高速冲击载荷下梯度金属泡沫夹芯梁的动态响应与失效

魏建辉; 李旭; 黄威; 徐宏建; 方搏鹏

doi:10.11883/bzycj-2022-0156

高速冲击载荷下梯度金属泡沫夹芯梁的动态响应与失效

doi: 10.11883/bzycj-2022-0156

魏建辉^1,,
李旭¹,
黄威^2, ,,
徐宏建^{2, 3},
方搏鹏²

1.
武汉第二船舶设计研究所，湖北武汉 430061
2.
华中科技大学船舶与海洋工程学院，湖北武汉430074
3.
天津航海仪器研究所，天津 300131

基金项目: 国家自然科学基金（12272147; 11802100）

详细信息

作者简介:
魏建辉（1986－　），男，博士，高级工程师，weijh@163.com

通讯作者:
黄　威（1987－　），男，博士，副教授，weihuang@hust.edu.cn

中图分类号: O382; O347.3
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- 被引次数: 0
出版历程
- 收稿日期: 2022-04-16
- 修回日期: 2022-06-06
- 网络出版日期: 2022-06-07
- 刊出日期: 2023-05-05

Dynamic response and failure of sandwich beams with graded metal foam core under high-velocity impact

WEI Jianhui^1
,,
LI Xu¹,
HUANG Wei^{2
, ,},
XU Hongjian^{2, 3},
FANG Bopeng²

1.
Wuhan Second Ship Design and Research Institute, Wuhan 430061, Hubei, China
2.
School of Naval Architecture and Ocean Engineering, Huazhong University of Science and Technology, Wuhan 430074, Hubei, China
3.
Tianjin Navigation Instrument Research Institute, Tianjin 300131, China

摘要

摘要: 采用泡沫弹冲击加载实验对梯度金属泡沫夹芯梁结构开展了不同冲击强度下的动态响应和失效研究，分析了由三种不同密度泡沫铝组成的等面密度的五种不同梯度的夹芯结构在夹支边界条件下的抗高速冲击性能，结合三点弯曲实验，研究梯度效应对夹芯结构抗冲击性能的影响。研究表明：密度梯度对结构的失效过程和失效模式有着明显的影响，且夹芯梁结构的初始失效模式对结构整体响应和主要的能量吸收机制起着主导作用；当冲击条件不足以使得均质芯材发生压缩时，均质及负梯度夹芯结构初始失效模式为整体弯曲变形，低强度芯层位于前两层的梯度结构随着冲击强度的变化出现不同程度的局部芯层压缩；当冲击强度较低时，梯度结构通过丰富的局部失效表现出明显优于均质结构的抗冲击变形能力；当冲击强度大于临界值时，均质结构具有更好的抗冲击变形能力。通过合理地设计密度梯度实现逐层压缩吸能，能够有效的提升防护结构的抗冲击性能。
- 梯度夹芯结构 /
- 抗冲击性能 /
- 动态响应 /
- 失效模式
Abstract: The dynamic response and failure of sandwich beams with gradient metal foam core subjected to high-velocity impact are studied experimentally. The impact resistance of five sandwich beams with different density gradient arrangements but the same surface density composed of three aluminum foams with different densities is analyzed. All the sandwich beams are simply-clamped. Combined with the quasi-static three-point bending tests, the impact resistance of the gradient sandwich beams is evaluated in terms of dynamic deformation and failure modes by considering the effects of core density gradient and impulsive intensity. The results show that the density gradient effect significantly influences the dynamic response and failure mode. The initial failure mode plays an important role in the structural response and the predominant energy absorption mechanism. Since the impact condition can not produce the local compression of the medium-density core, the initial failure mode of the uniform and negative gradient sandwich structures is the overall bending deformation, while the local core compression is the initial failure mode of the other structures with weak cores located in the first two layers. When the impulsive intensity is low, the gradient sandwich beam has superior impact resistance to the uniform counterpart. With increasing intensity, once a critical intensity is exceeded, the gradient sandwich beam shows low bending resistance to the uniform counterpart. Therefore, the optimal design of the core density gradient can efficiently improve the impact resistance of the sandwich beams under the high-velocity impact, which is a valuable reference for engineering applications.
- sandwich beam with gradient metal foam core /
- impact resistance /
- dynamic response /
- failure mode

HTML全文

图 1 金属泡沫梯度夹芯梁结构

Figure 1. Gradient metal foam sandwich beam

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图 2 泡沫梯度夹芯梁结构高速冲击加载实验装置示意图

Figure 2. Experimental setup for the graded foam sandwich beams

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图 3 典型泡沫铝梯度夹芯梁结构三点弯曲失效过程

Figure 3. Failure of typical gradient metal foam sandwich beams under the three-point bending

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图 4 典型泡沫铝梯度夹芯梁结构三点弯曲载荷-位移关系

Figure 4. Load-displacement curve of the typical gradient metal foam sandwich beam under the three-point bending

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图 5 低速冲击下金属梯度夹芯梁结构动态变形与失效

Figure 5. Dynamic deformation and failure modes of the gradient metal foam sandwich beams under the low impulsive intensity

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图 6 中速和高速冲击下金属梯度夹芯梁结构动态变形与失效

Figure 6. Dynamic deformation and failure modes of the gradient metal foam sandwich beams under the medium and high impulsive intensities

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图 7 不同冲击速度下梯度夹芯梁结构背板中点动态响应和变形

Figure 7. Central dynamic response and deformation of the gradient metal foam sandwich beams under the impulsive loads

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图 8 均质泡沫铝夹芯梁结构低速冲击载荷作用下的失效模式

Figure 8. Failure modes of UM under the low impulsive intensity

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图 9 梯度泡沫铝夹芯梁结构低速冲击载荷作用下的失效模式

Figure 9. Failure modes of the gradient metal foam sandwich beams under the low impulsive intensity

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图 10 梯度泡沫铝夹芯梁结构冲击载荷作用下的失效模式

Figure 10. Failure modes of the gradient metal foam sandwich beams under the impulsive loads

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图 11 梯度夹芯梁结构抗冲击失效模式

Figure 11. Failure modes of the gradient metal foam sandwich beams subjected to high-velocity impact

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表 1 金属梯度夹芯结构高速冲击实验初始条件及结果

Table 1. Experimental conditions and results of the graded metal foam sandwich beams

编号	芯层	m₀/g	v₀/ (m·s⁻¹)	I₀ / (N·s)	w_b/ mm	编号	芯层	m₀/g	v₀/ (m·s⁻¹)	I₀ / (N·s)	w_b/ mm	编号	芯层	m₀/g	v₀/ (m·s⁻¹)	I₀ / (N·s)	w_b/ mm
w-UM	MMM	21.00	157.0	3.30	10.89	m-UM	MMM	21.54	226.4	4.88	12.57	s-UM	MMM	19.00	266.3	5.06	9.21
w-HML	HML	21.14	160.6	3.39	5.90	m-HML	HML	19.14	234.4	4.49	25.97	s-HML	HML	19.26	261.4	5.04	26.81
w-LMH	LMH	21.83	175.9	3.84	2.58	m-LMH	LMH	22.36	229.6	5.13	52.78	s-LMH	LMH	21.47	260.8	5.60	23.46
w-MLH	MLH	19.95	179.7	3.59	7.01	m-MLH	MLH	20.44	240.0	4.91	15.50	s-MLH	MLH	21.20	261.6	5.54	31.83
w-MHL	MHL	21.29	176.4	3.76	9.22	m-MHL	MHL	22.27	233.3	5.20	20.94	s-MHL	MHL	22.69	263.5	5.98	38.53
注：(a) w_b为塑性变形；(b) 本表中均质梯度（UM）、正梯度（LMH）和负梯度（HML）夹芯结构数据均来自于文献[19]。

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参考文献(19)

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