Use of the fractal dimension for porosity modification in aluminum foams manufactured using space holder particles

IF 0.7 Q4 MECHANICS Theoretical and Applied Mechanics Pub Date : 2021-01-01 DOI:10.2298/TAM210129005R
C. Reyes, L. Béjar, L. Pérez, C. Aguilar, C. J. Carranza, E. L. Carranza, I. Alfonso
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引用次数: 2

Abstract

The effect of space holder particles (SHP) fractal distribution on the porosity of aluminum foams manufactured by infiltration is studied in the present work. Physical models were used to estimate aluminum foam porosity, simulating SHP distribution for bimodal mixtures with different particle sizes and relative quantities. Results of these models were compared with mathematical models and the results obtained for experimental aluminum foams manufactured using a 332 Al-alloy base material and NaCl grains as SHP. Experimental foam structural characterization was carried out using image analysis to obtain porosity, density, wall thickness and fractal dimension, while mechanical characterization focused on the compressive Young modulus. Results show that it was possible to manufacture foams with different fractal porosities and a wide variety of unit cells, reaching a maximum of ? 68%. It was also found that pore wall thicknesses significantly decreased with the increase in the fine particles fraction. Besides, all the models presented a peak with a maximum porosity, whose values increased and shifted to low fine particles fraction with the increase in the sizes ratio. This behavior was also observed for the experimental foams with low particle size ratio. Nevertheless, for higher size ratios porosity showed an irregular behavior attributed to the mixing process.
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分形维数在用空间支架颗粒制造的泡沫铝孔隙度改性中的应用
本文研究了空间保持颗粒(SHP)分形分布对渗透法制备泡沫铝孔隙率的影响。采用物理模型估算泡沫铝孔隙率,模拟不同粒径和相对量的双峰混合物的SHP分布。将这些模型的结果与数学模型以及以332铝合金基材和NaCl晶粒为SHP制备泡沫铝的实验结果进行了比较。实验泡沫结构表征主要通过图像分析获得孔隙率、密度、壁厚和分形维数,力学表征主要集中在压缩杨氏模量上。结果表明,该方法可以制备出具有不同分形孔隙率和多种单位孔的泡沫材料,最大可达?68%。随着细颗粒分数的增加,孔壁厚度显著减小。此外,所有模型均呈现出孔隙率最大值峰值,随着粒径比的增大,孔隙率峰值逐渐增大,并向低细粒率偏移。在低粒径比的实验泡沫中也观察到这种行为。然而,对于较高的尺寸比,孔隙率表现出归因于混合过程的不规则行为。
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来源期刊
CiteScore
0.90
自引率
0.00%
发文量
4
审稿时长
32 weeks
期刊介绍: Theoretical and Applied Mechanics (TAM) invites submission of original scholarly work in all fields of theoretical and applied mechanics. TAM features selected high quality research articles that represent the broad spectrum of interest in mechanics.
期刊最新文献
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