Arc erosion behavior of TiB2/Cu composites

被引：0

作者：

Li G. ^{[1
,2
]}

Liu Y. ^{[1
,3
]}

Guo X. ^{[2
,3
]}

Feng J. ^{[1
,2
]}

Song K. ^{[1
,3
]}

Tian B. ^{[1
,3
]}

机构：

[1] School of Materials Science and Engineering, He'nan University of Science and Technology, Luoyang

[2] He'nan Key Laboratory of Non-Ferrous Materials Science and Processing Technology, Luoyang

[3] Collaborative Innovation Center of Nonferrous Metals, He'nan Province, Luoyang

来源：

Liu, Yong (liuyong@haust.edu.cn.) | 2018年 / Beijing University of Aeronautics and Astronautics (BUAA)卷 / 35期

关键词：

Arc duration; Arc erosion; Composites; Material transfer; Spark plasma sintering; TiB[!sub]2[!/sub]/Cu;

D O I：

10.13801/j.cnki.fhclxb.20170531.003

中图分类号：

学科分类号：

摘要：

The TiB2/Cu composites with TiB2 mass fraction of 1wt%-5wt% were prepared by spark plasma sintering (SPS), and the electrical conductivity and hardness were tested. The electrical conductivity of TiB2/Cu composites decreases from 96.9% (International Annealed Copper Standard, IACS) to 65.1%(IACS) with TiB2 mass fraction increasing from 0 to 5wt%, while the Brinell hardness increases from 42.8 to 65.2. To discuss the effect of TiB2 content and current on TiB2/Cu composites arc erosion, the electrical contact tests were performed at 24 V and different direct current for TiB2/Cu composites with the different TiB2 mass fractions. For TiB2/Cu composites with different TiB2 mass fraction, the average arc duration, average arc energy and mass loss increase with the increase of current. The cathode of TiB2/Cu composites mass loss more than that of the anode. In general, the TiB2/Cu composites are transferred from cathode to anode. At 24 V and 25 A, the arc duration and arc energy of TiB2/Cu composites with different TiB2 mass fractions are fluctuant with the increase of operation times. On the whole, it shows a tendency to increase gradually. The 3wt% TiB2/Cu composite has higher stability, the average arc duration and average arc energy are lower than the others. With the increase of mass fraction of TiB2, TiB2/Cu composites present less mass loss and shallower arc erosion pits. © 2018, Editorial Office of Acta Materiae Compositae Sinica. All right reserved.

引用

页码：616 / 622

页数：6

共 20 条

[1] Si F., Wang J.B., Liu S.T., Et al., Preparation process research status and development trend of Ag-SnO2 electrical contact materials, Electronic Components and Materials, 34, 9, pp. 31-34, (2015)
[2] Yang Z.Q., Liu Y., Tian B.H., Et al., Critical conditions of dynamic recrystallization of TiC/Cu-Al2O3 composites, Acta Materiae Compositae Sinica, 31, 4, pp. 963-969, (2014)
[3] Guo Y.L., Li D.M., Li H.Y., Et al., Progress in Cu-based contact materials of low voltage apparatus, Electrical Engineering Materials, 3, pp. 10-13, (2011)
[4] Han B., Shi Q.N., Xie M., Et al., Arc erosion characteristics of W-15wt%Cu electric contact materials under DC condition, Rare Metal Materials and Engineering, 41, 6, pp. 994-997, (2012)
[5] Swingler J., Sumption A., Arc erosion of AgSnO2 electrical contacts at different stages of a break operation, Rare Metals, 29, 3, pp. 248-254, (2010)
[6] Biyik S., Arslan F., Aydin M., Arc-erosion behavior of boric oxide-reinforced silver-based electrical contact materials produced by mechanical alloying, Journal of Electronic Materials, 44, 1, pp. 457-466, (2015)
[7] Hauner F., Jeannot D., Mcneilly K., Et al., Advanced AgSnO2 contact materials for the replacement of AgCdO in high current contactors, Proceedings of the 56th IEEE Holm Conference on Electrical Contacts. Chicago: IEEE, pp. 225-230, (2000)
[8] Mutzel T., Niederreuther R., Development of contact material solutions for low voltage circuit breaker applications (2), Proceedings of the 57th IEEE Holm Conference on Electrical Contacts., pp. 1-6, (2011)
[9] Bai X.P., Lin W.H., Zhang M.J., Cotact materials for low voltage electric apparatus, Electrical Engineering Materials, 3, pp. 12-16, (2007)
[10] Omer G., Ertan E., The investigation of contact performance of oxide reinforced copper composite via mechanical alloying, Journal of Materials Processing Technology, 209, 3, pp. 1286-1290, (2009)

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