Fatigue delamination analysis of composite double cantilever beams based on discrete damage zone model
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摘要: 基于扩展逐层理论(Extended layerwise method,XLWM)、离散损伤模型(Discrete damage zone model,DDZM)和Peerlings损伤定律,建立了可以分析复合材料结构分层损伤疲劳扩展的疲劳渐进扩展逐层方法(Fatigue progressive extended layerwise method,FPXLWM)。首先对HTC/6736A碳纤维双悬臂梁进行分析,施加恒定弯矩,验证该方法的正确性;然后通过计算多组Paris曲线,确定模型的疲劳参数,对HTC/6736A碳纤维双悬臂梁分层疲劳扩展机制进行深入探讨。
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关键词:
- 离散损伤模型 /
- 扩展逐层方法 /
- 分层疲劳扩展 /
- HTC/6736A碳纤维双悬臂梁 /
- Paris曲线
Abstract: Based on extended layerwise method (XLWM), discrete damage zone model (DDZM) and Peerlings damage law, a fatigue progressive extended layerwise method (FPXLWM) was established to analyze the delamination fatigue growth of composites. Firstly, a HTC/6736A carbon fiber double cantilever beam subjected to a constant bending moment was analyzed to verify the proposed method in numerical examples. Then, the fatigue parameters of the proposed model were determined by several groups of Paris curves; the fatigue growth mechanisms of delamination in the HTC/6736A carbon fiber double cantilever beam were investigated. -
图 1 含离散损伤模型的求解区域Ω0
Figure 1. A solve domain Ω0 with discrete damage zone model
$\bar t $—Load; $\bar u $—Displacement ; $\varGamma_{\rm{t}} $—Load boundary ; $\varGamma_{\rm{tf}} $—Surface force region; $ \varGamma_{\rm{c}}$—Damage region; $\varGamma_{\rm{coh}} $—Cohesion region; $\varGamma_{\rm{u}} $—Displacement boundary
图 2 离散损伤模型的损伤演化关系
Figure 2. Pure mode damage evolution law for discrete damage zone model
(${\delta ^{{\rm{cr}}}},\;F^{{\rm{cr}}} $)—Critical point; $K_0 $—Initial stiffness; $(1-D_{{\rm{n}}})K_0 $—Damage stiffness; $K_{\rm{p}} $—Penalty stiffness
图 3 疲劳加载的载荷大小变化
Figure 3. Variation of the applied moment with increment during fatigue loading
图 4 离散损伤模型的疲劳本构关系
Figure 4. Fatigue damage evolution law for discrete damage zone model
1—Began to damage; 2—Damage; 2’—Failure; $F_0 $—Spring load; $\delta_0 $—Critical displacement; $\delta_{\rm{c}} $—Maximum displacement
图 5 疲劳渐进扩展逐层方法的位移场
Figure 5. Displacement field for fatigue progressive extended layerwise method
hk—Thickness of layer k; zk—Coordinate in thickness direction of layering interfaces of layers k and (k−1); The numbers on the left represent the mathematical layer interpolation nodes of the displacement field along the thickness direction, and the numbers on the right represent the interfaces between the layers
图 6 HTC/6736A碳纤维双悬臂梁(DCB)模型和加载方式
Figure 6. HTC/6736A carbon fiber double cantilever beam (DCB) model and load model
L—Length; B—Width; 2h—Thickness; a0—Initial delamination length; M—Moment
图 7 HTC/6736A双悬臂梁分层长度-载荷循环次数曲线
Figure 7. HTC/6736A double cantilever beam model delamination length versus loading cycles
图 8 疲劳渐进扩展逐层方法(FPXLWM)模拟得到HTC/6736A碳纤维双悬臂梁的Paris曲线
Figure 8. Paris plot of HTC/6736A carbon fiber double cantilever beam calculated by fatigue progressive extended layerwise method (FPXLWM)
图 9 不同C值计算得到HTC/6736A双悬臂梁的Paris曲线(β=2.0、λ=0.5)
Figure 9. Multiple groups of paris plots of HTC/6736A double cantilever beams with different values of C (β=2.0, λ=0.5)
图 10 不同β值计算得到HTC/6736A碳纤维双悬臂梁的Paris曲线(C=1.0、λ=0.5)
Figure 10. Multiple groups of paris plots of HTC/6736A carbon fiber double cantilever beams with different values of β (C=1.0, λ=0.5)
图 11 不同λ值计算得到HTC/6736A碳纤维双悬臂梁的Paris曲线(C=1.0、β=2.0)
Figure 11. Multiple groups of paris plots of HTC/6736A carbon fiber double cantilever beams with different values of λ (C=1.0, β=2.0)
图 12 实验数据匹配得到HTC/6736A碳纤维双悬臂梁的Paris曲线
Figure 12. Paris plots of HTC/6736A carbon fiber carbon fiber double cantilever beam with experimental and FPXLWM
图 13 不同加速倍数ΔN计算得到HTC/6736A碳纤维双悬臂梁的a-N曲线(循环载荷30 N、网格尺寸ls=0.25 mm)
Figure 13. Delamination growths of HTC/6736A carbon fiber double cantilever beams with loading cycles for different computing speed ΔN
(Applied load is 30 N, mesh scale ls=0.25 mm) 
图 14 HTC/6736A碳纤维双悬臂梁不同网格尺寸ls对应疲劳参数C的值(循环载荷30 N、加速倍数ΔN=200)
Figure 14. Variation of fatigue parameter C with different values of mesh scale ls of HTC/6736A carbon fiber double cantilever beam (Applied load is 30 N, computing speed ΔN=200)
图 15 不同网格尺寸计算得到HTC/6736A碳纤维双悬臂梁的a-N曲线
Figure 15. Delamination growths of HTC/6736A carbon fiber double cantilever beams with loading cycles for different mesh scale ls
图 16 铺层顺序为[0]4的HTC/6736A碳纤维双悬臂梁宽度方向三个位置的a-N曲线(循环载荷20 N、网格尺寸ls=0.25)
Figure 16. Delamination length of HTC/6736A carbon fiber double cantilever beam at three positions in width direction for stacking sequence [0]4 (Applied load is 20 N, mesh scale ls=0.25)
图 17 不同铺层顺序HTC/6736A碳纤维双悬臂梁宽度方向上两个位置的a-N曲线(循环载荷20 N)
Figure 17. Delamination length of HTC/6736A carbon fiber double cantilever beam with loading cycles at two positions in width direction with different stacking sequences (Applied load is 20 N)
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