Effect of Cu Content on Pore Structure of Aluminum Foams After Rolling Process

doi:10.12068/j.issn.1005-3026.2021.10.008

Abstract

Abstract: The liquid phase composite-rolling technology is used to prepare foamable preforms with different content of w_○Cu and closed-pore aluminum foams. The effect of w_○Cu on the pore structure of the aluminum foams was studied. The results show that with the increase of w_○Cu， the uniformity of the pore structure increases， and the pore size and the number of large pores produced by pore merging decrease， while the collapsing and aging characteristics of the foam are enhanced. After comparing the expansion curves of preforms with different w_○Cu， it is found that when the w_○Cu increases， _○the maximum expansion rate of the preform firstly increases and then decreases and the foaming time to reach the maximum expansion rate is greatly shortened. The microstructure analysis shows that CuAl₂O₄ and CuAl₂can be formed after adding Cu into AlSi₉ alloy. CuAl₂O₄ increases the viscosity of the melt， reduces the effect of gravity drainage and capillary action， and improves the stability of the foam. CuAl₂ melts prior to AlSi₉ alloy， forming a molten pool on the grain boundary， and the bubbles nucleate and grow in advance， so that the foaming process is completed ahead of schedule.

Key words: aluminum foam; liquid phase composite-rolling technology; Cu content; pore structure; expansion rate

CLC Number:

TG146.2

WEI You， LUO Hong-jie， LU Xiao-tong， YANG Shi-jie. Effect of Cu Content on Pore Structure of Aluminum Foams After Rolling Process[J]. Journal of Northeastern University(Natural Science), 2021, 42(10): 1421-1426.

References

[1]Banhart J.Manufacture，characterisation and application of cellular metals and metal foams［J］.Progress in Materials Science，2001，46(6):559-632.
[2]Qin J，Chen Q，Yang C，et al.Research process on property and application of metal porous materials［J］.Journal of Alloys & Compounds，2016，654:39-44.
[3]Miyoshi T，Itoh M，Akiyama S，et al.Alporas aluminum foam:production process，properties，and applications［J］.Advanced Engineering Materials， 1998，521(4):179-183.
[4]Gergely V，Clyne B.The formgrip process:foaming of reinforced metals by gas release in precursors［J］.Advanced Engineering Materials，2000，2(4):175-178.
[5]Chu X M，Wang H，He S Y，et al.Study on fabrication of shaped Al alloy foam by two-step foaming method［J］.International Journal of Modern Physics B，2009，23(6):972-977.
[6]Kennedy A R，Lopez V H.The decomposition behavior of as-received and oxidized TiH₂ foaming-agent powder［J］.Materials Science & Engineering A，2003，357(2):258-263.
[7]Helwig H M，Garcia-Moreno F，Banhart J.A study of Mg and Cu additions on the foaming behaviour of Al-Si alloys［J］.Journal of Materials Science，2011，46(15):5227-5236.
[8]张建坤.二次发泡法制备泡沫铝夹芯板材的工艺基础研究［D］.沈阳:东北大学，2019.(Zhang Jian-kun.Study on process basis of preparation of aluminum foamed sandwich by two-step foaming method［D］.Shenyang:Northeastern University，2019.)
[9]Deng F，Fan J，Liu Y，et al.Effect of Cu on pore structure of Al-Si foam［J］. Metals and Materials International， 2020，28(4):75-83.
[10]Liu W H，Qiu Q，Chen Y Q，et al.Simulation of PFZ on intergranular fracture based on XFEM and CPFEM［J］.Journal of Central South University， 2016，23(10):2500-2505.
[11]陆文华.铸造合金及其熔炼［M］.北京:机械工业出版社，1996:275-276.(Lu Wen-hua.Casting alloys and their smelting［M］.Beijing:China Machine Press，1996:275-276.)
[12]Paulsson H，Rosen E.A study of the formation of CuAl₂O₄ from CuO and Al₂O₃ by solid state reaction at 1000°C and 950°C［J］.Chemischer Informationsdienst，1973，401(2):172-178.
[13]姚广春.泡沫铝材料［M］.北京:科学出版社，2013:58-59.(Yao Guang-chun.Aluminum foam material［M］.Beijing:Science Press，2013:58-59.)
[14]Rack A，Helwig H M，Butow A，et al.Early pore formation in aluminium foams studied by synchrotron-based microtomography and 3-D image analysis［J］.Acta Materialia，2009，57(16):4809-4821.(上接第1413页)

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