Numerical Simulation of Material Flow and Analysis of Welding Characteristics in Friction Stir Welding Process
Abstract
:1. Introduction
2. Modeling and Acquisition Methods
2.1. Friction Stir Welding Heat Input Model
2.2. Finite Element Model
2.2.1. Geometric Model and Boundary Conditions
2.2.2. Finite Element Formula
2.2.3. Material Model
2.2.4. Dislocation Motion Model
2.3. Test Acquisition Method
3. Results and Discuss
3.1. Verification of Finite Element Model
3.2. FSW Temperature Field Distribution
3.3. Material Flow
3.3.1. Material Flow inside the Tool Pin
3.3.2. Material Flow on the Advancing Side
3.3.3. Material Flow on the Retreating Side
3.4. Prediction of Welding Defects
3.5. Effect of Material Flow on Microstructure
4. Conclusions
- (1)
- The thermogenic physical model of the FSW process is established, and the finite element model is constructed to simulate the FSW process. The axial force and torque of the friction stir welding process were collected by electromagnetic coupling technology, and the data of the test and simulation were compared. The curve trend verified the correctness of the finite element model.
- (2)
- Through a simulation analysis, it was found that the temperature on the advancing side is about 20 °C higher than that on the retreating side near the welding seam, and that the FSP temperature field has an important influence on the material flow field. By analyzing the temperature of the workpiece at different thickness layers, it was found that the temperature difference between the two sides of the middle and lower layers was relatively reduced.
- (3)
- The material flow law in different areas of the weld was studied, and it was found that a small part of the inner material of the tool pin was extruded to the bottom of the workpiece. There is a large difference in the flow conditions of the upper and lower parts of the weld. The material on the upper surface tends to move downward under the influence of the shoulder extrusion, while the material on the lower part moves spirally upward under the influence of the tool pin. The material flow amount of the advancing side is higher than that of the retreating side.
- (4)
- The material on the advancing side finally stays behind the weld, and most of the particles are distributed on the retreating side. The degree of the material flow gradually decreases along the thickness direction. Most of the material on the retreating side is finally distributed behind the welding seam, and some of it flows to the advancing side.
- (5)
- Through a simulation analysis, it was found that the abnormal material flow in the welding process is prone to welding defects under the conditions of a low rotating speed and high welding speed.
- (6)
- Through the comparative analysis of the cross-section of the joint, it was also found that there is a significant difference in the flow of the material between the advancing side and the retreating material, and that the material flow in the different regions makes the tissue forming boundary distinct. The tensile state of the joint microstructure can observe the flow tendency of the material. The advancing side forms a multi-directional material flow intersection area under the tool shoulder, which easily forms welding defects when the material flow is abnormal.
Author Contributions
Funding
Conflicts of Interest
References
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Variables | Physical Meanings | Variables | Physical Meanings |
---|---|---|---|
(N) | Axial force | (MPa) | Yield stress of the material |
(rad) | Rotational angular speed | (m) | Length of the tool pin |
(m) | Radius of the outer circumference | (MPa) | Deviatoric stress component |
(m) | Maximum radius of tool pin | () | Strain rate component |
(m) | Radius of the end of the tool pin | (/) | Large penalty factors |
(/) | Coefficient of friction | (N) | Arbitrary variables |
(°) | Taper angle of the tool pin | (MPa) | Flow stress |
(Pa) | Ultimate shear strength of the material | (/) | The rate sensitivity |
T (°C) | The temperature | ( cm−2) | Dislocation density |
Properties | AA 2014-T6 | Tool Steel W6 |
---|---|---|
Heat capacity () | 2.46 | 3.18 |
Young’s modulus () | 69,300 | 230,000 |
Heat expansion coefficient () | 21 | 11.9 |
Thermal conductivity () | 176 | 30.8 |
Poisson’s ratio (/) | 0.33 | 0.3 |
Cu | Si | Mn | Mg | Fe | Zn | Ti | Ni | Al |
---|---|---|---|---|---|---|---|---|
3.9~4.8 | 0.6~1.2 | 0.4~1.0 | 0.4~0.8 | ≤0.7 | ≤0.3 | ≤0.15 | ≤0.1 | Margin |
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Luo, H.; Wu, T.; Wang, P.; Zhao, F.; Wang, H.; Li, Y. Numerical Simulation of Material Flow and Analysis of Welding Characteristics in Friction Stir Welding Process. Metals 2019, 9, 621. https://doi.org/10.3390/met9060621
Luo H, Wu T, Wang P, Zhao F, Wang H, Li Y. Numerical Simulation of Material Flow and Analysis of Welding Characteristics in Friction Stir Welding Process. Metals. 2019; 9(6):621. https://doi.org/10.3390/met9060621
Chicago/Turabian StyleLuo, Haitao, Tingke Wu, Peng Wang, Fengqun Zhao, Haonan Wang, and Yuxin Li. 2019. "Numerical Simulation of Material Flow and Analysis of Welding Characteristics in Friction Stir Welding Process" Metals 9, no. 6: 621. https://doi.org/10.3390/met9060621
APA StyleLuo, H., Wu, T., Wang, P., Zhao, F., Wang, H., & Li, Y. (2019). Numerical Simulation of Material Flow and Analysis of Welding Characteristics in Friction Stir Welding Process. Metals, 9(6), 621. https://doi.org/10.3390/met9060621