EXPERIMENTAL INVESTIGATIONS ON PROPERTIES OF COPPER – SILICA FUME PARTICULATE COMPOSITES

Authors

  • Vijaya Sai N Department of Mechanical Engineering, V R Siddhartha Engineering College, Vijayawada, Andhra Pradesh - 520 007, India
  • Satyanarayana A Satyam - Venture Engineering Services Pvt. Limited, Secunderabad, Andhra Pradesh – 500 003, India

Keywords:

Density, Porosity, Hardness, Strength, Electrical conductivity

Abstract

Copper-silica fume mixtures containing 0-15 wt% silica fume were prepared.  Small cylindrical specimens of 9 mm diameter and 10.5 mm length were fabricated at 300 MPa using single acting die compaction at ambient temperature. These compacts were sintered in argon atmosphere for a period of 45 min at 8500C. The physical and mechanical properties of green and sintered compacts were determined as a function of silica fume weight percent. It was observed that green density and strength decreased, while green porosity and hardness increased with increasing weight percent of silica fume. Sintering resulted in decrease in volume and increase in density of green compacts. It was further observed that addition of silica fume resulted in increase in porosity and hardness and decrease in density and compressive yield strength of sintered compacts under the present experimental conditions. Electrical conductivity of sintered copper-silica fume compacts was also determined as a function of silica fume content. The electrical conductivity gradually decreased with increase in silica fume content.

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References

Harrigan Jr W C, Everett R K and Arsenault R J (1991), Metal Matrix Composites, Academic Press, New York.

Yih P and Chung D D L (1995), “Copper-Matrix Molybdenum Particle Composites Made from Copper Coated Molybdenum Powder”, Journal of Electronica Materials, Vol.24, 841-842.

Lee Y F, Lee S L, Chuang C L and Lin J C (1999), “Effects of SiCp Reinforcement by Electroless Copper Plating on Properties of Cu/SiCp Composites”, Powder Metallurgy, Vol.42, 147-152.

Moustafa, S F, Abdel-Hamid Z and Abd-Elhay A M (2002), “Copper Matrix SiC and Al2O3 Particulate Composites by Powder Metallurgy Technique”, Materials Letters, Vol. 53, 244-249.

Zhan Y and Zhang G (2003), “The Effect of Interfacial Modifying on the Mechanical and Wear Properties of SiCp/Cu Composites”, Materials Letters, Vol. 57, 4583-4591.

Tong Chingping, Yasuyuki Igo and Yasuo Kondo (2003), “Development of Low Expansion Copper Based Composite Materials (L-COP)”, Hitachi Cable Review, Vol. 22, 62-65.

Srivastava, V K (1992), “Effect of Fiber Angle on Fracture Properties of Unidirectional Fly Ash Filled FRP Composites”, Engineering Fracture Mechanics, Vol. 43, 1093-1096.

Dean Golden (1994), “Ash Alloys: Al-Fly Ash Composites”, EPRI Journal, pp. 46-49.

Rohatgi P K (1994), “Low Cost Fly Ash Containing Aluminum Matrix Composites”, Journal of Material Science, pp. 55-59.

Rohatgi P K, Guo, R Q, Kesavaram and Golden D M (1995), “Cast Al-Fly Ash Composites for Engineering Applications”, American Foundry Men’s society Transactions, Vol.103, 575-579.

Guo R Q, Rohatgi P K and Nath D (1997), “Preparation of Aluminum-Fly ash Particulate Composite by Powder Metallurgy Technique”, Journal of Material Science, Vol.32, 3971-3974.

Rohatgi P K, Guo, R Q, Huang P and Ray S (1997), “Friction and Abrasion Resistance of Cast Al Alloy-Fly Ash Composites”, Metallurgical and Materials Transactions, Vol. 28A, 245-250.

Devi M S, Murugesan V, Rengaraj K and Anand P (1998), “Utilization of Fly Ash as Filler for Unsaturated Polyester Resin”, Journal of Applied Polymer Science, Vol. 69, 1385-1391.

Rohatgi P K, (1998), “Aluminum Alloy-Fly ash Composite (Ash alloy) - Future Foundry Products for Automotive Applications”, Fuel and Energy Abstracts, Vol. 39, 25-25(1)

Sobczak N, Sobczak J, Morgiel J and Stobierski L (2003), “TEM Characterization of the Reaction Products in Aluminum-Fly Ash Couples”, Materials Chemistry and Physics, Vol. 81, 296-300.

Ramachandra M and Radhakrishna K (2005), “Synthesis - Microstructure - Mechanical Properties - Wear and Corrosion Behavior of an Al - Si (12%) - Fly Ash Metal Matrix Composite”, Journal of Materials Science, Vol. 40, 5989-5997.

Wu G H, Dou Z Y, Jiang L T and Cao J H (2006), “Damping Properties of Aluminum Matrix-Fly Ash composites”, Materials Letters, Vol. 60, 2945-2948.

Rohatgi P K, Gupta N and Alaraj S (2006), “Thermal Expansion of Aluminum-Fly Ash Cenosphere Composites Synthesized by Pressure Infiltration Technique”, Journal of Composite Materials, Vol. 40, 1163-1174.

Ramachandra M and Radhakrishna K (2007), “Effect of Reinforcement of Fly Ash on Sliding Wear, Slurry Erosive Wear and Corrosive Behavior of Aluminum Matrix Composite”, Wear, Vol. 262, 1450-1462.

Sudarshan and Surappa M K (2008), “Synthesis of Fly Ash Particle Reinforced A356 Al Composites and their Characterization”, Materials Science and Engineering A, Vol. 480, 117-124.

Kumar P R S, Kumaran S, Srinivasa Rao T and Sivaprasad K (2009), “Microstructure and Mechanical Properties of Fly Ash Particle Reinforced AA6061 Composites Produced by Press and Extrusion”, Transactions of The Indian Institute of Metals, Vol. 62, 559-566.

Li J and Pei T (1997), “Effect of Slag and Silica Fume on Mechanical Properties of High Strength Concrete”, Cement and Concrete Research, Vol. 27, 833-837..

Xu Y and Chung D D L (2000), “Improving Silica Fume Cement by using Silane”, Cement and Concrete Research, Vol. 30, 1305-1311.

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Published

2012-09-01

How to Cite

[1]
“EXPERIMENTAL INVESTIGATIONS ON PROPERTIES OF COPPER – SILICA FUME PARTICULATE COMPOSITES”, JME, vol. 7, no. 3, pp. 152–157, Sep. 2012, Accessed: Dec. 22, 2024. [Online]. Available: https://smenec.org/index.php/1/article/view/371

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