Finite element simulation on the rate-dependent properties of aluminum foams

Fan Zhi-geng; Chen Chang-qing; Wan Qiang

doi:10.11883/1001-1455(2014)06-0742-06

Volume 34 Issue 6

Dec. 2014

Turn off MathJax

Article Contents

Abstract

References

Article Navigation > Explosion And Shock Waves > 2014 > 34(6): 742-747

Fan Zhi-geng, Chen Chang-qing, Wan Qiang. Finite element simulation on the rate-dependent properties of aluminum foams[J]. Explosion And Shock Waves, 2014, 34(6): 742-747. doi: 10.11883/1001-1455(2014)06-0742-06

Citation:

Fan Zhi-geng, Chen Chang-qing, Wan Qiang. Finite element simulation on the rate-dependent properties of aluminum foams[J]. Explosion And Shock Waves, 2014, 34(6): 742-747. doi: 10.11883/1001-1455(2014)06-0742-06

Citation:

PDF( 2592 KB)

Finite element simulation on the rate-dependent properties of aluminum foams

doi: 10.11883/1001-1455(2014)06-0742-06

1.
Institute of Systems Engineering, China Academy of Engineering Physics, Mianyang 621999, Sichuan, China
2.
Department of Engineering Mechanics, School of Aerospace Engineering, Tsinghua University, Beijing 100084, China

Funds: Supported by the National Natural Science Foundation of China (11102196, 11372295); the National Basic Research Program of China (973 Program) (2010CB832700)

More Information

Corresponding author: Fan Zhi-geng, fanzg@caep.cn
Received Date: 2013-04-11
Rev Recd Date: 2013-06-26
Publish Date: 2014-11-25

Abstract

Abstract

To examine the rate-dependent properties of aluminum foams, three-dimensional random spherical cell models were constructed to simulate the microstructures of aluminum foams, and the dynamic deformations of aluminum foams at the strain rates of 10-10 000 s^-1 were calculated by using the ANSYS/LS-DYNA commercial code.Obtained results show that at moderate and low strain rates, the rate-dependent properties of aluminum foams originate mainly from the strain-rate sensitivities of their matrix materials.At high strain rates, the rate-dependent properties of aluminum foams are dominated by the combining action of the strain rate sensitivity of cell materials and the microstructure inertia of cells, and the microstructure inertia effects are more remarkable for aluminum foams with low relative density than for those with high relative density.
- solid mechanics,
- rate-dependent,
- three-dimensional random spherical cell model,
- aluminum foam,
- finite element

FullText(HTML)

References(13)

References

[1]	卢天健, 何德坪, 陈常青, 等.超轻多孔金属材料的多功能特性及应用[J].力学进展, 2006, 36(4): 517-535. Lu Tian-jian, He De-ping, Chen Chang-qing, et al. The multi-functionality of ultra-light porous metals and their applications[J]. Advances in Mechanics, 2006, 36(4): 517-535.
[2]	王永胜, 左孝青, 尹志其, 等.应变率对泡沫铝压缩性能的影响[J].材料导报, 2009, 23(3): 47-52. Wang Yong-sheng, Zuo Xiao-qing, Yin Zhi-qi, et al. Effect of strain rate on compressive property of aluminum foam[J]. Materials Review, 2009, 23(3): 47-52.
[3]	Deshpande V S, Fleck N A. High strain rate compressive behavior of aluminium alloy foams[J]. International Journal of Impact Engineering, 2000, 24(3): 277-298.
[4]	郭伟国, 李玉龙, 黄福增.不同应变率下泡沫铝的形变和力学性能[J].爆炸与冲击, 2008, 28(4): 289-292. Guo Wei-guo, Li Yu-long, Huang Fu-zeng. Deformation and mechanical property of aluminium foam at different strain rates[J]. Explosion and Shock Waves, 2008, 28(4): 289-292.
[5]	Dannemann K A, Lankford Jr J. High strain rate compression of closed-cell aluminum foams[J]. Materials Science and Engineering: A, 2000, 239(1/2): 157-164.
[6]	Mukai T, Kanahashi H, Miyoshi T, et al. Experimental study of energy absorption in closed-cell aluminum foam under dynamic loading[J]. Scripta Materialia, 1999, 40(8): 921-927.
[7]	Mukai T, Miyoshi T, Nakano S, et al. Compressive response of a closed-cell aluminum foam at high st rain rate[J]. Scripta Materialia, 2006, 54(4): 533-537.
[8]	程和法.应变率对泡沫Al-Mg合金压缩性能的影响[J].特种铸造及有色合金, 2003, 5: 1-3. Cheng He-fa. The effect of strain rate on the compressive properties of foamed Al-Mg alloy[J]. Special Casting & Nonferrous Alloys, 2003, 5: 1-3.
[9]	程和法, 黄笑梅, 王强, 等.通孔泡沫铝的动态压缩行为[J].爆炸与冲击, 2006, 26(2): 169-173. Cheng He-fa, Huang Xiao-mei, Wang Qiang, et al. The dynamic compressive behaviors of an open-cell aluminum foam[J]. Explosion and Shock Waves, 2006, 26(2): 169-173.
[10]	田杰, 胡时胜.基体性能对泡沫铝力学行为的影响[J].工程力学, 2006, 23(8): 168-176. Tian Jie, Hu Shi-sheng. Effect of matrix properties of the mechanical behaviors of aluminum foams[J]. Engineering Mechanics, 2006, 23(8): 168-176.
[11]	张健, 赵桂平, 卢天健.闭孔泡沫铝应变率效应的试验和有限元分析[J].西安交通大学学报, 2010, 44(5): 97-101. Zhang Jian, Zhao Gui-ping, Lu Tian-jian. Experimental and numerical study on strain rate effects of close-celled aluminum foams[J]. Jounal of Xi'an Jiaotong University, 2010, 44(5): 97-101.
[12]	胡时胜, 王悟, 潘艺, 等.泡沫材料的应变率效应[J].爆炸与冲击, 2003, 23(1): 13-18. Hu Shi-sheng, Wang Wu, Pan Yi, et al. Strain rate effect on the properties foam materials[J]. Explosion and Shock Waves, 2003, 23(1): 13-18.
[13]	Gibson L J, Ashby M F. Cellular solids: Structure and properties[M]. 2nd ed. Cambridge: Cambridge University Press, 1997.

Relative Articles

[1]	Ding Yuan-yuan, Yang Li-ming, Wang Li-li. Experimental determination of dynamic constitutive parameters for aluminum foams[J]. Explosion And Shock Waves, 2015, 35(1): 1-8. doi: 10.11883/1001-1455(2015)01-0001-08
[2]	Zhang Chao, Xu Song-lin, Wang Peng-fei, Zhang Lei. Deformation and stress nonuniformity of aluminum foam under different impact speeds[J]. Explosion And Shock Waves, 2015, 35(4): 567-575. doi: 10.11883/1001-1455(2015)04-0567-09
[3]	Li Yan-yan, Zheng Zhi-jun, Yu Ji-lin, Wang Chang-feng. Finite element analysis on deformation modes of closed-cell metallic foam[J]. Explosion And Shock Waves, 2014, 34(4): 464-470. doi: 10.11883/1001-1455(2014)04-0464-07
[4]	ZHANG Zhi-ying, PENG Lei, LIU Run-sheng, YANG Zheng, ZHAO Fu-xing. Astudyonexplosionweldingdefectsoflarge-sizedplates[J]. Explosion And Shock Waves, 2012, 32(1): 51-54. doi: 10.11883/1001-1455(2012)01-0051-04
[5]	WANGXi-jun, ZONGZhi, NIEChun, MUTSUOFuji. Parameteridentificationofthefailurestrainof laserscaledpolypropylenematerial[J]. Explosion And Shock Waves, 2012, 32(5): 457-462. doi: 10.11883/1001-1455(2012)05-0457-06
[6]	WANG Peng-fei, HU Shi-sheng. Mechanicalpropertiesoffoamaluminum withdifferentsizes[J]. Explosion And Shock Waves, 2012, 32(4): 393-398. doi: 10.11883/1001-1455(2012)04-0393-06
[7]	XIE Fan, ZHANG Tao, CHEN Ji-en, LIU Tu-guang. Updatingofthestresstriaxialitybyfiniteelementanalysi[J]. Explosion And Shock Waves, 2012, 32(1): 8-14. doi: 10.11883/1001-1455(2012)01-0008-07
[8]	LI Qiang, LI Peng-hui, ZHAO Jun-guan, RU Zhan-yong. Residualstressvariationinanautofrettagedbarrelunderimpactload[J]. Explosion And Shock Waves, 2011, 31(6): 635-640. doi: 10.11883/1001-1455(2011)06-0635-06
[9]	HUANG Xia, TANG Wen-hui, JIANG Bang-hai. Constitutiverelationforanisotropicmaterialsunderplane-strainconditions anditsapplicationtostress-wavepropagationsimulation[J]. Explosion And Shock Waves, 2010, 30(4): 383-389. doi: 10.11883/1001-1455(2010)04-0383-07
[10]	LI Ji-cheng, CHEN Xiao-wei, CHEN Gang. Numericalsimulationsonadiabaticsheardeformationsof 921Asteelpureshearhat-shapedspecimens[J]. Explosion And Shock Waves, 2010, 30(4): 361-369. doi: 10.11883/1001-1455(2010)04-0361-09
[11]	ZHANG Xiao-tian, JIA Guang-hui, HUANG Hai. Simulationofhypervelocity-impactdebrisclouds usingaLagrangeFEM withnodeseparation[J]. Explosion And Shock Waves, 2010, 30(5): 499-504. doi: 10.11883/1001-1455(2010)05-0499-06
[12]	JING lin, WANG Zhi-hua, ZHAO Long-mao, YAN Qing-rong. Dynamicplasticresponseoffoamsandwichbeams subjectedtoimpactloading[J]. Explosion And Shock Waves, 2010, 30(6): 561-568. doi: 10.11883/1001-1455(2010)06-0561-08
[13]	SONG Yan-ze, LI Zhi-qiang, ZHAO Long-mao. Finite element analysis of dynamic crushing behaviors of closed-cell foams based on a tetrakaidecahedron model[J]. Explosion And Shock Waves, 2009, 29(1): 49-55. doi: 10.11883/1001-1455(2009)01-0049-07
[14]	LIU Wei-ming, CHENG He-fa, HUANG Xiao-mei, PAN Zhen-ya. Quasi-static compression behaviors of cylindrical tubes filled with open-cell aluminum foam[J]. Explosion And Shock Waves, 2009, 29(6): 654-658. doi: 10.11883/1001-1455(2009)06-0654-05
[15]	ZHENG Bo, WANG An-wen. Axisymmetric dynamic plastic buckling of cylindrical shells under axial compression waves[J]. Explosion And Shock Waves, 2008, 28(3): 271-275. doi: 10.11883/1001-1455(2008)03-0271-05
[16]	DONG Jie, LI Yong-chi, CHEN Xue-dong. A phenomenological damage model of microvoids and its application[J]. Explosion And Shock Waves, 2008, 28(5): 443-447. doi: 10.11883/1001-1455(2008)05-0443-05
[17]	GUO Wei-guo, LI Yu-long, HUANG Fu-zeng. Deformation and mechanical property of aluminium foam at different strain rates[J]. Explosion And Shock Waves, 2008, 28(4): 289-292. doi: 10.11883/1001-1455(2008)04-0289-04
[18]	ZHENG Bo, WANG An-wen. Finite element analysis for elastic-plastic dynamic postbuckling of bars subjected to axial impact[J]. Explosion And Shock Waves, 2007, 27(2): 126-130. doi: 10.11883/1001-1455(2007)02-0126-05
[19]	WANG Ji, WANG Xiao-jun, BIAN Liang. Linking of smoothed particle hydrodynamics method to standard finite element method and its application in impact dynamics[J]. Explosion And Shock Waves, 2007, 27(6): 522-528. doi: 10.11883/1001-1455(2007)06-0522-07
[20]	TIAN Jie, HU Shi-sheng. Investigation on mechanical properties of the composites of aluminum foam containing silicone rubber[J]. Explosion And Shock Waves, 2005, 25(5): 400-404. doi: 10.11883/1001-1455(2005)05-0400-05

Supplements(0)

Cited By

Cited by

Periodical cited type(6)

1.	姜凯. 基于Voronoi模型的梯度孔隙率泡沫铝力学性能研究. 粉煤灰综合利用. 2021(03): 64-71 .
2.	贾然，赵桂平. 闭孔泡沫铝泊松比及三轴压缩变形模式. 力学学报. 2021(08): 2289-2297 .
3.	郭亚周，杨海，刘小川，郑志军，王计真. 闭孔泡沫铝在动态加载下的压缩力学行为研究. 振动工程学报. 2020(02): 338-346 .
4.	贾然，赵桂平. 泡沫铝本构行为研究进展. 力学学报. 2020(03): 603-622 .
5.	赵文杰，梁增友，时文超，邓德志，王耀琦. 高过载环境下胀环/泡沫铝复合结构缓冲吸能研究. 弹箭与制导学报. 2018(05): 51-54+59 .
6.	汤俊，葛建立，闫彬，杨国来，李振. 弹丸侵彻闭孔泡沫铝冲击波形数值模拟. 南京理工大学学报. 2016(03): 328-333 .