Machining Performance and Surface Integrity of SiC Ceramic Machined Using Electrical Discharge Milling and the Mechanical Grinding Compound Process

Abstract

A new combined process that integrates electrical discharge milling and mechanical grinding is presented. The process is able effectively to machine a large surface area on SiC ceramic with a good surface quality and low cost. The effects of machining conditions on the material removal rate, relative electrode wear ratio, and surface roughness were investigated. The surface microstructures machined by the new process were observed by a scanning electron microscope (SEM), an X-ray diffraction, and an energy dispersive spectrometer. The SEM micrographs show that the surfaces machined at rough machining mode and semi-finish machining mode are characterized by an uneven fusing structure, globules of debris, shallow craters, and micropores; the surface machined at finish machining mode is smooth, and covered by fewer little craters and pockmarks.

Keywords

silicon carbide ceramics surface integrity machining performance electric discharge milling mechanical grinding

References

Chiang

K.T.

Modeling and analysis of the effects of machining parameters on the performance characteristics in the EDM process of Al₂O₃+TiC mixed ceramic. Int. J. Advd Mfg Technol. 2008, 37(5-6), 523–533.

Lin

Y.C.

Wang

A.C.

Wang

D.A.

Chen

C.C.

Machining performance and optimizing machining parameters of Al₂O₃+TiC ceramics using EDM based on the Taguchi method. Mater. Mfg Process. , 2009, 24(6), 667–674.

C.F.

Zhou

Y.C.

Bao

Y.W.

Material removal and surface damage in EDM of Ti₃SiC₂ ceramic. Ceram. Int. , 2008, 34(3), 537–541.

Pradhan

M.K.

Das

Biswas

C.K.

Comparison of neural network models on surface roughness in electrical-discharge machining. Proc. IMechE, Part B: J. Engng Mf. , 2009, 223(7), 801–808. DOI: 10.1243/09544054JEM1367.

Chen

M.H.

Gao

Zhou

J.H.

Wang

Application of reaction sintering to the manufacturing of a spacecraft combustion chamber of SiC ceramics. J. Mater. Process. Technol. , 2002, 129(1-3), 408–411.

Yao

Zhang

Y.M.

Han

J.C.

Zou

H.B.

Fabrication and test of reaction bond silicon carbide for optical applications. Trans. Nonferrous Metals Soc. China , 2006, 16(2), 409–413.

Rajgopal

Zula

Garverick

Steven

A silicon carbide accelerometer for extreme environment applications. Mater. Sci. Forum , 2009, 600-603, 859–862.

Nozawa

Hinoki

Hasegawa

Kohyama

Katoh

Snead

L.L.

Henager

C.H.

Jr. Hegeman

J.B.J.

Recent advances and issues in development of silicon carbide composites for fusion applications. J. Nuclear Mater. , 2009, 386(c), 622–627.

Mercurio

Haber

Silicon carbide microstructure improvements for armor applications. Ceram. Engng Sci. Proc. , 2008, 28(5), 155–159.

10.

Veliadis

McNutt

McCoy

Hearne

DeSalvo

Clarke

Potyraj

Scozzie

1200-V, 50-A, silicon carbide vertical junction field effect transistors for power switching applications. Mater. Sci. Forum , 2009, 600-603, 1047–1050.

11.

Luis

C.J.

Puertas

Villa

Material removal rate and electrode wear study on the EDM of silicon carbide. J. Mater. Process. Technol. , 2005, 164-165, 889–896.

12.

Liu

Y.H.

R.J.

Q. Y.

L. L.

X.P.

An experimental investigation for electric discharge milling of SiC ceramics with high electrical resistivity. J. Alloys and Compounds , 2009, 472(1-2), 406–410.

13.

Liu

Y.H.

R.J.

Q.Y.

L.L.

X.P.

Electric discharge milling of silicon carbide ceramic with high electrical resistivity. Int. J. Mach. Tools Mf. , 2008, 48(12-13), 1504–1508.

14.

R.J.

Liu

Y.H.

L.L.

X.P.

Study on high efficient electric discharge milling of silicon carbide ceramic with high resistivity’

Chinese Sci. Bull. , 2008, 53(20), 3247–3254.

15.

Patel

K.M.

Pandey

P.M.

Rao

Venkateswara P.

Surface integrity and material removal mechanisms associated with the EDM of Al₂O₃ ceramic composite. Int. J. Refract. Metals and Hard Mater. , 2009, 27(5), 892–899.

16.

Kurina

Tan

P.C.

Yeo

S.H.

Tan

Q.P.

Surface roughness model for micro electro-discharge machining. Proc. IMechE, Part B: J. Engng Mf. , 2009, 223(3), 279–287. DOI: 10.1243/09544054JEM1188.

17.

Pradhan

B.B.

Bhattacharyya

Modeling of micro electro-discharge machining during machining of titanium alloy Ti-6Al-4V using response surface methodology and artificial neural network algorithm. Proc. IMechE, Part B: J. Engng Mf. , 2009, 223(6), 683–693. DOI: 10.1243/09544054JEM1343.