Effect of Residual Stress on the Ultimate Bearing Capacity of Titanium Alloy Pressure Spherical–Cylindrical-Combined Shells
Abstract
:1. Introduction
2. Theory and Methods
2.1. Finite Element Analysis of Welding Residual Stress
- The sequential coupling analysis is conducted to simulate an instantaneous temperature field change in the welding process.
- A temperature field is introduced into the model as an external load, and the stress and strain of the structure are simulated to obtain the residual stress.
2.2. Nonlinear Ultimate Bearing Capacity of the Structure
- Material nonlinearity: Considering the plastic behavior of the material, the stress–strain relationship of the material changes with increasing stress. When the local yield of the structure occurs, the material enters its plastic state, and the stress–strain relationship no longer remains linear.
- Geometric nonlinearity: The structure undergoes considerable deformation under loading; therefore, the original equilibrium equation derived based on the small-deformation theory is no longer valid. Consequently, a new equation must be established based on the real-time state of the structure after deformation.
3. Results: Welding Residual Stress
3.1. Verification of Residual Stress of the Titanium Alloy Butt-Welding Plate
3.1.1. Finite Element Model
3.1.2. Material Properties
3.1.3. Welding Process and Related Parameters
3.1.4. Numerical Simulation of Welding Residual Stress
3.2. Welding Residual Stress of Titanium Alloy Pressure Spherical–Cylindrical-Combined Shells
3.2.1. Geometric Model
3.2.2. Finite Element Model and Boundary Conditions
3.2.3. Material Properties
3.2.4. Simulation Results and Analysis of Welding Residual Stress
- A large residual tensile stress existed near the weld on Path 2, and the transverse residual stress exhibited a bimodal distribution. The maximum tensile stress was approximately 170 MPa, which was approximately 20% of the yield strength of the material. The longitudinal residual tensile stress was high, and the maximum value was approximately equal to the yield strength.
- The longitudinal residual stress near the weld on Path 3 had a high tensile stress; the maximum value was approximately 780 MPa, and the transverse residual stress near the weld was compressive stress.
- Along Paths 4 and 5, both the inner and outer shells showed large longitudinal residual tensile stress, whereas the transverse residual tensile stress of the inner shell was small, and that of the outer shell was compressive stress.
- The von Mises residual stress on Paths 2 and 3 perpendicular to the weld direction was larger in the weld part, whereas that on Paths 4 and 5 along the weld direction was larger.
4. Discussion: Effect of Welding Residual Stress on Ultimate Bearing Capacity
4.1. Ultimate Bearing Capacity of Shells without Considering the Influence of Residual Stress
4.2. Ultimate Bearing Capacity of Ttitanium Alloy Pressure Spherical–Cylindrical-Combined Shell Considering Welding Residual Stress
5. Conclusions
- The transverse residual stress on the surface of the inner shell of the titanium alloy pressure spherical–cylindrical combined shell has a bimodal distribution that reaches approximately 20% of the yield strength, and the longitudinal residual tensile stress is higher than the transverse residual tensile stress. The longitudinal residual tensile stress near the weld on the shell surface perpendicular to the weld path is higher, whereas the transverse residual stress is close to the compressive stress.
- The surfaces of the inner and outer shells of titanium alloy pressure spherical–cylindrical-combined shells along the weld direction exhibit a large longitudinal residual tensile stress, and the transverse residual stress of the inner shell is small, whereas the outer shell exhibits residual compressive stress.
- Owing to the characteristics of the ring structure and cooling shrinkage of the girth weld during manufacturing, the additional bending moment and stress perpendicular to the direction of the girth weld are relatively prominent, and tensile and compressive stresses exist simultaneously.
- The welding residual stress has little effect on the ultimate bearing capacity of the titanium alloy pressure spherical–cylindrical composite shell’s structure.
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Temperature T (℃) | Elastic Modulus E (MPa) | Poisson Ratio | Thermal Expansion Coefficient K (1/°C) | Heat Transfer Coefficient λ (W/(m·°C)) | Specific Heat C (J/kg·°C) | Density ρ (kg/m3) |
---|---|---|---|---|---|---|
25 | 1.16 × 105 | 0.3 | 1.0 × 10–5 | 10 | 611 | 4530 |
550 | 0.79 × 105 | 0.3 | 0.93 × 10–5 | 15.8 | 691 | 4530 |
850 | 0.14 × 105 | 0.3 | 0.90 × 10–5 | 22.8 | 730 | 4530 |
1300 | 0.04 × 105 | 0.3 | 0.898 × 10–5 | 26.4 | 775 | 4530 |
Temperature T (°C) | Elastic Modulus E (MPa) | Poisson Ratio μ | Thermal Expansion Coefficient α (1/°C) | Heat Transfer Coefficient λ (W/(m·°C)) | Specific Heat C (J/kg·°C) | Density ρ (kg/m3) |
---|---|---|---|---|---|---|
20 | 1.14 × 105 | 0.34 | 9.1 × 10–6 | 6.8 | 611 | 4440 |
400 | 8 × 104 | 0.34 | 9.5 × 10–6 | 10.3 | 691 | 4440 |
800 | 3.5 × 104 | 0.34 | 1.04 × 10–5 | 15.8 | 735 | 4440 |
1540 | 1.0 × 102 | 0.34 | 1.1 × 10–5 | 25.3 | 800 | 4440 |
Strain | 0.003 | 0.007 | 0.008 | 0.01 | |
---|---|---|---|---|---|
Temperature (°C) | |||||
20 | 342 MPa | 798 MPa | 880 MPa | 920 MPa | |
400 | 240 MPa | 560 MPa | 560 MPa | 560 MPa | |
800 | 105 MPa | 130 MPa | 130 MPa | 130 MPa | |
1540 | 6 MPa | 12 MPa | 12 MPa | 12 MPa |
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Wang, Y.; Guo, J.; Zhang, B.; Ge, K.; Li, L.; Lv, F. Effect of Residual Stress on the Ultimate Bearing Capacity of Titanium Alloy Pressure Spherical–Cylindrical-Combined Shells. Metals 2024, 14, 123. https://doi.org/10.3390/met14010123
Wang Y, Guo J, Zhang B, Ge K, Li L, Lv F. Effect of Residual Stress on the Ultimate Bearing Capacity of Titanium Alloy Pressure Spherical–Cylindrical-Combined Shells. Metals. 2024; 14(1):123. https://doi.org/10.3390/met14010123
Chicago/Turabian StyleWang, Yuxuan, Jianting Guo, Bowen Zhang, Keke Ge, Liangbi Li, and Feng Lv. 2024. "Effect of Residual Stress on the Ultimate Bearing Capacity of Titanium Alloy Pressure Spherical–Cylindrical-Combined Shells" Metals 14, no. 1: 123. https://doi.org/10.3390/met14010123
APA StyleWang, Y., Guo, J., Zhang, B., Ge, K., Li, L., & Lv, F. (2024). Effect of Residual Stress on the Ultimate Bearing Capacity of Titanium Alloy Pressure Spherical–Cylindrical-Combined Shells. Metals, 14(1), 123. https://doi.org/10.3390/met14010123