Strength and Failure Analysis of Fiber-Wound Composite Gas Cylinder via Numerical Simulation
Abstract
:1. Introduction
2. Stress Analysis
2.1. Modeling of Filament Wound Composite Gas Cylinder
2.2. Autofrettage Stress of Filament-Wound Composite Gas Cylinder
3. Failure Analysis of Cylinder
4. Conclusions
- Starting from the perspective of autofrettage treatment and damage analysis of a fiber-wound composite gas cylinder, the angle and thickness of the fiber layer are calculated by using the grid theory for modeling. The fiber winding method is geodesic winding. The ABAQUS subroutine compiled by the Hashin criteria is used to analyze the damage during the process from working pressure to blasting pressure of the fiber-wound composite gas cylinder.
- The simulation results show that applying autofrettage pressure can reduce the stress level of the inner liner under working pressure and increase the stress of the fiber layer. In other words, applying autofrettage pressure can improve the stress distribution between the inner liner and the fiber under working pressure. In the study, failure analysis was carried out on a fully wound carbon fiber gas cylinder with an aluminum alloy inner liner under nominal working pressure of 35 MPa. According to the simulation results, it was found that the initial damage of the matrix of the fiber layer appeared in the transition section between the dome and the barrel body, and the damage generally started from the circumferential winding layer and the outer layer of the winding layer.
Author Contributions
Funding
Data Availability Statement
Conflicts of Interest
References
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Parameter | Value | Parameter | Value |
---|---|---|---|
E1/GPa | 130 | Xt/MPa | 2080 |
E2/GPa | 7.7 | Xc/MPa | 1250 |
E3/GPa | 7.7 | Yt/MPa | 60 |
v12 | 0.3 | Yc/MPa | 140 |
v13 | 0.3 | Sxy/MPa | 110 |
v23 | 0.35 | Gft/N/mm | 133 |
G12/GPa | 4.8 | Gfc/N/mm | 10 |
G13/GPa | 4.8 | Gmt/N/mm | 0.5 |
G23/GPa | 3.8 | Gmc/N/mm | 1.6 |
Gs/N/mm | 1.6 |
Autofrettage Pressure /MPa | Zero Pressure /MPa | Working Pressure /MPa | Hydraulic Test Pressure /MPa | Minimum Burst Pressure /MPa |
---|---|---|---|---|
40 | 0 | 35 | 52.5 | 120 |
Working Pressure /MPa | Hydraulic Test Pressure /MPa | Minimum Burst Pressure /MPa |
---|---|---|
35 | 52.5 | 120 |
Working Pressure | Hydraulic Test Pressure | Minimum Burst Pressure | |||||||
---|---|---|---|---|---|---|---|---|---|
Maxi-Mum Mises Stress of Liner/MPa | Maxi-Mum S1 Stress of Circum-Ferential Fiber Layer/MPa | Maxi-Mum S1 Stress of Spiral Fiber Layer/MPa | Maximum MISES Stress of Liner/MPa | Maxi-Mum S1 Stress of Circu-Mfere-Ntial Fiber Layer/MPa | Maxi-Mum S1 Stress of Spiral Fiber Layer/MPa | Maxi-Mum Mises Stress of Liner/MPa | Maxi-Mum S1 Stress of Circumferential Fiber Layer/MPa | Maxi-Mum S1 Stress of Spiral Fiber Layer/MPa | |
No Autofrett-age Pressure | 302.9 | 1045 | 772 | 318.7 | 2412 | 1897 | 330 | 7201 | 8380 |
Autofrett-age Pressure | 274.2 | 1328 | 925.2 | 318.7 | 2413 | 1564 | 330 | 6842 | 7842 |
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Wu, X.; Yang, B.; Zhou, S. Strength and Failure Analysis of Fiber-Wound Composite Gas Cylinder via Numerical Simulation. Materials 2024, 17, 717. https://doi.org/10.3390/ma17030717
Wu X, Yang B, Zhou S. Strength and Failure Analysis of Fiber-Wound Composite Gas Cylinder via Numerical Simulation. Materials. 2024; 17(3):717. https://doi.org/10.3390/ma17030717
Chicago/Turabian StyleWu, Xiaodi, Bo Yang, and Song Zhou. 2024. "Strength and Failure Analysis of Fiber-Wound Composite Gas Cylinder via Numerical Simulation" Materials 17, no. 3: 717. https://doi.org/10.3390/ma17030717
APA StyleWu, X., Yang, B., & Zhou, S. (2024). Strength and Failure Analysis of Fiber-Wound Composite Gas Cylinder via Numerical Simulation. Materials, 17(3), 717. https://doi.org/10.3390/ma17030717