232

REFERENCES

[1] Rhoades L.J., Abrasive flow machining, Manufacturing Engineering, (1988), pp.75-

78.

[2] Rhoades L.J., Abrasive flow machining: A case study, J. Material Processing

Technology, 28,(1991), pp.107-116.

[3] N.Ramchandran, S.S.Pande, N.Ramakrishnan, “The role of deburring in

manufacturing: a state of the art survey”, Journal of Material Process. Technology 44

(1999) 1-13

[4] Schrader, George F.; Elshennawy, Ahmad K.; Doyle, Lawrence E. (2000),

Manufacturing processes and materials (4th ed.), SME, p. 626, ISBN 978-0-87263-

517-3, http://books.google.com/books?id=Nz2wXvmkAF0C&pg=PA626.

[5] Extrude Hone Corpn., www.extrudehone.in accessed on 01/11/2011

[6] US Patent No. 3521412, McCarty, Ralph William, "Method of honing by

extruding", issued 1970-08-21.

[7] L.J.Rhoades, “Abrasive flow machining and its use”, Proceedings of the Non

traditional Machining Conference, Cincinnati, OH, 1985, pp.111-120

[8] H.S.Shan, Advanced Machining Processes, (2004), Tata McGraw Hill, New Delhi

*9+ YOU S E, WANG A C, HUANG F Y, YAN B H.,“Precision improvement of micro slit

by electro-chemical polishing”, Proceedings of the 17th National Conference on

Mechanical Engineering. Kaohsiung: The Chinese Society of Mechanical Engineers,

2000: 73−80.

*10+ CHANG G W, HSU R T, YAN B H, CHANG R H.,“Study of applying magnetic

abrasive finishing to improve EDM surface”, Proceedings of the 18th National

Conference on Mechanical Engineering. Taipei: The Chinese Society of Mechanical

Engineers, 2001: 555−562.

*11+ WANG A C, YAN B H, LEE X T, HUANG F Y., “Use of micro ultrasonic vibration

lapping to enhance the precision of microholes drilled by micro electro-discharge

machining”, International Journal of Machine Tools and Manufacture, 2002, 42:

915−923.

[12] YAN B H, LIN Y C, HUANG F Y., “Surface modification of Al-Zn- Mg alloy by

combined electrical discharge machining with ball burnish machining”, International

Journal of Machine Tools and Manufacture, 2002, 42: 925−934.

233

[13] LOVELESS T R, WILLIAMS R E, RAJURKAR K P.,“Study of the effects of abrasive

flow machining on various machined surfaces”, Journal of Materials Processing

Technology, 1994, 47(1/2): 133−151.

[14] KIM J D, KIM K D.,“Deburring of burrs in spring collets by abrasive flow

machining”, International Journal of Advanced Manufacturing Technology, 2004,

24(7/8): 469−473.

[15] WANG A C, LIANG K Z, LIU C H, WENG S H.,“High precision polishing method in

3-D surface and elastic abrasive gel development”, 4th Asia Pacific Forum on

Precision Surface Finishing and Deburring Technology, Taichung: Metal Industries

Research & Development Centre, 2005: 123−128.

[16] TOM K., “Advanced abrasive flow technologies”,4th Asia Pacific Forum on

Precision Surface Finishing and Deburring Technology. Taichung: Metal Industries

Research & Development Centre, 2005: 129−138.

[17] Sommer, C. (2000) Non-Traditional Machining Handbook Advance Publishing

Inc. , Houston, TX

*18+ V.K. Jain,“Magnetic field assisted abrasive based micro-/nano-finishing”, Journal

of Materials Processing Technology, Volume 209, Issue 20, 19 November 2009, Pages

6022-6038

*19+ M. Ravi Sankar, VK Jain, J. Ramkuar, “Experimental investigations and

mechanism of material removal in nano finishing of MMCs using abrasive flow

finishing (AFF) process”, Wear 266 (2009) 688-698

[20] D Graham, RM Baul, “An investigation into the mode of metal removal in the

grinding process”, Wear 19 (1972) 301-314

*21+ PK Basuray, BK Misra, GK Lal, “Transition from ploughing to cutting during

machining with blunt tools”, Wear 43 (1977) 341-349

*22+ NP L’vov, “Determining the minimum possible chip thickness”, Machine Tools

(USSR) 40 (1969) 45

*23+ MM Khrushov, MA Babichev, “Investigation of the effect of abrasive hardness

on wear of metals” Friction and Wear in Machines, Issue 6 Izd. AN SSSR, Moscow

(1960), pp. 45-46.

*24+ VN Marochkin, “The limiting plastic state in indenting and compressing a

truncated cone”, Friction Wear Mach., 13 ASME, 1959

234

[25] JN Brecker, R Brown, T Matsuo, K Saito, JA Sweeney, JB Van Suan, MC Shaw,

ourth Annual Report on Abrasive Grain Association Investigation of Abrasive Grain

Characteristics, Carnegie Institute of Technology, 1969

*26+ FP Bowden, AJW Moore, D Tabor, “Ploughing and adhesion of sliding of metals”

Journal Appl.Phy. 14 (1943) 80-91

[27] Gorana V.K., Jain V.K., Lal G.K., Forces prediction during material deformation in

abrasive flow machining, Wear 260 (2006) 128-139.

*28+ A Groenou van Broese, N Maan, JDB Veldkamp, “Scratching experiments on

various ceramic materials”, Phillips Res.Rep. 30 (1975) 320-359

[29] MM Khrushchov, MA Bavichev, Research on wear of metals, Ch.8, NEL

Translation No.893, National Engineering Laboratory, East Kilbride, 1960

*30+ D Graham, RM Baul, “An investigation into the mode of material removal in the

grinding process”, Wear 19 (1972) 301-314

*31+ MC Shaw, “A new theory of grinding”, Proceedings of Institutions Conference on

Production Science in Industry, Melbourne, 1971, pp.73-78

*32+ X Chen, WB Rowe, “Analysis and Simulation of the grinding process part II:

Mechanics of Grinding”, International Journal of Machine Tools and Manufacture 36

(1996) 883-896

[33] Rhoades L.J., Kohut T.A., Nokovich N.P., YandaD.W., Unidirectional abrasive flow

machining, USpatent number 5,367,833, Nov 29th, 1994.

[34] Rhoades L.J., Kohut T.A., ReversibleUnidirectional AFM, US patent

number5,070,652, Dec 10th, 1991.

[35] Rhoades L.J., Orbital and or reciprocal machining with a viscous plastic medium,

International patent no: WO 90/05044, 17thMay, 1990.

[36] J.L.Rhoades, “Orbital polishing apparatus and method, Extrude Hone

Corporation, United States Patent No.7255631 (2007)

[37] Liang Fang, Kun Sun, Qihong Cen, “Particle movement patterns and their

prediction in abrasive flow machining” Copyright © 2007 John Wiley & Sons, Ltd.

[38] L.J.Rhoades, Automation of non traditional processes, SME Technical Paper MR

85-475, Society of Manufacturing Engineers, Dearborn, MI, USA, 1985, pp. 1-18

*39+ W.Perry, “Properties and capabilities of low pressure abrasive flow media”, SME

Technical Paper MR 75-831, Society of Manufacturing Engineers, Dearborn, MI, USA,

1975

235

*40+ J. Stackhouse, “Deburring by dynaflow”, SME Technical Paper MR 75-484,

Society of Manufacturing Engineers, Dearborn, MI, USA, 1975

*41+ T.Kohut, “Surface finishing with abrasive flow machining”, Proceedings of the 4th

International Aluminium Extrusion Technology Seminar, Washington, DC,1988,

pp.35-43

[42] Jain R.K., Jain V.K., Dixit P.M., Modeling of material removal and surface

roughness in abrasive flow machining process, International Journal of Machine Tool

& Manufacture 39 (1999) 1903-1923.

[43] Kato, K. (1997) Abrasive wear of metals. Tribology International 30:5 , pp. 333-

338.

[44] Singh S, Shan HS, Kumar P (2002) Wear behavior of materials in magnetically

assisted abrasive flow machining. J Mater Process Technol 128:155–161

doi:10.1016/S0924-0136(02)00442-9

*45+ A. Di Ilio, A. Paoletti, V. Tagliaferri, F. Veniali, “An experimental study on grinding

of silicon carbide reinforced aluminium alloys”, International Journal of Machine

Tools and Manufacture 36 (1996) 673-685

*46+ Williams, R. E. and K. P. Rajurkar, “Stochastic Modeling and Analysis of Abrasive

Flow Machining,” ASME Journal of Engineering for Industry, 114 (1), 74-81 (1992).

*47+ H.S.Shan, A.K.Dubey,”Micro machining by flow of abrasives”, Proceedings of the

17th AIMTDR Conference, Warrangal, India, 1997, pp. 269-275

[48] Haan JJ, Steif PS (1998) Abrasive wear due to slow flow of a concentrated

suspension. Wear 219:177–183

[49] Przylenk K (1986) Abrasive flow machining—a process for surface finishing and

deburring of workpiece with a complicated shape by means of an abrasive laden

medium. ASME, New York.PED 22:101–110

[50] Loveless T.R., Willams R.E., Rajurkar K.P., A study of the effects of abrasive flow

finishing on various machined surfaces, Journal Material Processing Technology, 47

(1994), pp.133- 151.

[51] Jain V.K., Adsul S.G., Experimental investigations into abrasive flow machining,

International Journal of Machine tool and Manufacturer, 40 (2002), pp.1003-1021.

[52] Williams R.E., Rajurkar K.P., Stochastic modeling and analysis of abrasive flow

machining, Transaction ASME, Journal of Engineering for Industry, 114, (1992), 74-

81.

236

[53] FLETCHER A J, FIORAVANTI A. Polishing and honing process: an investigation of

the thermal properties of mixtures of polyborosiloxane and silicon carbide abrasive

*J+. Proceedings of the Institution of Mechanical Engineers, 1996, 210: 256−265.

[54] JAIN V K, RANGANATHA C, MURALIDHAR K. Evaluation of rheological properties

of medium for AFM process [J]. Machine A-Cheng WANG, et al/Trans. Nonferrous

Met. Soc. China 19(2009) Science and Technology, 2001, 5(2): 151−170.

[55] WANG A C, WENG S H. Developing the polymer abrasive gels in AFM process [J].

Journal of Materials Processing Technology, 2007, 192/193: 321−328.

[56] Singh S., Shan H.S., Development of magneto abrasive flow machining process,

International Journal of Machine Tool & Manufacture 42 (2002) 953-959.

[57] Jha, S. and Jain, V. K. Design and development of the magnetorheological

abrasive flow finishing (MRAFF) process. Int. J. Mach. Tools Mf., 2004, 44, 1019–

1029.

[58] Jain, VK, “Abrasive Flow Machining – an overview”,

http://www.psgtech.edu/psgias/smart_machine_tools

*59+ Rhoades L.J., “Abrasive flow machining with not-so-silly putty”, Metal Finishing,

(1987),pp.27-29.

[60] Perry W.B., Abrasive flow machining –principles and practices, Non-traditional

conference proceedings, (1989), pp.121-127.

[61] Davies P.J., Fletcher A.J., The assessment of the rheological characteristics of

various polyborosilixane/grit mixtures as utilized in the abrasive flow machining,

Proceedings of Instn. Mech. Engrs. 209, (1995), 409-418.

[62] Williams, R. E. and K. P. Rajurkar, “Metal Removal and Surface Finish

Characteristics in Abrasive Flow Machining,” Mechanics of Deburring and Surface

Finishing Processes (R. J. Stango and P. R. Fitzpatrick, eds.), New York, NY: ASME, 93-

106 (1989).

[63] Williams R.E., Rajurkar K.P., Kozak J., Metal removal distribution and flow

characteristics in AFM, Transaction of NAMRI/SME, Vol. XX, (1992), pp. 145-150.

[64] Uhlmann, E.; Mihotovic, V.; Coenen, A.Zugang, “Modelling the abrasive flow

machining process on advanced ceramic materials”, International Conference on

Abrasive Processes (ICAP) 1, 2008, Churchill College, Cambridge, England from 21 to

25 September 2008 Amsterdam: Elsevier, 2009 (Journal of materials processing

technology 209.2009, Nr.20 Special Issue) S.6062-6066

237

[65] Rajeshwar, G., Kozak, J., and Rajurkar, K. P. Modelling and computer simulation

of media flow in abrasive flow machining process, PED-Vol. 68–2, 1994

(Manufacturing Science and Engineering, Chicago, Illinois).

*66+ Lucjan Dabrowski1, Mieczyslaw Marciniak1, Władyslaw Wieczorek2 and Anna

Zygmunt2, “Advancement of Abrasive Flow Machining Using an Anodic Solution”

Journal of New Materials for Electrochemical Systems 9, 439-445 (2006)

[67] J. Stachause, Abrasive — flow machining debars difficult channels. Tooling and

Production Magazine.July, 1990, USA.

[68] O. R. Kuzmanovic, Flussige Feile. Stromungsschleifen zur Feinbearbeitung von

Bauteiloberflachen. Maschinenmarkt nr 16, Vogel Verlag und Druck KG, 1994

[69] G. Rajeshwar, J. Kozak, K. P. Rajurkar, Modeling and computer simulation of

media flow in abrasive flow machining process.Winter Annual Meeting of ASMA,

Chicago, 1994, USA.

[70] E. Uhlmann, H. Szulczynski, Precise Finishing of Inner Contours with Abrasive

Flow Machining (AFM). Proceeding of Advances in Production Engineering APE2004,

Warsaw 2004.

[71] Jain VK (2002) Advanced machining processes. Allied Publishers, New Delhi, pp

57–76

[72] Gorana VK, Jain VK, Lal GK (2004) Experimental investigation into cutting forces

and active grain density during abrasive flow machining. Int J Mach Tools Manuf

44:201–211 doi:10.1016/j. ijmachtools.2003.10.004

[73] Walia RS, Shan HS, Kumar P (2006) Abrasive flow machining with additional

centrifugal force applied to the media. Machining Science and Technology: An

International Journal 10:3 , pp. 341-354.

[74] Walia RS, Shan HS, Kumar P (2007) Determining dynamically active abrasive

particles in the media used in centrifugal force assisted abrasive flow machining

process.Int J Adv Manuf Technol (in press) doi:10.1007/s00170-007-1184-8

[75] Yan B-H, Yan B-H, Tzeng H-J et al (2007) Finishing effects of spiral polishing

method on micro lapping surface. Int J Mach Tools Manuf 47:920–926

doi:10.1016/j.ijmachtools.2006.07.009

*76+ JAIN R K, JAIN V K, KALRA P K.,“Modeling of abrasive flow machining process: a

neural network approach” *J+. Wear, 1999, 231(2): 242−248.

[77] Sarah S., Lam.Y., Smith A. E., Cascade- Correlation Neural Network Modeling of

the Abrasive Flow Machining Process, Advances in Industrial Engineering Theories,

238

Applications and Practice III, Volume III, International Journal of Industrial

Engineering, (1998), pp.898-905.

[78] Jayswal SC, Jain VK, Dixit PM (2005) Modeling and simulation of magnetic

abrasive finishing process. Int J Adv Manuf Technol 26:477–490 doi:10.1007/s00170-

004-2180-x

*79+ I.Finnie, “Some observations on the erosion of ductile metals” Wear 19 (1972)

81-90

*80+ E.Rabinowicz, et al., “A study of abrasive wear under three body conditions”,

Wear 4 (1961) 345-355

*81+ J.H.Neilson, A.Gilchrist, “Erosion by stream of solid particles”, Wear 11 (1968)

111-122

*82+ R.E.Williams, K.P.Rajurkar, “Performance Characteristics of abrasive flow

machining”, SME Technical Paper FC89-806, Society of Manufacturing Engineers,

Dearborn, MI, USA, 1989, pp.898-906

*83+ JAIN R K, JAIN V K.,“Simulation of surface generated in abrasive flow machining

process” *J+. Robotics and Computer-Integrated Manufacturing, 1999, 15(5):

403−412.

*84+ R.E.William, K.P.Rajurkar, “Monitoring of abrasive flow machining process using

acoustic emission” S.M.Wu Symposium, Vol.I, 1994, pp. 35-41

[85] Hsinn-Jyh Tzeng, Biing-Hwa Yan, Rong-Tzong Hsu and Han-Ming Chow,

“Finishing effect of abrasive flow machining on micro slit fabricated by wire-EDM”

THE INTERNATIONAL JOURNAL OF ADVANCED MANUFACTURING

TECHNOLOGYVolume 34, Numbers 7-8, 649-656

[86] Petri K.L., Billo R.E., Bopaya Bidanda., A Neural Network Process Model for

Abrasive Flow Machining Operations, Journal of Manufacturing Systems Vol.17/No.1,

(1998), pp. 52-64.

[87] Jain R.K., Jain V.K., Optimum selection of machining conditions in abrasive flow

machining using neural network, Journal of Material Processing Technology, 108

(2000), pp.62-67.

[88] JAIN R K, JAIN V K.,“Stochastic simulation of active grain density in abrasive flow

machining” *J+. Journal of Materials Processing Technology, 2004, 152(1): 17−22.

[89] Jain RK, Jain VK (2001) Specific energy and temperature determination in

abrasive flow machining process. Int J Mach Tools Manuf 41:1689–1704

239

[90] Singh S, Shan HS, Kumar P (2002) Parametric optimization of magnetic-field-

assisted abrasive flow machining by the Taguchi method. Qual Reliab Eng Int 18:273–

283

*91+ JAIN R K, JAIN V K.,“Finite element simulation of abrasive flow machining” *J+.

Proceedings of the Institution of Mechanical Engineers, Engineering Manufacture B,

2003, 217(12): 1723−1736.

[92] T. Kohut, Advanced abrasive flow technologies, 4th Asia Pacific Forum on

Precision Surface Finishing and Deburring Technology, Taiwan, (2005) 129-138.

[93] Sehijpal Singh; H. S. Shan; Pradeep Kumar, “Experimental Studies on Mechanism

of Material Removal in Abrasive Flow Machining Process” Materials and

Manufacturing Processes Volume 23, Issue 7, 2008, Pages 714 – 718

*94+ Liang Fang, Jia Zhao, Kun Sun, Degang Zheng, Dexin Ma, “Temperature as

sensitive monitor for efficiency of work in abrasive flow machining”, Wear 266(2009)

678-687

[95] M.C.Shaw, Principles of Abrasive Processing, Clarendon Press, 1996.

*96+ G.K.Lal, “Forces in vertical surface grinding”, International Journal of Machine

Tool Design Research 8 (1968) 33-43

[97] Liang Fang, Jia Zhao, Bo Li and Kun Sun, “Movement patterns of ellipsoidal

particle in abrasive flow machining”, Journal of Materials Processing Technology

Volume 209, Issue 20, 19 November 2009, Pages 6048-6056

[98] Zhi Guo Dong, Xiao Dong Zhang, Yuan Zong Li, “Analysis of Flowing

Characteristics of Abrasive Flow Machining in Slit” Key Engineering Materials

(Volumes 467 - 469)Materials, Mechatronics and Automation283-286

*99+ HS Mali, A Manna, “Current status and application of abrasive flow finishing

processes: A review”, Proceedings of the Institution of Mechanical Engineers, Part B:

Journal of Engineering Manufacture July 1, 2009 vol. 223 no. 7 809-820

[100] Koshy P, Jain VK, Lal GK (1997), “Stochastic simulation approach to modeling

diamond wheel topography”, International Journal of Machine Tools Manufacturing

37 (6): 751-761

[101] Yoshikawa H, Sata T (1968), “Simulated grinding process by Monte Carlo

method”, Ann CIRP 16: 297-302

[102] Law SS, Wu SM, Jogelkar AM (1973), “On building models for the grinding

process”, Trans ASME J Eng Ind 95: 983-991

240

[103] Hamed MS, Whitehouse DJ, Buttery TC (1978), “Random surface generation –

integrated approach”, ANN CIRP 27: 499-504

[104] Abrahamson EP II, Jahanmir S, Suh NP (1975), “The effect of surface finish on

the wear of sliding surfaces”, ANN CIRP 24(1): 513-514

[105] RK Jain, VK Jain, “Effect of operating parameters on the performance of

abrasive flow machining process”, 20th AIMTDR, Birla Institute of Technology, 2002,

Ranchi, India

[106] Pandey PM, Reddy NV, Dhande SG (2002), “Improvement of surface finish by

staircase machining in fused deposition modeling”, J Mater Process Technol 132(1):

323-331

[107] Spurr RT (1976), “The roughness of abraded metal surfaces”, Wear 40: 383-387

[108] Dowson D, Whomes TL (1971), “The effect of surface roughness upon the

lubrication of rigid cylindrical rollers I Theoretical”, Wear 18: 129-140

[109] Sakamoto T, Tsukizoe T (1977), “Friction and prow formation in a scratch

process of copper by a diamond cone”, Wear 44: 393-403

[110] Tsuwa H (1964), “An investigation of grinding wheel cutting edges”, J Eng Ind

Nov:371-382

[111] Tanaka Y, Ikawa N (1966), “Cutting mechanism of the bronze-bonded diamond

wheel”, ANN CIRP XIII: 433-44-

[112] Malkin S (1989) Grinding Technology – Theory and Application of machining

with abrasives, Wiley, New York

*113+ TW Liao, LJ Chen, “A neural network approach for grinding processes, modeling

and optimization”, International Journal of Machine Tools Manufacturing 34 (1994)

919-937

*114+ G Chryssolouris, M Guillot, “Modeling of machining processes using neural

network”, Trans. ASME J.Eng.Ind.112 (1990) 122-131

*115+ SS Rangwala, DA Dornfeld, “Learning and optimization of machining operations

using computing abilities of neural networks”, IEEE Trans. Syst., Man Cybernet. 19

(1990) 299-314

*116+ N Zouaghi, Y Ichida, “Grinding mode identification and surface quality

prediction using neural networks in grinding of silicon nitride”, Int.J.Jpn.

Soc.Prec.Eng. 30(1996) 35-40

241

*117+ G Sathyanarayan, I Joseph Lin, MK Chen, “Neural networks modeling and multi-

objective optimization of creep feed grinding of super alloys”, Int J. Prod.Res. 30

(1992) 2421-2428

*118+ R Lippman, “An introduction to computing with neural nets”, IEEE

Trans.Acous.Signal Process. ASSP-4 (1987) 4-22

[119] S Haykin, Neural Networks – A Comprehensive Foundation, Macillan, New

York, 1984

[120] DE Goldberg, Genetic Algorithms in Search, Optimization and Machine

Learning, Addison-Wesley, New York, 1989

[121] Rajeshwar G., Kozak J., Rajurkar K.P., Modeling and computer simulation of

media flow in abrasive flow machining process, Proceedings of the International

Mechanical Engineering Congress and Exposition, Chicago, PED, 68, (1994), pp.965-

971.

*122+ Fletcher, A. J., J. B. Hull, J. Mackie, and S. A. Trengrove, “Computer Modelling

of the Abrasive Flow Machining Process,” Proceedings of the International

Conference on Surface Engineering: Current Trends and Future Prospects, Toronto,

Ontario, Canada, (Abington, Cambridge: Welding Institute), 592-601 (1990).

[123] Petri K.L., Billo R.E., Bidanda B., A neural network process model for abrasive

flow machining operations, Journal of Manufacturing Systems, Vol. 17(1), (1998), pp.

52-64.

[124] Lam S.S.Y., Smith A.E., Process monitoring of abrasive flow machining using a

predictive neural network model, Proc. 6th Industrial Engineering Research

Conference, Florida, (1997)pp. 477-482.

[125] Lam S.S.Y., Smith A.E., Process control of abrasive flow machining using a static

neural network model, Intelligent Systems through Artificial Neural Networks, 8,

(1998) 797-802.

*126+ Petri, K. L., R. E. Billo, and B. Bidanda, “Modeling the Abrasive Flow Machining

Process:A Neural Network Approach,” 4th Industrial Engineering Research

Conference Proceedings,Nashville, Tennessee, (IIE), 239-244 (1995).

[127] Liang Fang, X.L. Kong, Q.D. Zhao, “A wear tester capable of monitoring and

evaluating the movement pattern of abrasive particles in three body abrasion”,

Wear 159(1992) 115-120

*128+ Liang Fang, X.L. Kong, Q.D. Zhao , “Movement patterns of abrasive particles in

three body abrasion”, Wear 162-164(1993) 782-789

242

*129+ Liang Fang, Q.D. Zhao, “A statistical model describing wear traces in three body

abrasion”, Tribotest 2(1995) 47-53

*130+ J.D. Gates, “Two body and three body abrasion: a critical discussion”, Wear 214

(1998) 139-146

*131+ S.Wirojanupatump, P.H. Shipway, “A direct comparison of wet and dry

abrasion behaviour of mild steel”, Wear 233-235 (1999) 655-665

[132] V. K. Gorana, V. K. Jain and G. K. Lal, “Prediction of surface roughness during

abrasive flow machining”, The International Journal of Advanced Manufacturing

TechnologyVolume 31, Numbers 3-4, 258-267, DOI: 10.1007/s00170-005-0197-4

[133] Zienkiwicz, OC, Jain, PC and Onate, E, “Flow of solids during forming and

extrusion: some aspects of numerical solutions”, International Journal Solids Structs.,

1978, 14, 15-38

[134] Dixit, US and Dixit, PM, “An analysis of the steady-state wire drawing of strain-

hardening material”, Journal Mater. Processing Technology, 1995, 47, 201-229

*135+ Crochet, MJ, Davies, AR and Walters, K, “Numerical Simulation of Non-

Newtonian Flow”, 1984 (Elsevier, New York)

*136+ Wilson, KC, Addie, GR, Sellgren, A and Clift, R, “Slurry Transport Using

Centrifugal Pumps”, 1997 (Blackie, London)

[137] Manas Das, V.K. Jain and P.S. Ghoshdastidar, “Fluid flow analysis of

magnetorheological abrasive flow finishing (MRAFF) process” , International Journal

of Machine Tools and Manufacture, Volume 48, Issues 3-4, March 2008, Pages 415-

426

*138+ Andersen, K., G. E. Cook, G. Karsai, and K. Ramaswamy, “Artificial Neural

Networks Appliedto Arc Welding Process Modeling and Control,” IEEE Transactions

on Industry Applications,26(5), 824-830 (1990).

*139+ Martinez, S. E., A. E. Smith, and B. Bidanda, “Reducing Waste in Casting with a

PredictiveNeural Model,” Journal of Intelligent Manufacturing 5, 277-286 (1994).

[140] Stinson, M. E., O. W. Lee, J. S. Steckenrider, and W. A. Ellingson, “Recognition

of SubsurfaceDefects in Machined Ceramics by Application of Neural Networks to

Laser Scatter Patterns,”Ceramic Engineering and Science Proceedings 15, 390-396

(1994).

[141] Willis, M. J., C. Di Massimo, G. A. Montague, M. T. Tham, and A. J. Morris,

“Artificial NeuralNetworks in Process Engineering,” IEEE Proceedings, Part D: Control

Theory and Applications, 138 (3), 256-266 (1991).

243

[142] Williams R.E., Acoustic Emission Characteristics of Abrasive Flow Machining,

Transaction of the ASME, 120, (1998), 264- 271.

*143+ L Dabrowski*, M Marciniak, and T Szewczyk, “Analysis of abrasive flow

machining with an electrochemical process aid” Proc. IMechE Vol. 220 Part B: J.

Engineering Manufacture JEM249 IMechE 2006.

*144+ Robert Edward Williams,“Investigation of the abrasive flow machining process

and development of a monitoring strategy using acoustic emission”(January 1,

1993). ETD collection for University of Nebraska - Lincoln. Paper

AAI9333989. http://digitalcommons.unl.edu/dissertations/AAI9333989

*145+ Alice E. Smith, William S. Slaughter, “Neural Network Modeling of Abrasive

Flow Machining”, Proceedings of the Advanced Technology Program Motor Vehicle

Manufacturing Technology Public Workshop, NIST Document NISTIR 6079, Ann

Arbor, MI, October 1997, 151-158.

[146] Method and apparatus for controlling abrasive flow machining, United States

Patent 6319094

[147] US Patent No. 3 909 217, 1992.

[148] R. W. McCarty, Patent US3634973, Apparatus for abrading by extrusion and

abrading medium, 18 January 1972.

*149+ Coit, D. W. and A. E. Smith, “Using Designed Experiments to Produce Robust

Neural Network Models of Manufacturing Processes,” 4th Industrial Engineering

Research Conference Proceedings, Nashville, Tennessee, (IIE), 229-238 (1995).

*150+ M. Ravi Sankar, VK Jain, J. Ramkumar, Kamal K. Kar, “Rheological

characterization and performance evaluation of a new medium developed for

abrasive flow finishing”, 2ndInternational and 17thAll India Manufacturing

Technology, Design and Research Conference, (2008)Chennai, India

[151] Agrawal A., Jain V.K., Muralidhar K., “Experimental determination of viscosity

of abrasive flow machining media”, International Journal of Manufacturing

Technology and Management 2005 - Vol. 7, No.2/3/4 pp. 142 - 156

[152] Kamal K. Kar,N. L. Ravikumar, Piyushkumar B. Tailor, and J. Ramkumar, D.

Sathiyamoorthy “Preferential Media for Abrasive Flow Machining” J. Manuf. Sci.

Eng. -- February 2009 -- Volume 131, Issue 1, 011009 (11 pages)

[153] A. C. Wang, C. H. Liu, K. Z. Liang and S. H. Pai, “Study of the rheological

properties and the finishing behavior of abrasive gels in abrasive flow machining”,

JOURNAL OF MECHANICAL SCIENCE AND TECHNOLOGY, Volume 21, Number

10, 1593-1598

244

[154] J.M. Mark, The Science and Technology of Rubber, Elsevier Academic Press,

Burlington, 2005

[155] P.Ghose, Polymer Science and Technology of Plastics and Rubbers, Tata

McGraw Hill, New Delhi, 2000

[156] S. Y. M. Wan, W. S. Fong, C. J. Kong, D. L. Butler and M. S. Tiew, “Low pressure

abrasive flow machining”, SIMTech technical reports (STR_V11_N1_04_MTG)

Volume 11 Number 1 Jan-Mar 2010

[157] Kozak, J.; Oczos, K.E. Selected problems of abrasive hybrid machining.Journal

of Material Processing Technology 2001,109, 360–366.

[158] Walia, R.S.; Shan, H.S.; Kumar, P. Parametric optimization of centrifugal force

assisted abrasive flow machining by the Taguchi Method. Journal of Materials and

Manufacturing Processes 2005, 21 (4) (in press).

[159] Walia, R.S.; Shan, H.S.; Kumar, P. Simulation of the path of an abrasive particle

in centrifugal force assisted abrasive flow machining (CFAAFM) Process.Proceedings

AMREG- 2005, 2005(a), Pune, India.

[160] Walia, R.S.; Shan, H.S.; Kumar, P. Abrasive flow machining with additional

centrifugal force applied to the media. Machining Science and Technology 2006, 10

(3), 341–354.

[161] R. S. Walia, H. S. Shan, and P. Kumar, “Multi-Response Optimization of CFAAFM

Process Through Taguchi Method and Utility Concept”, Materials and Manufacturing

Processes, 21: 907–914, 2006Copyright © Taylor & Francis Group, LLC

*162+ J.Kozak, K.E.Oczos, “Selected problems of abrasive hybrid machining”, Journal

of Material Process. Technology 109 (2001) 360-366

[163] C.Yuquan, L.Zhenjia, “Research on a magnetic field in electrolytic lapping”,

China Journal Mech. Engg. 12 (1) (1999)

*164+ G.Kuppuswamy, “Magnetic field affects electrochemical grinding”, Tribology

International 6 (1977) 184-188

[165] S.Singh, H.S.Shan, P.Kumar, “Effect of magnetic field on abrasive flow

machining process”, Proceedings of the 12th DAAAM International Symposium, Jena,

Germany, 2001, pp.447-448

[166] Ravi Sankar M., Mondal S., Ramkumar J., Jain V.K., Experimental Investigations

and Modelling of Drill Bit Guided Abrasive Flow Finishing (DBG-AFF) Process,

International Journal of Advanced Manufacturing Technology 42 (2009) 678-688.

245

[167] Biing-Hwa Y., Biing-Hwa Y., Hsinn-Jyh T., Finishing effects of spiral polishing

method on micro lapping surface. International Journal of Machine Tools and

Manufacture 47 (2007) 920-926.

[168] Walia R.S., Shan H.S., Kumar P., Effect of providing a rotating rod inside the

hollow cylindrical workpiece on the material removal in AFM, Proceedings of 21st

AIMTDR Conference, VIT, Vellore, India, pp, 143-148, 2004.

[169] Ravi Sankar M., Jain V.K., Ramkumar J., Experimental Investigations into

rotating workpiece abrasive flow finishing, International conference on Wear of

material, Wear 267 (2009) 43-51.

[170] Dabrowski, L. and Marciniak, M. A method of electrochemically assisted

abrasive flow machining and a device for electrochemically assisted abrasive flow

machining. Pat. Application P. 336 709, 1999.

[171] Yunn-Shiuan Liao, Chao-Chang A. Chen, Choung-Lii Chao and Pei-Lum Tso,

“Study the Rheological Properties of Abrasive Gel with Various Passageways in

Abrasive Flow Machining”,2010, Advanced Materials Research, 126-128, 447

[172] R.S. Walia , H.S. Shan , P. Kumar, “Optimisation of finishing conditions in

Centrifugal Force Assisted Abrasive Flow Machining using Taguchi method”,

International Journal of Manufacturing Technology and Management, Volume 18,

Number 1 / 2009, 79 – 93

[173] WALIA R. S. ; SHAN H. S. ; KUMAR P. K., “Finite element analysis of media used

in the centrifugal force assisted abrasive flow machining process”, Proceedings of the

Institution of Mechanical Engineers. Part B. Journal of engineering manufacture

ISSN 0954-4054, 2006, vol. 220, no11, pp. 1775-1785

[174] K Malla Reddy, A K Sharma, P Kumar, “Some aspects of centrifugal force

assisted abrasive flow machining of 2014 Al alloy”, Proceedings of the Institution of

Mechanical Engineers, Part B: Journal of Engineering Manufacture, Volume 222,

Number 7 / 2008, 773-783

[175] Ravi Sankar M.,Jain V.K., Ramkumar J., “Rotational abrasive flow finishing (R-

AFF) process and its effects on finished surface topography”, International Journal of

Machine Tools & Manufacture50 (2000) 637-650.

*176+ RS Walia, HS Shan, P Kumar, “Morphology and integrity of surfaces finished by

centrifugal force assisted abrasive flow machining”, International Journal of

Advanced Manufacturing Technology 39(2008) 1171-1179

[177] Manas Das, V. K. Jain and P. S. Ghoshdastidar, “Analysis of magnetorheological

abrasive flow finishing (MRAFF) process”, The International Journal of Advanced

246

Manufacturing TechnologyVolume 38, Numbers 5-6, 613-621, DOI: 10.1007/s00170-

007-1095-8

[178] Sunil Jha and Vijay Kumar Jain, “A novel nanofinishing process using

magnetorheological abrasive polishing fluid”, International Journal of Manufacturing

Technology and Management, Volume 21, Number 1-2 / 2010 4 - 16

[179] Sunil Jha, Vijay Kumar Jain, “Parametric analysis of magnetorheological

abrasive flow finishing process”, International Journal of Manufacturing Technology

and Management (IJMTM), Vol. 13, No. 2/3/4, 2008, 308-323

[180] A. Sadiq; M. S. Shunmugam, “MAGNETIC FIELD ANALYSIS AND ROUGHNESS

PREDICTION IN MAGNETORHEOLOGICAL ABRASIVE HONING (MRAH)”Machining

Science and Technology: An International Journal, Volume 13, Issue 2, 2009, Pages

246 - 268

[181] A. Sadiq and M.S. Shunmugam, “A novel method to improve finish on non-

magnetic surfaces in magneto-rheological abrasive honing process”,Tribology

InternationalVolume 43, Issues 5-6, May-June 2010, Pages 1122-1126

[182] A. Sadiq and M.S. Shunmugam, “Investigation into magnetorheological

abrasive honing (MRAH)”, International Journal of Machine Tools and

ManufactureVolume 49, Issues 7-8, June 2009, Pages 554-560

[183] Jones, A. R. and Hull, J. B. (1998) Ultrasonic flow polishing. Ultrasonics 36 , pp.

97-101.

[184] J.R. Gilmore, Orbital Polishing – An Emerging Technology: SME Buff and Polish

Clinic, Schaumburg, IL,1997

[185] K.P.Rajurkar, J.Kozak, Hybrid machining process evaluation and development,

online available at: www.unl.com

*186+ T.Shinmura, H.Yamaguchi, “Study on a new internal finishing process by the

application of magnetic abrasive machining, JSME Int. J. Ser.C38 (4) (1995) 798-804

*187+ J.D.Kim et al., “Development of magnetic abrasive jet machining system for

precision internal polishing of circular tubes”, Journal of Material Process Technology

71 (1997) 384-393

[188] G.Z.Kremen, E.A.Elsayed, V.I.Rafalovich, “Mechanism of material removal in

MAP and the accuracy of machining”, International Journal Prod. Res. 34 (9) (1996)

2629-2638

247

[189] A.B.Khairy, “Aspects of surface and edge finish by magnetoabrasive

particles”,Proceedings of International Conference on Advanced Manufacturing

Technology, Malaysia, 2000, pp.77-84

[190] H S Mali, A Manna, “Current status and application of abrasive flow finishing

processes: a review”, Proceedings of the Institution of Mechanical Engineers, Part B:

Journal of Engineering Manufacture,Volume 223, Number 7 / 2009 809-820

[191] Robert E. Williams, Harold L. Dunegan, Eric L. Clark, Owen M. Kinyungu, “A

NEW ACOUSTIC EMISSION MONITORING TECHNIQUE FOR ABRASIVE FLOW

MACHINING” Proceedings of the 2000 Japan-USA Flexible Automation Conference

July 23-26, 2000, Ann Arbor, Michigan2000JUSFA-13143

[192] A-Cheng WANG, Lung TSAI, Kuo-Zoo LIANG, Chun-Ho LIU, Shi-Hong

WENG,“Uniform surface polished method of complex holes in abrasive flow

machining”, Ching Yun University, Trans. Nonferrous Met. Soc. China 19(2009)

s250−257

[193] Robert E. Williams, Daniel F. Walczyk, Hoang T. Dang, (2007) "Using abrasive

flow machining to seal and finish conformal channels in laminated tooling", Rapid

Prototyping Journal, Vol. 13 Iss: 2, pp.64 – 75

[194] Eckart Uhlmann, Vanja Mihotovic ,and Andre Coenen, “Modelling the abrasive

flow machining process on advanced ceramic materials”,Institute for Machine Tools

and Factory Management (IWF), Berlin University of Technology, PTZ 1, Pascalstr.,

2009, 8-9, 10587 Berlin, Germany

[195] M. Barletta,“Progress in abrasive fluidized bed machining”, Journal of Materials

Processing Tech. (November 2009), 209 (20), pg. 6087-6102

[196] Jain, N. K. and Jain, V. K. (2001) Modeling of MR in mechanical type advanced

machining processes: A state-of-art review. International Journal of Machine Tools

and Manufacturing 41:11 , pp. 1573-1635.

[197] Singh, S. , Shan, H. S. and Kumar, P. (2006) Quality optimization of surface

finishing by magnetic field assisted abrasive flow machining through Taguchi

technique. International J. Computer Applications in Technology 27:1 , pp. 31-37.

[198] Jain, N. K. , Jain, V. K. and Deb, K. (2007) Optimization of process parameters of

mechanical type advanced machining processes using genetic

algorithms. International Journal of Machine Tools and Manufacture 47:6 , pp. 900-

919.

248

[199] Singh, S. (2002) — Studies in Metal Finishing with Magnetically Assisted

Abrasive Flow machining. Ph.D thesis, Mechanical and Industrial Engg Dept., IIT

Roorkee (India)

[200] Ross, P.J. (1988), “Taguchi techniques for quality engineering”, McGraw-Hill

Book Company, New York.

*201+ Roy, R.K. (1990), “A primer on Taguchi method”, Van Nostrand Reinhold, New

York.

[202] Barker, T.B. (1990), “Engineering quality by design”, Marcel Dekker, Inc., New

York.

*203+ Byrne, D.M. and Taguchi, S. (1987), “The Taguchi approach to parameter

design”, Quality Progress, 19-26.

*204+ Barker, T.B. (1986), “Quality engineering by design: Taguchi‟s Philosophy”,

Quality Progress, December, 33-42.

*205+ Ross, P.J. (1996), “Taguchi techniques for quality engineering”, McGraw-Hill

Book Company, New York.

*206+ Taguchi, G. and Wu, Y. (1979), “Off-line quality control”, Central Japan Quality

Control Association, Nagaya, Japan.

[207] Peace, G.S. (1993), Taguchi Methods: A hands on approach, Addison Wesley,

New York.

[208] Roy, R.K. (2001), “Design of Experiments Using the Taguchi approach” Canada

John Wiley & Sons.

[209] Metropolis, N. and Ulam, S., 1949, "The Monte Carlo Method." J. Amer. Stat.

Assoc. 44, 335-341.

[210] Hoffman, P., 1998, The Man Who Loved Only Numbers: The Story of Paul

Erdos and the Search for Mathematical Truth. New York: Hyperion, pp. 238-239.

[211] "Introductory Econometrics via Monte Carlo Simulation with Microsoft Excel."

From http://www.wabash.edu/econometrics/home.htm

[212] Eric W. Weisstein. "Monte Carlo Method." From MathWorld--A Wolfram Web

Resource.

[213] Paul Coddington. "Monte Carlo Simulation for Statistical Physics." Northeast

Parallel Architectures Center at Syracuse University

249

[214] Wittwer, J.W., "Monte Carlo Simulation Basics" From Vertex42.com, June 1,

2004, http://vertex42.com/ExcelArticles/mc/MonteCarloSimulation.html

[215] Saaty, Thomas L.; Peniwati, Kirti (2008). Group Decision Making: Drawing out

and Reconciling Differences. Pittsburgh, Pennsylvania: RWS Publications. ISBN 978-1-

888603-08-8.

[216] Saaty, Thomas L. (2008-06). "Relative Measurement and its Generalization in

Decision Making: Why Pairwise Comparisons are Central in Mathematics for the

Measurement of Intangible Factors - The Analytic Hierarchy/Network

Process". RACSAM (Review of the Royal Spanish Academy of Sciences, Series A,

Mathematics) 102 (2): 251–318. Retrieved 2008-12-22.

[217] Saaty, Thomas L. (2008). Decision Making for Leaders: The Analytic Hierarchy

Process for Decisions in a Complex World. Pittsburgh, Pennsylvania: RWS

Publications. ISBN 0-9620317-8-X.

[218] Saaty, Thomas L. (2010). Principia Mathematica Decernendi: Mathematical

Principles of Decision Making. Pittsburgh, Pennsylvania: RWS Publications. ISBN 978-

1-888603-10-1.

[219] SAATY, Thomas L.(1990), “How to make a decision – The Analytical Hierarchy

Process”, European Journal of Operation Research, 48, 19-26

[220] Rao, R. V. Machinability evaluation of work materials using a combined

multiple attribute decision-making method. Int. J. Adv. Mfg Technol., 2006, 28, 221–

227.

[221] Rao, R. V. and Davim, J. P. A decision-making framework model for material

selection using a combined multiple attribute decision-making method. Int. J. Adv.

Mfg Technol., 2008, 35, 751–760.

[222] Byun, H. S. and Lee, K. H. A decision support system for the selection of a rapid

prototyping process using the modified TOPSIS method. Int. J. Adv. Mfg Technol.,

2005, 26, 1338–1347.

[223] Garg, R. K., Agrawal, V. P., and Gupta, V. K. Coding, evaluation and selection of

thermal power plants – a MADM approach. Electl Power Energy Syst., 2007, 29, 657–

668.

[224] Bhangale, P. P., Agrawal, V. P., and Saha, S. K. Attribute based specification,

comparison and selection of a robot. Mechanism Mach. Theory, 2004, 39, 1345–

1366.

[225] Mahmoodzadeh, S., Pariazar, M., Zaeri, M. S., and Torkamani, M. A. Evaluate

projects by using multiple criteria decision making techniques. In Proceedings of the

250

2007 IEEE/IEEM Conference, Singapore 2–5 December 2007, pp. 272–276 (IEEE EMS

Singapore).

[226] Isiklar, G. and Buyukozkan, G. Using a multi-criteria decision making approach

to evaluate mobile phone alternatives. Comput. Standards & Interfaces, 2007, 29,

265–274.

[227] Lin, M.-C., Wang, C.-C., Chen, M.-S., and Chang, C. A. Using AHP and TOPSIS

approaches in customer-driven product design process. Comput. in Industry, 2008,

59, 17–31.

[228] Rao, R. V. Evaluating flexible manufacturing systems using a combined multiple

attribute decision making method. Int. J. Prod. Res., 2008, 46(7), 1975–1989.

[229] Yurdakul, M. and IC, Y. T. ¸ Development of a performance measurement

model for manufacturing companies using the AHP and TOPSIS approaches. Int. J.

Prod. Res., 2005, 43(21), 4609–4641.

[230] Yang, T. and Hung, C.-C. Multiple-attribute decision making methods for plant

layout design problem. Robotics and Computer-Integrated Mfg, 2007, 23, 126–137.

[231] Hwang, C. L. and Yoon, K. Multiple attribute decision making – method and

applications: a state-of-the-art survey, 1981 (Springer-Verlag, New York).

[232] Tong, L.-I., Wang, C.-H., and Chen, H.-C. Optimization of multiple responses

using principal component analysis and technique for order preference by similarity

to ideal solution. Int. J. Adv. Mfg Technol., 2005, 27, 407–414.

[233] Liao, H.-C. Using PCR-TOPSIS to optimize Taguchi’s multi-response problem.

Int. J. Adv. Mfg Technol., 2003, 22, 649–655.

[234] Saaty, T. L. Analytic hierarchy process, 1980 (McGrawHill, New York).

[235] Pradeep Kumar, P.B. Barua and JL Gaindhar, “Quality optimization(multi-

characteristics) through Taguchi’s technique and Utility concept”, Quality and

Reliability Engineering International, 2000; 16: 475-485

[236] Gupta V, Murthy PN, “An Introduction to Engineering Design Methods”, Tata

Mcgraw I-IEII: New Delhi, 1982

[237] Bosser JL, “Quality Function Deployment – A Practitioner Approach” Marcel

Dekkar: New York, New York, 1991

[238] Roy K, “A Primer on Taguchi Methods”, Van Nonstrand Reinhold: New York,

1990.

[239] Deng JL, “Introduction to grey system theory”, J Grey System, 1989, 1:1-24

251

[240] Arshad Noor Siddiqui, Zahid A. Khan, Zulquernain Mallick, “Grey relational

analysis coupled with principal component analysis for optimization design of the

process parameters in in-feed centreless cylindrical grinding”, International Journal

of Advanced Manufacturing Technology, 2010, 46, 983-992

[241] Lu, HS, Chang CK, Hwanga NC, Chung CT, “Grey relational analysis coupled with

principal component analysis for optimization design of the cutting parameters in

high-speed end milling”, Journal of Material Processing Technology, 2008, 10, 1016,

08-030

[242] Cochran, G., and Cox, G.M. (1962), “Experimental design”, Asia Publishing

House, New Delhi.

[243] Box, G. E. P. and Wilson, K.B. (1951) On the Experimental Attainment of

Optimum Conditions (with discussion). Journal of the Royal Statistical Society Series

B 13(1):1–45

[244] Box, G. E. P. and Draper, Norman. 2007. Response Surfaces, Mixtures, and

Ridge Analyses, Second Edition [of Empirical Model-Building and Response Surfaces,

1987], Wiley

[245] Montgomery, DC, “Design and analysis of experiments”, 5th Ed. Wiley, New

York, 2005

[246] Minitab: Minitab version 15 Document, (2007), www.minitab.com

[247] Saad Saeed Siddiqui and M Hameedullah,(2011) “Micromachining internal

holes & cavities and investigating the performance measures in abrasive flow

machining”, Proceedings International Conference on Emerging Trends in

Mechanical Engineering (ICETME 2011) Patiala February 24- 26,2011, pp 323 – 331.

[248] Saad Saeed Siddiqui and M Hameedullah, (2010) “Abrasive Flow Machining

performance measure on work-piece surfaces having different vent/passage

considerations for media outflow”, International Journal of Computer

Communication and Information System (IJCCIS) Vol 2, No.1, July-Dec’2010, pp 194 –

199 ISSN: 0976-1349.

[249] Saad Saeed Siddiqui and M Hameedullah, (2010) “Micromachining blind holes

and investigating the performance measures in abrasive flow machining” 2Nd

International Conference on Production & Industrial Engineering (CPIE 2010)

Jalandhar 3 – 5 December 2010, pp 649 – 656, ISBN: 978-81-920453-0-6.

[250] Saad Saeed Siddiqui and M Hameedullah, (2010) “Abrasive flow machining

performance measures on work-pieces of different geometrical shapes & sizes”,

252

Proceedings of Advancements & Futuristic Trends in Mechanical and Industrial

Engineering (AFTMIE-2010) Bilaspur November 12-13 2010, pp 25 – 30.

[251] Saad Saeed Siddiqui and M Hameedullah, (2010) “Experimental Investigations

of the Effect of Work-piece Geometry on the Performance Measures in Abrasive

Flow Machining”, Proceedings International Conference on Emerging Trends in

Engineering and Technology (IETET 2010) October 14-16, 2010, pp.36-41, ISBN: 978-

93-80697-22-2.

[252] Saad Saeed Siddiqui and M Hameedullah , (2011) “Micromachining work-

pieces of different geometries and investigating the performance measures in

abrasive flow machining”, Proceeding of the 8th Saudi Engineering Conference

(SEC8), Buraydah, Saudi Arabia, Dec. 10-13, 2011(under press).

[253] Fung, C. P. Manufacturing process optimization for wear property of fiber-

reinforced polybutylene composites with grey relational. Wear, 2003, 254: 298-306.

[254] Tosun, N. Determination of optimum parameters for multiperformance

characteristics in drilling by using grey relational analysis. International Journal of

Advanced Manufacturing Technology, 2006, 28 (5-6): 450- 455.