Fractal characters and thermal conductive properties of self-assembled material texture of silicon nitride/stainless steel (SUS316L) composites

被引：0

作者：

Takeda M. ^{[1
]}

Okubo K. ^{[1
]}

Nemoto K. ^{[1
]}

Mizukami Y. ^{[2
]}

Sato Y. ^{[2
]}

Abe S. ^{[1
]}

Bao Y. ^{[2
]}

Kobayashi R. ^{[1
]}

Munakata F. ^{[1
]}

机构：

[1] Faculty of Engineering, Tokyo City University, 1-28-1 Tamatsutsumi, Setagaya-ku

[2] Faculty of Knowledge Engineering, Tokyo City University, 1-28-1 Tamatsutsumi, Setagaya-ku

来源：

Funtai Oyobi Fummatsu Yakin/Journal of the Japan Society of Powder and Powder Metallurgy | 2020年 / 67卷 / 06期

关键词：

Aggregated morphology; Multifractal analysis; Self-assembly; Thermal conductivity; β-Si[!sub]3[!/sub]N[!sub]4[!/sub]/SUS316L composite material;

D O I：

10.2497/jjspm.67.307

中图分类号：

学科分类号：

摘要：

The dispersion of self-assembled β-Si3N4 (SN) agglomerates in stainless steel (SUS316L) was decided with the multifractal analysis to investigate characters of the aggregated morphology of the average secondary particle area of SN particles. The thermal conductivity (λe) of SN/SUS316L with the average particle diameter of SUS316L powder of 3 μm was higher than that expected from Kanenari model because SN agglomerations were formed. On the other hand, λe of SN/SUS316L with the average particle diameter of SUS316L powder of 8 μm was lower than that expected from Kanenari model. On the multifractal analysis, the results showed that the capacity dimension (D0) was not changed with adding SN particles. It suggested that the SN agglomerations were formed with similarity. λe was increased with increasing the average secondary particle area of SN particles. D0 was not increased with increasing λe. It indicated that the forming the network of the thermal conductive particles played an important role in improving λe,. ©2020 Japan Society of Powder and Powder Metallurgy

引用

页码：307 / 312

页数：5

共 13 条

[1]

Furuya K., Munakata F., Matsuo K., Akimune Y., Ye J., Okada A., J. Therm. Anal. Calorim, 69, pp. 873-879, (2002)

[2]

Komeya K., Noda F., SAE Paper, (1974)

[3]

Shimamura A., Hotta Y., Hyuga H., Kondo N., Hirao K., The Ceramic Society of Japan, 123, pp. 908-912, (2015)

[4]

He H., Fu R., Shen Y., Han Y., Song X., Composites Science and Technology, 67, pp. 2493-2499, (2007)

[5]

Kobayashi S., Et al., Acta Materialia, 102, pp. 397-405, (2016)

[6]

Takeda M., Yoshino K., Mizukami Y., Sato Y., Ito A., Bao Y., Munakata F., J. Jpn. Soc. Powder Powder Metellurgy, 66, pp. 122-127, (2019)

[7]

Jalan S., Et al., Chaos, Solitons and Fractals, 97, pp. 11-14, (2017)

[8]

Kanari K., Ozawa T., Netsu Bussei, 3, pp. 106-111, (1989)

[9]

Kanari K., Polymer, 23, pp. 557-561, (1977)

[10]

Suzuki M., Et al., J. Soc. Powder Technol., Japan, 25, pp. 287-291, (1988)

← 1 2 →