Your search keyword '"Yunwu Ma"' showing total 3 results

1. Combined strengthening mechanism of solid-state bonding and mechanical interlocking in friction self-piercing riveted AA7075-T6 aluminum alloy joints

Author

Ninshu Ma, Bingxin Yang, Peihao Geng, Yongbing Li, He Shan, Shanqing Hu, and Yunwu Ma

Subjects

Friction stir processing, Materials science, Polymers and Plastics, Mechanical Engineering, Metals and Alloys, Microstructure, Indentation hardness, Mechanics of Materials, Ultimate tensile strength, Materials Chemistry, Ceramics and Composites, Dynamic recrystallization, Rivet, Composite material, Joint (geology), Interlocking

Abstract

A recently developed friction self-piercing riveting (F-SPR) technique based on the combination of friction stir processing and riveting has been reported to possess both solid-state bonding and mechanical fastening characteristics. However, there is still a lack of quantitative understanding of the hybrid enhancement mechanism, hindering its engineering application. To fill in this gap, the current research investigated the microstructure evolution, microhardness distribution, and miniature-tensile performance of the aluminum alloy AA7075-T6 F-SPR joints by experiments. An accurate numerical simulation model was established to quantitatively evaluate the individual contributions of microstructure, local bonding strength, and macro interlocking to the performance of the joint, which could well explain the experimental results. It was found that due to the friction stirring of the rivet, solid-state bonding driven by dynamic recrystallization is realized between the trapped aluminum in the rivet cavity and the bottom aluminum sheet. The solid-state bonding zone has 75% yield strength, 81% ultimate tensile strength, and 106% elongation compared to the base material. This solid-state bonding enables the internal interlocking between the trapped aluminum and the rivet to withstand the additional load, which forms a novel dual-interlock fastening mechanism and increases the peak cross-tension force by 14.3% compared to the single-interlock joint.

Published

2022

2. Flat friction spot joining of aluminum alloy to carbon fiber reinforced polymer sheets: Experiment and simulation

Author

Huihong Liu, Hong Ma, Yasuhiro Aoki, Peihao Geng, Yunwu Ma, Ninshu Ma, Hidetoshi Fujii, and Kazuki Murakami

Subjects

Carbon fiber reinforced polymer, Materials science, Polymers and Plastics, business.industry, Mechanical Engineering, Alloy, Metals and Alloys, Fractography, Rotational speed, Welding, engineering.material, Thermal conduction, law.invention, Mechanics of Materials, law, Materials Chemistry, Ceramics and Composites, engineering, Coupling (piping), Composite material, business, Thermal energy

Abstract

The Al alloy and carbon fiber reinforced polymer (CFRP) hybrid structures, incorporating the performance advantages of the two materials, have been attracting more attention in high-end manufacturing fields. In the current investigation, the flat friction spot joining (FSJ) was employed in joining the AA6061-T6 alloy and CFRP sheets. The significance of temperature distribution in influencing joint quality was highlighted through analyzing interface microstructural features, weld defect formation as well as fractography. To understand the role of thermal energy generation and conduction in the process comprehensively, a 3D thermal-mechanical coupling finite element model was established. The interfacial temperature was characterized by an uneven distribution behavior due to the inhomogeneous heat distribution. The peak temperatures on the top surface and Al alloy to CFRP interface at 1500 rpm rotational speed with 0.1 mm/s plunging speed were 498 °C and 489 °C, respectively. The peak interface temperature was reduced to 286 °C at 250 rpm, which produced an extremely small melted area. Compared with the plunging speed, rotational speed was found to be the predominant parameter for determining the joint property, which could be optimized to simultaneously realize the avoidance of thermal decomposition of CFRP, the sufficient melting duration time, and the wide enough melted area. Simulated thermal histories and melted area profiles were in agreement with experimental ones. The findings could be utilized to provide some feasible guidance for process optimization of dissimilar FSJ of metals and composites.

Published

2022

3. Microstructural evolution in friction self-piercing riveted aluminum alloy AA7075-T6 joints

Author

Sizhe Niu, Yunwu Ma, Ninshu Ma, Yongbing Li, and Huihong Liu

Subjects

Materials science, Yield (engineering), Polymers and Plastics, Mechanical Engineering, Metals and Alloys, 02 engineering and technology, Strain rate, 010402 general chemistry, 021001 nanoscience & nanotechnology, Microstructure, 01 natural sciences, 0104 chemical sciences, Mechanics of Materials, Materials Chemistry, Ceramics and Composites, Dynamic recrystallization, Rivet, Severe plastic deformation, Composite material, 0210 nano-technology, Ductility, Electron backscatter diffraction

Abstract

Friction self-piercing riveting (F-SPR) is an emerging technique for low ductility materials joining, which creates a mechanical and solid-state hybrid joint with a semi-hollow rivet. The severe plastic deformation of work materials and localized elevated temperatures during the F-SPR process yield complex and heterogeneous microstructures. The cut-off action of the work materials by the rivet further complicates the material flow during joint formation. This study employed the F-SPR process to join AA7075-T6 aluminum alloy sheets and systematically investigated the microstructural evolutions using electron backscatter diffraction (EBSD) techniques. The results suggested that as the base material approached the rivet, grains were deformed and recrystallized, forming two distinct fine grain zones (FGZs) surrounding the rivet and in the rivet cavity, respectively. Solid-state bonding of aluminum sheets occurred in the FGZs. The formation of FGZ outside the rivet is due to dynamic recrystallization (DRX) triggered by the sliding-to-sticking transition at the rivet/sheet interface. The FGZ in the rivet cavity was caused by the rotation of the trapped aluminum, which created a sticking affected zone at the trapped aluminum/lower sheet interface and led to DRX. Strain rate gradient in the trapped aluminum drove the further expansion of the sticking affected zone and resulted in grain refinement in a larger span.

Published

2021