Producing the titanium nano composite statically compacted with the different pressure and investigation of the mechanical properties
Subject Areas : Journal of Simulation and Analysis of Novel Technologies in Mechanical Engineeringسید مهران زحلی 1 , فرزاد فریبا 2
1 - کارشناسی ارشد، مهندسی مکانیک، دانشگاه آزاد اسلامی واحد همدان
2 - استادیار، دانشکده مکانیک، دانشگاه آزاد اسلامی واحد همدان
Keywords: Nano composites, Powder Metallurgy, static compression pressure, titanium and silicon carbide reinforcing,
Abstract :
Building the Nano composites for getting material with combinational properties and improving properties of currently used material has been taken significant attention. One of the ways of building Nano composites is using a method known as powder metallurgy. Because with this method not only wastes are decreased to minimum but we can also mix the materials with high melting point with the materials with low melting point which is a difficult thing to do with foundry method. In this research titanium alloy for improvement in its mechanical properties is mixed with silicon carbide reinforcing. Knowing the fact that silicon carbide is in Nano scale these two materials start building Nano composites. The powder metallurgy method is the best way for mixing these two materials together. To make sure that the properties of the made alloy is similar to the foundry alloy, the static compression methods are used. For comparison the results, two factors such as the Nano silicon carbide percentage and the static compression pressure are. Also, Density experiment, observation of grain boundaries using a scanning electron microscope, pressure test and the hardness experiment was done on it.
[1] Da Vincil. L., Fracture Mechanic, Bibilioteca Ambrosiana, 1894, 54.
[2]Galilei G., Dialogues concerning two new sciences, Evanston, University of Illinois Press, 35-78.
[3]Griffith A.A., The phenomena of Ruture and Flow In Solid, Phil Trans. Royal Soc.,221, 1921, Pp 163-167.
[4] Anderson T.L, Fracture Mechanics, CRC Press 1994.
[5] Inglis C.E., Stresses In A Plate Due To The Presence Of Cracks And Sharp Corners, Transactions of The Institute of Naval-Architects, 55, 1913, pp.219-241
[6]Irwin G.R., Fracture Dynamics, fracture of metals, American society for metals, Cleveland, 1948 , pp.147-166.
[7]Orowan E., Fracture of solids, reports on progress in physics, Vol. XII., 1948, pp.185-232.
[8]Mott N.F., Fracture of Metals: Theoretical Considerations, Engineering, 165, 1948, pp.16-18.
[9]Irwin G.E., Onset of fast crack propagation in high strength steel and aluminum alloys, sagamore research conference proceeding, 2, 1956, pp. 289-305.
[10]Westergaard H.M., Bearing pressures and cracks, journal of applied mechanics, 6,1939, pp. 49-53.
[11]Irwin G.R., Fracture Dynamics, fracture of metals, American society for metals, 1948, , pp.147-166.
[12]Williams M.L., On the stress distribution at the base of a stationary crack, journal of applied mechanics, 24, 1957, pp.109-114.
[13]Wells A.A., The condition of fast fracture in aluminul alloys wiyh particular reference to comet failures, British welding research association report, April 1955, pp. 76.
[14]Winne D.H., Wundt B.M. Application of the Griffith-Irwin theory of crack propagation to the bursting behavior of disks, including analytical and experimental studies, Transactions of the American society of mechanical engineers, 80, 1958, pp. 1643-1655.
[15] Paris P.C., A rational analytic theory of fatigue”, The trend in engineering, vol. 13, 1961, pp. 9-14.
[16] Wells A.A., Unstable crack propagation in metals: cleavage and fast fracture. Proc Crack Propagation Symposium, 1, 1961, pp.84.
[17] Rice JR, Rosengren GF, Plane strain deformation near a crack tip in a power law hardening materials. Journal of Mechanical Physic Solids, 16,1968, pp. 1–12.
[18]Oliver J., Continuum Modeling of Strong Discontinuities in Mechanics, International journal for numerical methods in engineering 17, 1995, pp. 49-61.
[19]Rashid MM., The Arbitrary local mesh refinement method, An computer method in applied Mechanics and Engineering, 5, 1995, pp.45-58.
[20]Moes N., Dolbow J., Belytschko T., A finite element method for crack growth without re-