Quantitative characterization of morphology of explosive welding interfaces based on fractal theory

被引：0

作者：

Xia M. ^{[1
]}

Fu Y. ^{[1
]}

Zeng X. ^{[1
]}

Zhang B. ^{[1
]}

机构：

[1] School of Mechanical & Electrical Engineering, Nanchang University, Nanchang, 330031, Jiangxi

来源：

Baozha Yu Chongji/Explosion and Shock Waves | 2016年 / 36卷 / 01期

关键词：

Explosive welding; Fractal dimensions; Interface morphology; Mechanics of explosion; Quantitative characterization;

D O I：

10.11883/1001-1455(2016)01-0050-07

中图分类号：

学科分类号：

摘要：

Explosive welding interface structure determines the quality of composite materials. However, analyses on the interfaces morphology so far remain limited on the qualitative level and quantitative analysis methods have not been well established. In our work we took explosive welding interface morphology as research subject, extracted the fractal dimensions and multi-fractal spectrums of interface based on the fractal theory to understand its morphological characteristics. First, we obtained the interface structure by three-dimensional ultra-depth microscopy. Then we dealt with it by picture analysis techniques to gain its binary image. Furthermore, we calculated the fractal dimensions and multi-fractal spectrum of the images by fractal geometry. Following the fractal theory, the fractal dimension is the macroscopic characteristics of the welding interfaces and the multi-fractal spectrum reflects their degree of fluctuation and the ratio of distribution. Thus taking fractal dimension and multi-fractal spectrum into account when describing welding interface structure can make up for what is lacking in the qualitative analysis and achieve the quantitative analysis. © 2016, Explosion and Shock Waves. All right reserved.

引用

页码：50 / 56

页数：6

共 14 条

[1] Shi C., Wang Y., Li Z., Et al., Study on the technique of blasting demolishing the long aqueduct with the control of domino effect, Explosive Materials, 33, 5, pp. 25-28, (2004)
[2] Wang Y., Hong J., Shi C., Three bond interface of explosive welding of steel SA266/304, Materials Science and Technology, 6, 4, pp. 35-38, (1998)
[3] Fu Y., Sun Y., Chen Z., Et al., An experimental investigation on Al-Al explosive welding interfaces, Journal of Experimental Mechanics, 26, 1, pp. 49-53, (2011)
[4] Zhang Y., Yang X., Li X., Et al., An experimental research on explosive welding of titanium/steel clad plate, Explosion and Shock Waves, 32, 1, pp. 103-107, (2012)
[5] Zhang Y., Babu S.S., Prothe C., Et al., Application of high velocity impact welding at varied different length scales, Journal of Materials Processing Technology, 211, 5, pp. 944-952, (2011)
[6] Chizari M., Al-Hassani S.T.S., Barrett L.M., Effect of flyer shape on the bonding criteria in impact welding of plates, Journal of Materials Processing Technology, 209, 1, pp. 445-454, (2009)
[7] Akbari-Mousavi S.A.A., Barrett L.M., Al-Hassani S.T.S., Explosive welding of metal plates, Journal of Materials Processing Technology, 2029, 1, pp. 224-239, (2008)
[8] Drennov O.B., Mikhailov A.L., Nizovtsev P.N., Et al., Instability of an interface between steel layers acted upon by an oblique shock wave, International Journal of Impact Engineering, 32, 1, pp. 161-172, (2005)
[9] Drennov O.B., Davydov A.I., Mikhailov A.L., Et al., Shear instability at the "explosion product-metal" interface for sliding detonation of an explosive charge, International Journal of Impact Engineering, 32, 1, pp. 155-160, (2005)
[10] Ben-Artzy A., Stern A., Frage N., Et al., Wave formation mechanism in magnetic pulse welding, International Journal of Impact Engineering, 37, 4, pp. 397-404, (2010)

← 1 2 →