Sage Journals: Discover world-class research

Abstract

In the present investigation, copper alloy composites with tungsten carbide particle reinforcement have been prepared using the liquid metallurgy technique and the thermal properties have been evaluated. The reinforcing tungsten carbide particles had an average size of 25 µm and the content of the reinforcing particles in the composite was varied from 0 to 8 wt% in steps of 2%. It was observed that the coefficient of thermal expansion reduced significantly with the increase in the reinforcement content and the same was true even in the case of thermal conductivity and diffusivity. When measured against temperature, coefficient of thermal expansion decreased as the temperature was increased from 100 °C to 600 °C, while the thermal conductivity and thermal diffusivity of the composites increased with temperature.

Keywords

Thermal management tungsten carbide copper composites

Get full access to this article

View all access options for this article.

References

Chung

DDL

. Materials for thermal conduction. Appl Therm Eng 2001; 21: 1593–1605.

Chen

Xiu

Meng

. Fabrication and thermo-physical properties of TiB_2p/Cu composites for electronic packaging applications. Trans Nonferrous Met Soc China 2009; 19: 448–452.

Chrysanthou

Erbaccio

. Production of copper-matrix composites by in-situ processing. J Mater Sci 1995; 30: 6339–6344.

Turner

Taylor

Gordon

. Thermal conductivities of Ti-SiC and Ti-TiB₂ particulate composites. J Mater Sci 1993; 28: 3969–3976.

Randall

Karl

John

. Powder metallurgy processing of thermal management materials for microelectronic applications. Int J Powder Metall 1994; 30(2): 205–215.

Yih

Chung

DDL

. Titanium Diboride copper-matrix composites. J Mater Sci 1997; 32: 1703–1709.

Yih

Chung

DDL

. Powder metallurgy fabrication of metal matrix composites using coated fillers. Int J Powder Metall 1995; 31(4): 335–340.

Deshpande

Lin

. Infrared processed Cu composites reinforced with WC particles. Mater Sci Eng A 2006; 429: 58–65.

Gusmano

Bianco

Polini

. Chemical synthesis and sintering behavior of highly dispersed W/Cu composites. J Mater Sci 2001; 36: 901–907.

10.

Hashmi

Looney

Hashmi

MSJ

. Metal matrix composites: production by the stir casting method. J Mater Process Technol 1999; 92-93: 1–7.

11.

Cairney

Smith

Munroe

. Transmission electron microscope Specimen preparation of metal matrix composites using the focused ion beam Miller. Microsc Microanal 2000; 5: 452–462.

12.

Gasser

Klotz

Khalid

. Site specification specimen preparation by focused ion beam milling for transmission electron microscopy of metal matrix composites. Microsc Microanal 2004; 10: 311–316.

13.

Giannuzzi

Stevie

. A review of focused ion beam milling technique for TEM specimen preparation. Micron 1999; 30: 197–204.

14.

Girish

Prakash

Satish

. An investigation into the effects of graphite particles on the damping behavior of ZA-27 alloy composite material. Mater Design 2011; 32: 1050–1056.

15.

Zhao

Zhoa

Cao

. Thermal expansion of novel hybrid SiC foam-SiC particles-Al composites. Compos Sci Technol 2007; 67: 3404–3408.

16.

Hsieh

Tuan

. Thermal expansion behavior of a model ceramic-metal composite. Mater Sci Eng A 2007; 460: 453–458.

17.

Hasselman

DPH

Lloyd

. Effective thermal conductivity of composites with interfacial thermal barrier resistance. J Compos 1987; 21: 508–515.

18.

Zhao

Shi

. Reinforcing copper matrix composites through molecular-level mixing of functionalized nanodiamond by co-deposition route. Mater Sci Eng 2008; 490: 293–299.

Tungsten carbide reinforced copper composites for thermal management applications

Abstract

Keywords

Get full access to this article

References