-102.

Figures/Tables 18

Table 1 Mechanical properties of high-strength aluminum alloys

Materials	Tensile strength (MPa)	Elongation (%)	Microhardness (HV)
AA7150-T77511	579	14	166
AA7075-T6	605	11	182

Fig. 1 Schematic of a combined tool with the consumable pin and outer fixed shoulder

Fig. 2 Schematics: a a regularized hole, b geometric dimensions of the pin

Table 2 Geometric dimensions of the consumable pins

Pin type	Top diameter (mm)	Conical angle (°)
1	3.4	13
2	3.4	14
3	3.4	15
4	3.4	16
5	3.2	14
6	3.6	14
7	3.8	14

Fig. 3 Working principle of the consumable pin in the friction stir remanufacturing: a plunging tage, b repairing stage, c processing stage, d retracting stage

Fig. 4 Surface morphology: a keyhole defect, b repaired joint

Fig. 5 Magnified views of the interfaces using a Pin 1, b Pin 2, c Pin 3, d Pin 4

Fig. 6 Magnified views of interfaces using a Pin 5, b Pin 2, c Pin 6, d Pin 7

Fig. 7 Microstructure of a FSR joint along the repairing direction using Pin 3

Fig. 8 Characteristics of grains in various zones using Pin 3: a P-TMAZ, b QWNZ, c NWNZ, d WNZ, e TMAZ, f HAZ, g BM

Fig. 9 Microhardness distribution along the repairing direction of the joint using Pin 3

Fig. 10 Ultimate tensile strength and elongation of joints: a various conical angles of pins at the top diameter of 3.4 mm, b various top diameters of pins at the conical angle of 14°

Fig. 11 Comparison of joint efficiencies of different techniques [6,7,20]

Fig. 12 Two typical kinds of fractography: a fracture at the interface (mode 1), b fracture at the HAZ (mode 2), c magnified view of the region c, d magnified view of the region d

Fig. 13 Schematics for the material flow of the sound repaired joints: a start of the plunging stage, b end of the plunging stage, c end of the dwelling stage

Fig. 14 Microstructures: a sound joint, interfaces of b the left side, c the right side

Fig. 15 Geometric dimensions of the pin and the regularized hole

Table 3 Nomenclature

Symbols	Parameters	Annotation
R	Radius of the hole exposed to the plate surface	Known
r	Radius of the hole bottom	Known
h	Depth of the hole	Known
l	Generatrix length of the hole	Known
R + ΔR	Radius of the pin root	Unknown
r + Δr	Radius of the pin top	Unknown
h + Δh	Height of the pin	1 mm greater than h
s	Distance between the initial contact location to the pin top	Determined by Pin 3
ΔV	Volume difference of the pin and the hole	Expressed by Δr and ΔR
S	truncated cone lateral area of the hole	Calculated by r, R and l

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