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BIBLIOGRAPHY
Abilio, M., Pinho. D.J., Alfredo, S.R. and Antonio, A.F. (2007) Influence of
the submerged arc welding in the mechanical behaviour of the
P355NL1 steel-Part II: analysis of the low/high cycle fatigue
behaviours. Journal of Material Science, 42: 5973–5981.
Aggarwal, A. and Singh, H. (2005) Optimization of Machining Techniques-
A Retrospective and Literature Review. Sadhana, 30(6): 699-711.
Aksoy, M., Ero, M. and Orhan, N. (1999) Effect of coarse initial grain size
on microstructure and mechanical properties of weld metal and HAZ of
a low carbon steel. Material Science and Engineering, 269 (1): 1-9.
Aksoy, M., Ero, M., and Orhan, N. (1999) Effect of coarse initial grain size
on microstructure and mechanical properties of weld metal and HAZ of
a low carbon steel. Material Science and Engineering, 269 (1): 1-9.
Al-Aomar, R. (2002) Robust Simulation based Multi criteria Optimization
Methodology”, Proceedings of the 34th conference on Winter
simulation: exploring new frontiers, San Diego, California, 2(8-
11):1931-1939.
Ana, M., Paniagua, M., Victor, M. Lopez, H., Hector, J., Dorantes, R.,
Paulino, E., Diazb., E. and Diaz, V. (2009) Effect of TiO2-containing
fluxes on the mechanical properties and microstructure in submerged-
arc weld steels. Material Characterization, 60(1):36-39.
189
Ana, M., Paniagua, M., Victor, M., Lopez, H., Maribel, L. and Saucedo,
M. (2005) Influence of the Chemical Composition of Flux on the
Microstructure and Tensile Properties of Submerged-Arc Welds.
Journal of Materials Processing Technology, 169: 346-351.
Ana, M., Paniagua. M., Paulino, E.D., Victor, M. and Lopez, H. (2003)
Chemical and structural Characterization of the crystalline phases in
agglomerated fluxes for submerged arc welding. Journal of Materials
Processing Technology, 141: 93-100.
Antony, J. and Antony, F (2001) Teaching the Taguchi Method to Industrial
Engineers. Work Study, 50(4): 141-149.
Antony, J. and Kaye, M. (1996) An application of Taguchi's parameter
design methodology for process improvement. Journal of Quality
World Technical Suppl. 350-41.
Asiabanpour, B., Palmer, K. and Khoshnevis, B. (2004) An Experimental
Study of Surface Quality and Dimensional Accuracy for Selective
Inhibition of Sintering. Rapid Prototyping Journal, 10(3), 181-192.
Avner, H. (2000) Introduction to Physical Metallurgical. Second Edition,
Tata Mcgraw-Hill, New-Delhi.
Baach, H., Nadkarni, S.V. and Vishvanasth, P.S. (1981) Submerged arc
welding: Combined increased deposition rates with improved
mechanical properties. Proceedings of the National Conference, Trichi,
India.
190
Babu, S.P.K. and Natarajan, S. (2008) Influence of heat input on high
temperature weldment corrosion in submerged arc welded power plant
carbon steel. Materials & Design, 29(5): 1036–1042.
Basu, B. and Raman, R. (2002) Micro structural Variations in a High-
Strength Structural Steel Weld under Isoheat Input Conditions.
Welding Journal, 81(11): 239s-248s.
Baune, C. Bonnet. and Lieu, S. (2000) Reconsidering the basicity of FCAW
consumables- Part1: Solidified slag composition of FCAW
consumable as a basicity indicator. Welding Journal, 79 (3): 57s- 65s.
Baune, E., Bonnet, C. and Liu, S. (2000b) Reconsidering the basicity of
FCAW consumables-Part2: Solidified slag composition of FCAW
consumable as a basicity indicator, Welding Journal Suppl , 79 (3):
66s - 75s.
Baune, E., Bonnet, C., and Liu, S. (2000a) Reconsidering the Basicity of a
FCAW Consumable-Part 1: Solidified Slag Composition of a FCAW
Consumable as a Basicity Indicator. Welding Research Suppl. 3:57s-
65s.
Bebis, G. and Georgiopoulus, M. (1994) Feed Forward Networks, Why
Network Size is so important, IEEE Potential, 27-31.
Beck, H.P. and Jackson, A.R. (1996) Recycling of SAW Slag Proves
Reliable and Repeatable. Welding Journal, 75(66): 51-54.
191
Behçet, G. and Nizamettin, K. (2003) Wear behavior of bulldozer rollers
welded using a submerged arc welding process, Materials and Design,
24: 537-542.
Belton, G. R., Moore, T. J. and Takings, E.S. (1963) Slag Metal Reactions
in Submerged Arc Welding, Welding Journal, 42(7): 289s- 297s.
Bennet, A. P. and Stanley, P. J. (1966) Fluxes for the SAW of QT 35 Steel.
British Welding Journal, 13: 59-66.
Bennett, A.P. (1970) Using basic fluxes. Metal Construction, December: 523-
527.
Besseris, George. J. (2008) Multi-response optimization using Taguchi
method and super ranking concept. Journal of Manufacturing
Technology Management, 19(8):1015-1029.
Bhadeshia, H. (1997) Mathematical Modeling of Weld Phenomena III,
London: Institute of Materials, 229-284.
Bhole, S.D., Nemade, J.B., Collins, L. and Cheng, Liu. (2006) Effect of
nickel and molybdenum additions on weld metal toughness in a
submerged arc welded HSLA line-pipe steel. Journal of Materials
Processing Technology, 173: 92–100
Bobrikov, Yu. V., Potapov, N.N. and Volauev, Yu. S. (1983) The
metallurgical properties of silicon fluxes containing halides and
alkaline metal oxides. Automatic Welding, 36(6): 41-43.
192
Box G.E.P, Hunter W.G. and Hunter J.S. (1976) Statistics for
experimenters: An introduction to design, data analysis, and model
building, New York: John Wiley & Sons.
Box, G.E.P. and Behnken, D.W. (1960) Some new three level designs for the
study of quantitative variables. Techno metrics, 2: 455-475.
Brien, R.L. (1978). Welding Handbook, Vol. 2, 8th Edition, Miami. U.S.A:
American Welding Society.
Butler, C.A. and Jackson, C.E. (1967) Submerged arc welding
characteristics of CaO-TiO2-SiO2 system. Welding Journal, 46(11):
448s - 445s.
Eijk, C. Vander., Grong, O. and Hjelen, J. (1999) Quantification of
inclusions stimulated ferrite nucleation in wrought steel using the
SEMEBSD technique, Proceedings of the International Conference on
Solid–Solid Phase Transformations’99 (JIMIC-3), Kyoto, Japan.
Caddle, R.M. (1967) The influence of physical properties in on penetration in
arc welding. Transactions of ASME, Journal of Engineering for
Industry, May: 328-332.
Chai, C. S. and Eagar, T. W. (1982) Slag-Metal Reactions in Binary CaF2-
Metal Oxide Welding Fluxes. Welding Research Supplement, July:
229s-232s.
193
Chai, C.S. and Eagar, T.W. (1981) Slag-Metal Equilibrium During
Submerged Arc Welding. Metallurgical Transactions B, 12(B),
September: 539- 547.
Chandel, R.S. (1987) Mathematical modeling of melting rates for submerged
arc welding. Welding Journal, 65 (5): 32s -39s.
Chandel, R.S., Bala, S.R. and Malik, L. (1987) Effect of submerged arc
welding process variables. Welding & Metal Fabrication, August: 302-
30.
Chandel, R.S., Chan, B., Yang, L.J. and Bibby, M.J. (1994) A software
system for anticipating the size and shape of submerged arc welds.
Journal of Materials Processing Technology, 40: 249-262.
Chandel, R.S.and Cheng, H. P. (1997) Effect of increasing deposition rate on
the bead geometry of submerged arc welds. Journal of Materials
Processing and Technology, 72: 124 – 128.
Charles, H. and Entrekin. J.R. (1979) The Influence of Flux Basicity on
Weld-Metal Microstructure. Metallography, 12: 295-312.
Chester, D. (1990) Why Two Hidden Layers Are Better Than One?
Proceedings of IEEE International Joint Conference on Neural
Networks, Washington, DC, 265-268.
Chew B. (1976) Moisture loss and regain by some basic flux covered
electrodes. Welding Journal, 55 (7): 127s - 131s.
194
Christopher, Bayley., Gregory, Glinka. and John, Porter.(2000), Fatigue
crack initiation and growth in A517 submerged arc welds under
variable amplitude loading. International Journal of Fatigue, 22: 799–
808.
Cornu, J. (1988) Advanced Welding Systems, Vol.2, London: IFS Publication.
Dallam, C.B., Liu, S. and Olson, D.L. (1985) Flux composition dependence
of microstructure and toughness of submerged arc HSLA weldments.
Welding Journal, 64 (5): 140s -149s.
Datta S, Bandyopadhyay, A. and Pal P.K. (2006a) Quadratic response
surface modeling for prediction of bead geometry in submerged arc
welding. Indian Weld Journal 39(1):33–43.
Datta, G.L. and Nagesh, D.S. (2002) Prediction of weld bead geometry and
penetration in shielded metal arc welding using artificial neural
networks. Journal of Material Processing Technology, 123(2): 303-
312.
Datta, S., Bandyopadhyay, A. and Pal P.K. (2006) Desirability Function
Approach for solving Multi-Objective optimization problem in
Submerged Arc Welding. International Journal of Manufacturing
Science and Production, 7(2): 127-135.
Datta, S., Bandyopadhyay, A. and Pal P.K.(2008) Modeling and
Optimization of features of bead geometry including percentage
Dilution in Submerged Arc Welding Consuming Mixture of Fresh Flux
195
and Fused Slag. International Journal of Advanced Manufacturing
Technology, 36: 1080-1090.
Datta, S., Bandyopadhyay, A. and Pal, P.K. (2008), Application of Taguchi
philosophy for parametric optimization of bead geometry and HAZ
width in submerged arc welding using a mixture of fresh flux and fused
flux. International Journal of Advanced Manufacturing Technology,
36: 689-698.
Datta, S., Bandyopadhyay, A. and Pal, P.K. (2008), Solving multi-criteria
optimization problem in submerged arc welding consuming a mixture
of fresh flux and fused slag. International Journal of Advanced
Manufacturing Technology, 35(9-10): 935-942.
Datta, S., Bandyopadhyay, A., Pal P. K, Nandi, G. and Roy, S. C. (2007)
Controlled Random Search Algorithm for Parametric Optimization of
Bead Geometry in Submerged Arc Double Pass Butt Welding.
Proceedings of the Global Conference on Production and Industrial
Engineering, March 22-24, Dr. B. R. Ambedkar National Institute of
Technology, Jalandhar, India.
Datta, S., Sundar, M., Bandyopadhyay, A., Pal, P.K., Nandi, G. and Roy,
S.C. (2006b) Statistical modeling for predicting bead volume of
submerged arc butt welds. Australasian Welding Journal, 51(2):39–47
Davies, O.L. (1978) The Design and Analysis of Industrial Experiments, New
York: Longman.
196
Davis, M. L. E. and Bailey, N. (1982) Properties of Submerged Arc Fluxes-
Fundamental Studies. Metal Construction, 65(6): 202-209.
Davis, M. L. E. and Bailey, N. (1991) Evidence from Inclusion Chemistry of
Element Transfer during Submerged Arc Welding. Welding Journal,
70(2): 57s-65s.
Davis, M.L. and Bailey, N. (1991) Evidence from inclusion chemistry of
element transfer during submerged arc welding, Weld. J. Suppl. Res. 70
(2):57–61.
Dowling, J.M., Corbett, J.M. and Kerr, H.W. (1986) Inclusion phases and
the nucleation of acicular ferrite in submerged-arc welds in high-
strength low alloy steels, Metall. Trans. A, 17 (9): 1613–1618.
Eagar, T.W. (1980) Oxygen and Nitrogen Contamination during Submerged
Arc Welding of Titanium. Proceedings of the International Conference
of Welding Research, Osaka University, Osaka, Japan.
Eager, T.W. (1978) Sources of weld metal oxygen contamination during
submerged arc welding, Welding Journal, 57(3): 76s - 80s.
Easterling, K.E. (1992) Introduction to the Physical Metallurgy of Welding,
Butterworth-Heinemann, London.
Eroglu, M. and Aksoy, M. (2000) Effect of initial grain size on
microstructure and toughness of intercritical heat-affected zone of a
low carbon steel, Materials Science and Engineering, 286(A): 289–
297.
197
Eroglu, M., Aksoy, M. and Orhan, N. (1999) Effect of coarse initial grain
size on microstructure and mechanical properties of weld metal and
HAZ of a low carbon steel, Materials Science and Engineering,
269(A): 59-66.
Evans, G.M. (1989) The effect of chromium on the microstructure and
properties of C–Mn all-weld metal deposits. Weld Met Fabr, 57(7):
346– 58.
Farias, J.P., Scotti, A., Balsamo, P.S. and Surian, E. (2004) The Effect of
Wollastonite on Operational Characteristics of AWS E6013 Electrodes,
Journal of Brazilian Society of Mechanical Sciences and Engineering,
26(3): 317-322.
Farias, J.P., Quites, A.M. and Surian, E.S. (1997) The effect of magnesium
content on the arc stability of SMAW E7016-C2L / 8016-C2 covered
electrodes. Welding journal, 78(1): 1s - 8s.
Ferrera, K. P. and Olson, D. L. (1975) Performance of the MnO-SiO2-CaO
Systems as Welding Fluxes, Welding Journal, 54: 211s-215s.
Fleck, N.A., Grong, O., Edwards, G. R. and Matlock, D. K. (1986) The
Role of Filler Metal Wire and Flux Composition in the SAW Metal
Transformation Kinetics, Welding Journal, 65(5): 113s-121s.
Flick, N.A. (1986) The role of filler metal wire and flux composition in
submerged arc weld metal transformation kinetics. Welding Journal, 66
(5): 113s- 120s.
198
Ful-Chiang, Wu. (2005) Optimization of Correlated Multiple Quality
Characteristics Using Desirability Function. Quality Engineering,
17(1): 119-126.
George, F. (1986) Applied Metallography. Van Nastrand Reinhold Company,
New-York.
Ghosh, P.K. and Ahmed, M. (1999) Characterization of Mechanical
Properties of Multipass Submerged Arc Weld by Model Analysis of its
Microstructure Facilitated by Aid of Computer. Indian Welding
Journal, 32(4): 32-42.
Ghosh, P.K. and Khanna, A. (1991) The influence of electrode polarity and
welding current on mechanical properties of submerged arc welding.
Indian Welding Journal, 24(3): 145-150.
Goloshubov,V.I. (1972), The viscosity and surface tension of the certain
fluxes. Automatic Welding, 25 (2): 61-62.
Gretoft, B., Bhadeshia, H. and Svensson, L.E. (1986) Development of
Microstructure in the Fusion Zone of Steel Weld Deposits. Acta
Stereol, 5(2): 365-371.
Gulenç, B. and Kahraman, N. (2003) Wear behavior of bulldozer rollers
welded using a submerged arc welding process. Materials and Design,
24: 537-542.
199
Gunaraj V, Murugan N. (2000) Prediction and optimization of weld bead
volume for the submerged arc process-part-2. Weld Res. Suppl.79(11):
331–338
Gunaraj, V. and Murgun, N. (1999) Application of response surface
methodology for predicting weld bead quality in submerged arc
welding of pipes. Journal of Materials Processing Technology, 88:
266-275.
Gunaraj, V. and Murugan, N. (2000) Prediction and Optimization of Weld
Bead Volume for the Submerged Arc Process- Part-1. Welding
Research Suppl. 79(10): 286s-294s.
Gunaraj, V. and Murugan, N. (1999) Prediction and Comparison of the Area
of the Heat Affected Zone for the Bead-no-Plate and Bead-on-Joint in
Submerged Arc Welding of Pipes. Journal of Materials Processing
Technology, 95(1-3): 246-261.
Gupta, S.R. and Arora, N. (1993) Influence of Flux Basicity on Weld Bead
Geometry and HAZ in Submerged Arc Welding. Journal of Material
Processing Technology, 39(1-2): 33-42.
Gupta, S.R. and Gupta, P.C. (1988) Investigation into flux consumption in
submerged arc welding. Indian Welding Journal, 21 (3): 365-369.
Gupta, S.R. and Arora,N.(1991) Influence of flux basicity index on weld
bead geometry and HAZ submerged arc welding. Indian Welding
Journal, 24 (3):127-133
200
Hazlett, T.H. (1957) Coating ingredients influences on surface tension arc
stability and bead shape. Welding Journal, 38 (1): 18s - 22s.
Heuschkel, J. (1969) Weld metal composition control. Welding Journal,
48(8): 323s -347s.
Heuschkel, J. (1973) Weld metal property control. Welding Journal, 52(1): 1s
-20s.
Hould croft P.T. (1989), Submerged Arc Welding, 2nd ed., England:
Abington Publishing, Cambridge.
Indacochea, J.E. and Olson, D.L. (1983) Relationship of weld–metal
microstructure and penetration to weld-metal oxygen control. Materials
for energy systems, 5 (3): 139- 145.
Irvine, K.J. (1969) A comparison of the bainite transformation with other
strengthening mechanisms in high strength structural steels. Symp. on
Steel Strengthening Mechanisms, Climax Molybdenum. MI, USA. 55–
65.
Jackson, C.E. and Shrubsall, A. E. (1953) Control of penetration and
melting ratio with welding technique. Welding Journal, 32(4): 172s-
178s.
Janez, Tueck. (2000) Mathematical modeling of melting rate in twin-wire
welding. Journal of Material Processing, 100(4): 250-256.
Jang, J. and Indacochea, J.E. (1987) Inclusion effects on submerged-arc
weld microstructure. Journal of Materials Science, 2(2): 689-700.
201
Jeffus, Larry. (2000) Welding: Principles and Applications. Florence, KY:
Thomson Delmar Learning.
Jerzy, Nowacki. and Paweł, Rybicki. (2005) The influence of welding heat
input on submerged arc welded duplex steel joints imperfections.
Journal of Materials Processing Technology, 164(165): 1082–1088.
Jeyapaul, R., Shahabudeen, P. and Krishnaiah, K. (2005) Quality
Management Research by Considering Multi-Response Problems in the
Taguchi Method-A Review. International Journal of Advanced
Manufacturing Technology, 26: 1331-1337.
Joarder, A., Saha, S. C. and Ghosh, A. K. (1991) Study of Submerged Arc
Weld Metal and Heat Affected Zone Microstructure of Plain Carbon
Steel. Welding Journal, 151-157.
Joarder, A., Saha, S.C. and Ghose, A.K. (1991) Study of submerged arc
weld metal and heat-affected zone microstructures of plain carbon
steel, Weld. J. Suppl. Res. 70 (6): 141–146.
Jorge, J.C.F., Rebello J.M.A. and Evans, G.M. (1993) Microstructure and
toughness relationship in C–Mn – Cr all weld metal deposits. IIW
DOC. II-A-880-93.
Jorge, J.C.F., Souza, L.F.G., and Rebello, J.M.A. (2001) The effect of
chromium on the microstructure/toughness relationship of C–Mn weld
metal deposits. Materials Characterization, 47:195– 205.
202
Kaae,J.L. (1968) Mechanical Properties, Microstructure and Susceptibility to
Cracking in the HAZ of Controlled Rolled Niobium Treated Low
Carbon Manganese Steels. British Welding Journal, 12(7): 395-398.
Kalpakjian, Serope, and Steven Schmid. (2006) Manufacturing Engineering
and Technology, 5th ed. Upper Saddle river, NJ: Pearson Prentice Hall.
Kane,S.F.(1999) Welding consumable Development for a cryogenic
application. Welding Journal.78 (8):292s-300s.
Kang, B. Y. (2005), Fuzzy Regression Method for Prediction and Control the
Bead Width in the Robotic Arc-Welding Process. Journal of Materials
Processing Technology, 164(165): 1134-1139.
Kanjilal, P., Mazumder, S. K., Pal, T.K.(2004) Prediction of Submerged Arc
Weld-Metal Composition from Flux Ingredients with the help of
Statistical Design of Mixture Experiment. Scandinavian Journal of
Metallurgy, 33: 146-149.
Kanjilal, P., Pal, T.K. and Majumdar, S.K. (2006) Combined effect of flux
and welding parameters on chemical composition and mechanical
properties of submerged arc weld metal. Journal of Materials
Processing Technology, 171: 223-231.
Karaoglu, S. and Secgin, A. (2008), Sensitivity analysis of submerged arc
welding process parameters. Journal of Material Processing
Technology, 202(3): 500-507.
203
Khallaf, M.E., Ibrahim, M.A., EI-Mahallawy N.A. Taha, M.A. (1997) On
crack susceptibility in the submerged arc welding of medium-carbon
steel plates. Journal of Materials Processing Technology, 68: 43-49.
Khuri A.I. and Cornell, J.A. (1996) Response Surfaces; Design and Analysis,
New York: Marcel Dekker.
Kim, D. and Rhee, S. (2001) Optimization of arc welding process parameters
using genetic algorithm. Welding Journal, 80(7): 184s -190s.
Kim, D. and Rhee, S. (2004). Optimization of Gas Meal Arc Welding Process
using the Desirability Function and the Genetic Algorithm.
Proceedings of the Institution of Mechanical Engineers, Part B: Journal
of Engineering Manufacture, 218(1): 35-41.
Kim, D., Kang, M. and Rhee, S. (2005) Determination of Optimal Welding
Conditions with a Controlled Random Search Procedure. Welding
Journal, 84:125s-129s.
Kim. I. S., Jeong, Y.J., Lee, C.W. and Yarlagadda, P.K.D.V. (2003)
Prediction of Welding Parameters for Pipeline. Welding using an
Intelligent System, 22(9-10): 713-719.
Kohno, R., Takami, N., Mori,N. and Nagane, K.(1982) New fluxes of
improved weld metal toughness for HSLA steels. Welding Journal,
61(12): 173s – 180s.
Kolhe, K.P.and Datta,C. K. (2005) Prediction of Microstructure and
mechanical properties of multipass Submerged Arc Welding.
204
Proceedings of International Conference on Mechanical Engineering
in Knowledge Age, December 12-14, Delhi College of Engineering,
Delhi, India.
Kolhe, Kishor. P. and Data, C.K. (2008), Prediction of microstructure and
mechanical properties of multipass SAW. Journal of Materials
Processing Technology, 197: 241–249.
Komapov, A.I., Khodakov, V.D. and Volobuev, Yu. (1983) Effects of the
surface tension of steels and fluxes on the shape of deposited metal.
Automatic Welding, 36 (3): 27-29.
Kostrivas, A. and Lippold, J. C. (2000) A Method for Studying Weld Fusion
Boundary Microstructure Evolution in Aluminium Alloys. Welding
Research Suppl. 79: 1s-8s.
Kubli, R.A. and Sharav, W.B. (1961) Advancements in submerged arc
welding of high impact steels. Welding Journal, 40 (11): 497s - 502s.
Kuzmenko, V.G. (1985) Effects of slag on formation of the surface of a weld.
Automatic Welding, 38 (2): 32-35.
Lancaster, J.F. (1980) Metallurgy of Welding, London: Alden Press Ltd. 25–
50.
Lancaster. J.F (1993) Metallurgy of Welding, 5th Edition, London: Publisher.
Chapman and Hall, 171-175.
205
Lau, T., Weatherly, G.C. and Mc Lean, A. (1980) Gas/metal/slag reactions
in submerged arc welding using CaO-Al2O3 based fluxes. Welding
Journal, 69(2): 31s -39s.
Lekthi, Y. (1998) Engineering Physical Metallurgy, Moscow: Mir
Publication.
Lightfoot, M.P., Bruce, G.J., McPherson, N.A. and Woods, K. (2005) The
Application of Artificial Neural Networks to Weld-Induced
Deformation in Ship Plate. Welding Journal, 84:23s-31s.
Little, R.L. (1976) Welding and Welding Technology, New Delhi: Tata-
Mcgraw-Hill publishing Company.
Liu, S. and Olson, D.L. (1986) The role of inclusions in controlling HSLA
steel weld microstructures, Weld. J. Suppl. Res. 65 (6): 139–141.
Livshit, L.G. and Shiryaev, A.I. (1960) A New Ceramic Flux for Hard
Facing. Welding Production, 1: 25-29.
Louise, D. (1981) An introduction to welding fluxes for mild and alloy steels.
Cambridge: The Welding institute, 1-10.
M.Y. Li and Kannatey Asibu, E., Jr. (2002) Monte Carlo Simulation of Heat
–Affected Zone Microstructure in Laser-Beam-Welded Nickel Sheet.
Welding Journal, 81: 37s-44s.
Maghsoodloo, S., Ozdemir, G., Jordan,V. and Huang,C.H. (2004)
Strengths and Limitations of Taguchi‟s Contributions to Quality,
206
Manufacturing, and Process Engineering. Journal of Manufacturing
Systems, 23(2): 73-126.
Maheshwari, Sachin. (1998) Elements transfer behaviour in submerged arc
welding. Ph.D. thesis, IIT, Delhi.
Malin, V. (2001) Root Weld Formation in Modified Refractory Flux One-
Sided Welding: Part 1-Effect of Welding Variables. Welding Research
Suppl. 217s-226s.
Malin, V. (2001) Root Weld Formation in Modified Refractory Flux One-
Sided Welding: Part 2- Effect of Joint Geometry. Welding Journal
Research Suppl. 227s-237s.
Mandatov, N.M. (1969) Shape relationships for under water welding.
Welding Production, 16(3): 18-23.
McGlone, J.C. (1982) Weld bead geometry prediction-A review. Metal
Construction, 14(7): 378-384.
Mitra, U., Chai, C.S. and Eagar, T.W. (1984) Slag-Metal Reactions During
Submerged Arc Welding of Steel. Proceedings of International
Conference and Reliability in Welding, 2, Chinese Mechanical
Engineering Society, Harbin, PRC, B.24.1, 1984.
Mohan, N. and Pandey, S. (2005) Modeling for Element Transfer in
Submerged Arc Welding. Proceedings of International Conference on
Mechanical Engineering in Knowledge Age, December 12-14, Delhi
College of Engineering, Delhi.
207
Mohan, N. and Pandey. S. (2002) Welding current and melting rate in
submerged arc welding. Proceedings of International Conference in
Mechanical Engineering, Dakha, Bangladesh.
Mohandas, T and Reddy, G.M. (2001) Solidification cracking studies on
steels. Indian Welding Journal, 34(3):13-19.
Moi, S. C., Bandyopadhyay, A. and Pal, P. K. (2001) Submerged Arc
Welding with a Mixture of Fresh Flux and Fused Slag. Proceedings of
National Seminar on Advances in Material and Processing, IIT,
Roorkee, India.
Montgomery, D.C. (1992) The use of statistical process control and design of
experiments in product and process improvement, IEE Transactions,
24(5): 4-17.
Montgomery, D.C., Peck, E. A. and Vining, G.G. (2006) Introduction to
Linear Regression Analysis, 3rd edition, New York: John Wiley &
Sons, Inc.
Montgomery, D.C. and Mayers R.H. (1995) Response surface Methodology:
Processes and product Optimization Using Designed Experiments,.
John Wiley & Sons: New York;
Murray, P.E. (2002) Selecting Parameters for GMAW using Dimensional
Analysis. Welding Journal, 125s-131s.
208
Murugan, N. and Gunaraj, V. (2005), Prediction and Control of Weld Bead
Geometry and Shape Relationships in Submerged Arc Welding of
Pipes. Journal of Materials Processing Technology, 168: 478-487.
Murugan, N., Parmer, R.S. and Sud, S.K.(1993) Effect of submerged arc
process variables on dilution and bead geometry in single wire
surfacing, Journal of Materials Processing Technology, 37: 767–780
Nadkarni, S.V. (1988) Modern Arc Welding Technology, New Delhi: IBH
publication.
Nalbant, M., Gokkaya, H. and Sur, G. (2007) Application of Taguchi
Method in the Optimization of Cutting Parameters for Surface
Roughness in Turning. Materials & Design, 28(40:1379-1385.
Nippes, E.S. (1993) Welding, brazing and soldering. Metals Handbook,
Volume-6, 9th Edition. Metal Park Ohio, American Society for Metals:
202-207.
Noordin, M.Y., Venkatesh, V.C, Sharif, S., Elting, S., Abdullah, A. (2004).
Applications of response surface methodology in describing the
performance of coated carbide tools when turning AISI 1045 steel.
Journal of Materials Processing Technology, 145: 46-58.
North, T.H., Bell, H.B. and Raig, C. (1978) Slag/ Metal interaction, oxygen
and toughness in submerged arc welding. Welding Journal, 56 (3): 63s-
73s.
209
Olson, D.L., Dixon, R. and Liby, A.L. (1990) Welding Theory and Practice,
Holland: North- Publication.
Pal, P.K., Bandyopadhyay, A. and Bala A.K. (2001) Some Aspects of
Submerged Arc Welding with Mixture of Fresh Flux and Fused Slag.
Proceedings of the International Conference on Mechanical
Engineering, BUET, Dhaka, Bangladesh.
Palani, P.K. and Murugan, N. (2005) Optimization of Weld Bead Geometry
of Stainless Steel Cladding by Flux Cored Arc Welding Using Excel
Solver. Indian Welding Society Journal, March: 15-19.
Palm, J.H. (1972) How fluxes determine the metallurgical properties of
submerged arc welds. Welding Journal, 51(7):358s -365s.
Pandey Sunil. (2004) Welding current and melting rates in submerged arc
welding: A new approach. Australian Welding Journal, 2: 34-42.
Pandey, N.D., Bharti, A. and Gupta, S.R. (1994) Effect of submerged arc
welding parameters and fluxes on element transfer behaviour and weld-
metal chemistry. Journal of Materials Processing Technology, 40: 195-
211.
Pandey, S. and Mohan, N. (2003) Investigation into flux consumption.
Proceedings of International Conference on CAD, CAM, Robotics and
Autonomous Factories, IIT, Delhi.
Parmar, R.S. and Srihari. T. (1991) Mathematical models for predicting
bead geometry and dimensions in automatic submerged arc welding.
210
Proceedings of International Conference on Computer and
Mathematical Modeling, Maryland, U.S.A.
Patchett, B.M. (1983) Some effects of physical properties on weld bead
formation, in SAW process. Materials for energy system, 5(3): 165 -
174.
Patchett, B.M. and Dancy, E.A. (1980) Discussion on the relationship of
weld penetration to the welding flux. Welding Journal, 59 (1):
Patchett, B.M. and Milner, D.R. (1972) Slag-metal reaction in electro-slag
process. Welding Journal, 51 (10): 491s -505s.
Patchett, B.M. (1974) Some influences of slag composition on heat transfer
and arc stability. Welding Journal, 53 (5): 203s - 210s.
Pathak, A. K. and Datta, G. L. (2004) Three-dimensional finite element
analysis to predict the different zones of microstructure in submerged
arc welding. Proceedings of Institution of Mechanical Engineers Part
B: Journal of Engineering Manufacture, 218: 269-280.
Peng, Y., Chen, W. and Xu, Z. (2001) Study of High Toughness Ferrite Wire
for Submerged Arc Welding of Pipeline Steel. Materials
Characterization, 47: 67-73.
Peng, Yun., Wuzhu, Chen. And Zuze, Xu. (2001) Study of high toughness
ferrite wire for submerged arc welding of pipeline steel. Materials
Characterization, 47: 67– 73.
211
Petropoulos, G.P., Vaxevanidis, N. M., Pandazaras, C. N. and Antoniadis,
A. (2006) Multi-Parameter Identification and Control of Turned
Surface Textures. International Journal of Advanced Manufacturing
Technology, 29: 118-128.
Ping, Li., Fang, M.T.C. and Lucas, J. (1997), Modelling of submerged arc
weld beads using self-adaptive offset neutral networks. Journal of
Materials Processing Technology, 71: 288-298.
Polar, A., Indacochea, J.E. and Blander, M. (1991) Fundamentals of the
Chemical Behavior of Selected Welding Fluxes. Welding Journal,
70(1): 15s-19s.
Potapov, N.N. (1978) A quantitative evaluation of basicity of fluxes. Welding
Production, 25 (9): 4-8.
Potapov, N.N., Kurlanov, S.A. and Lazerev, B.I. (1981) The metallurgical
properties of silicon fluxes containing halides salts and alkaline metal
oxides. Automatic Welding, 34 (6): 38-40.
Prasad, K and Dwivedi, D.K. (2008) Some investigations on microstructure
and mechanical properties of submerged arc welded HSLA steel joints.
International Journal of Advanced Manufacturing Technology, 36(5-
6): 475-483.
Price, W.L. (1977) A Controlled Random Search Procedure for Global
Optimization. The Computer Journal, 20(4): 367-370.
212
Quintana, R., Cruz, A., Perdomo, L. and Castellanos, G., Garcia, L.L.,
Formoso, A. and Cores A. (2003) Study of the transfer efficiency of
alloyed elements in fluxes during the submerged arc welding process.
Welding International, 17 (12): 958–965.
Ramakrishnan, R. and Karunamoorthy, L. (2006) Multi Response
Optimization of Wire EDM Operations Using Robust Design of
Experiments. International Journal of Advanced Manufacturing
Technology, 29: 105-112.
Ramasamy, S., Gould, J. and Workman, D. (2002) Design of Experiments
Study to Examine the Effect of Polarity on Stud Welding. Welding
Journal, 19s-26s.
Ramasawmy, H. and Blunt L. (2002) 3D Surface Characterization of Electro
polished EDMed Surface and Quantitative Assessment of Process
Variables using Taguchi Methodology. International Journal of
Machine Tools and Manufacture, 42: 1129-1133.
Reddy, G. M., Ghosh, P. K. and Khanna, A. (1991) The Influence of
Electrode Polarity and Welding Current on Mechanical Properties of
Submerged Arc Weld. Indian Welding Journal, 23(3): 145-150.
Reddy, N.S.K. and Rao, P.V. (2005) Selection of Optimum Tool Geometry
and Cutting Conditions Using a Surface Roughness Prediction Model
for End Milling. International Journal of Advanced Manufacturing
Technology, 26: 1202-1210.
213
Renwick, B.G. and Patchett, B.M. (1976) Operating characteristics of
submerged arc process. Welding Journal, 55 (3): 69s-79s.
Ridings, G.E., Thomson, R.C. and Thewlis, G. (2002) Prediction of
Multiwire Submerged Arc Weld Bead Shape Using Neural Network
Modeling. Science and Technology of Welding and Joining, 7(5): 265-
279.
Rissone, N.M., Farias, J.P., Surian, E.S. and Bott, S. (2002). ANSI / AWS
A5.1-91 E6013 rutile electrodes: the effect of calcite. Welding Journal,
81(12): 113s-120s.
Robinson M.H. (1961) Observation on Electrode Melting Rate During
Submerged Arc Welding. Welding Journal, 40: 503s-515s.
Robinson, M.H. (1983) Observation on electrode melting rates during
submerged arc welding. Welding Journal, 62 (11): 503s-509s.
Rowlands, H., Antony, J. and Knowles, G. (2000) An Application of
Experimental Design For Process Optimization. The TQM Magazine,
12(2): 78-83.
Roy, S. S. (2006) Design of Genetic-Fuzzy System for Predicting Surface
Finish in Ultra-Precision Diamond Turning of Metal Matrix
Composite. Journal of Materials Processing Technology, 173: 337-
344.
Samiti, Z. (1986) Automatic pulsed MIG welding. Metal Construction 1: 38R-
33R.
214
Sarkar, B.R., Doloi, B. and Bhattacharyya, B. (2006) Parametric analysis of
Discharge Machining of Silicon Nitride Ceramics. International
Journal of Advanced Manufacturing Technology, 28(9-10): 873-881.
Schwemmer, D.D. and Olson, D.L. (1979) Relationship of Weld Penetration
to Welding Fluxes. Welding Journal, 58 (5): 153s-160s.
Shan-Ping Lu., Oh-Yang, K., Tae-Bum, K.and Kwon-Hu, K. (2004)
Microstructure and wear property of Fe–Mn–Cr–Mo–V alloy cladding
by submerged arc welding. Journal of Materials Processing
Technology, 147: 191-196.
Sharma, A., Arora, N. and Mishra, B.K. (2008) A practical approach
towards mathematical modeling of deposition rate during twin-wire
submerged arc welding. International Journal of Advanced
Manufacturing Technology, 36: 463-474.
Shultz, B.L. and Jacson C.E. (1973) Influence of weld bead area on weld
metal mechanical properties. Welding Journal, 52(1):26s- 37s.
Singh, K., Pandey, S. and Arul M.R. (2005) Effect of Recycled Slag on Bead
Geometry in Submerged Arc Welding. Proceedings of International
Conference on Mechanical Engineering in Knowledge Age, December
12-14, Delhi College of Engineering, Delhi.
Singh, K., Pandey, S. and Mani, R.A. (2006) Recycling of Submerged
Welding Slag. Australasian Welding Journal, 51(2): 34-38.
215
Sirvanci. M. B. and Durmaz, M. (1993) Variation reduction by the use of
designed experiments. Quality Engineering, 5(4): 611-618.
Smith, N.J. (1989). Microstructure / Mechanical property relationships of
submerged arc welds in HSLA 80 steel. Welding Journal, 68(3): 112s-
120s.
Songbai, Xue. and Wang Donglin. (1994) The effect of Chemical
metallurgical factors on contents of phosphorus and sulfur in weld
metal during submerged arc welding. Proceedings of Hanjie Xuebao
Transactions of China, Welding Institute, 14 (4): 215- 220.
Srihari, T. (1992) Submerged arc welding of high Strength low alloy steels.
Ph.D. thesis, IIT, Delhi.
Stuck, S.S. and Stout, R.D. (1972) Heat treatment effects in multi-pass
weldments of high strength steel. Welding Journal, 52 (10): 508s -
514s.
Sui, S.H., Cai W., Liu Z.Q., Song T.G. and Zhang, A. (2006) Effect of
Submerged Arc Welding Flux Component on Softening Temperature.
Journal of iron and steel research, 13(2): 65-68.
Suresh, P.V.S., Rao, P. and Deshmukh, S. G. (2002) A Genetic Algorithm
approach for optimization of Surface Roughness prediction model.
International Journal of Machine Tools and Manufacture, 42: 675-
680.
216
Surian, E and Boniszewski, T. (1992) Effect of manganese and type of
current on the properties and microstructure of all- weld- metal
deposited with E7016-1 electrodes. Welding Journal, 72 (9): 348s-
360s.
Surian, E., Maranillo, E. and Boniszewski, F. (1995) The effect of carbon in
E7027 SMAW electrodes all weld metal. Welding Journal, 75 (8):
279s-280s.
Surian, E., Trotti, A. Cassanelli, A. and Devedia, L.A. (1994) Influence of
chromium on mechanical properties and microstructure of weld metal
from a high-strength SMA electrode. Welding Journal, 75 (8): 45s-54s.
Surian, E.S. and Vedia, L.A. (1999) All-Weld-Metal Design for AWS
E10018M, E11018M and E12018M Type Electrodes. Welding
Research Suppl. 217s-228s.
Svensson, L.E. (1994) Control of Microstructures and Properties in Steel Arc
Welding, CRC Press, Boca Raton, FL.
Synder, J.P. and Pense, A.W. (1982) The effects of Titanium on submerged
arc weld metal. Welding Journal, 61 (7): 201s –210 s.
Tanaka, J., Kitada, T., Nagarwa, Y., Kunisada, Y. and Nakagawa, H.
(1980) Element transfer behavior during submerged arc welding.
Proceedings of International Conference on Weld Pool Chemistry and
Metallurgy, Cambridge, England, The Welding Institute: 279-288.
217
Tandon, S., Kanshal, G.C. and Gupta, S.R. (1988) Effect of Flux
Characteristics on HAZ during Submerged Arc Welding. Proceedings
of the International Conference on Welding Technology, September,
University of Roorkee, 65-73.
Tarlinsku. (1980) The effect of viscosity of slag on the welding and
technological properties of electrodes. Svar. Proiz. 9: 21-22
Tarng, Y.S., Yang, W.H. and Juang, S.C. (2000) The Use of Fuzzy Logic in
the Taguchi Method for the Optimization of the Submerged Arc
Welding Process. International Journal of Advanced Manufacturing
Technology, 16:688–694.
Tarng, Y.S. and Chang, S.C. (2002) The use of grey- based Taguchi methods
to determine submerged arc welding process parameters in hard facing.
Journal of Materials Processing Technology, 128: 128-131.
Tarng, Y.S., Juang, S.C., Chang, C.H. (2002) The Use of Grey-Based
Taguchi Methods to determine Submerged Arc Welding Process
Parameters in Hardfacing. Journal of Materials Processing
Technology, 128: 1-6.
Thier. H. (1980) Metallurgical reactions in submerged arc welding. Weld Pool
Chemistry and Metallurgy, International Conference, Cambridge,
England, The Welding Institute: 271-278.
218
Tsai, H. L., Tarng Y. S. and Tseng C. M. (1996) Optimization of Submerged
Arc Welding Process Parameters in Hardfacing. International Journal
of Advanced Manufacturing Technology, 12: 402-406.
Tsai, J.T., Liu, T.K. and Chou, J.H. (2004) Hybrid Taguchi-Genetic
Algorithm for Global Numerical Optimization. Evolutionary
Computation, Proceedings of IEEE Transactions, 8(4): 365-377.
Tuliani, S.S., Boniszewski, T. and Eatan, N.F. (1972) Carbonate fluxes for
submerged arc welding of mild steel. Welding and Metal Fabrication,
40 (7): 247-250.
Tusek, J. (1999) A Mathematical Model for the Melting Rate in Welding with
a Multiple Wire Electrode. Journal of Physics D: Applied Physics, 32:
1739-1744.
Tusek, J. and Suban, M. (2003) High-productivity multiple-wire submerged-
arc welding and cladding with metal powder addition. Journals of
Materials Processing Technology, 133: 207-213.
Unal, R., and Dean, Edwin B. (1991) Taguchi Approach to Design
Optimization for Quality and Cost: An Overview. Proceedings of the
International Society of Parametric Analysts 13th Annual Conference,
May 21-24, 1991, New Orleans, LA.
Vishvanath, P.S. (1982) Submerged arc welding fluxes. Indian Welding
Journal, 15(1): 1-11.
219
Vitek, J.M., Iskander, Y.S. and Oblow, E.M. (2000a) Improved Ferrite
Number Prediction in Stainless Steel Arc Welds Using Artificial
Neural Networks-Part 1: Neural Network Development. Welding
Research Suppl. 33s-40s.
Vitek, J.M., Iskander, Y.S. and Oblow, E.M. (2000b) Improved Ferrite
Number Prediction in Stainless Steel Arc Welds Using Artificial
Neural Networks-Part 2: Neural Network Results. Welding Research
Suppl. 41s-50s.
Volobue, S. (1982) Metallurgical properties of fluxes with a varying silica
content used in the welding of 08 Kh19N 10B type corrosion resisting
steels. Svar. Proiz. (1):31-33.
Wang, Jen-Ting and Jean, Ming-Der. (2006) Optimization of Cobalt-Based
Hardfacing in Carbon Steel using the Fuzzy Analysis for the Robust
Design. International Journal of Advanced Manufacturing Technology,
28: 909-918.
Wang, S.H., Luu, W.C., Ho, K.F. and Wu, J.K. (2002) Hydrogen
permeation in a submerged arc weldment of TMCP steel, Materials
Chemistry and Physics, 77: 447–454.
Wanka, R. (1980) The influence of the physical properties of fluxes on
submerged arc welding. Proceedings of International Conference on
Weld Pool Chemistry and Metallurgy, Cambridge, England, The
Welding Institute. 93-95.
220
Ward, R.G. (1965) An introduction to the physical chemistry of iron and steel
making, London: Publisher English Book Society.
Weiman, C. (1981) Fundamentals of welding, Vol. 2, Florida: American
Welding Society Handbook.
Weymueller, C.R. (1981) Electrodes and fluxes-needed: speed, quality.
Welding Design & Fabrication, (6): 56-64.
Widrow, B. and Lehr, M.A. (1990) 30 Years of Adaptive Neural Networks,
Perception and Back propagation. Proceedings of IEE, 78: 1415-1442.
Wilson, E.M. (1966) SAW of 1% Titanium 18% Nickle-Co-Mo Maraging
Steel. British Welding Journal, 13 (2): 67-74.
Wiseman C. (1976) Welding Hand Book, Vol.1, 7th Edition, American
Welding Society: 137-138.
Witting, L. (1980) Some physical and chemical properties of welding slag and
their influence on slag detachability. Proceedings of International
Conference on Weld Pool Chemistry and Metallurgy, Cambridge,
England, The Welding Institute. 83-90.
Wojnowski, D., Oh, Y.K. and Indacochea, J.E. (2000) Metallurgical
assessment of the Softened HAZ region during multipass welding.
Journal of Manufacturing Science and Engineering, Transactions of
the ASME, 122: 310-315.
221
Wu, C.S. and Gao, J.Q. (2002) Analysis of the heat flux distribution at the
anode of a TIG welding arc. Computational Materials Science, 24:324-
327.
Xue, Y., Kim, I.S., Son, J.S., Park, C.E., Kim, H.H., Sung, B.S., Kim, I.J.,
Kim, H.J. and Kang, B.Y. (2005) Fuzzy Regression Method for
Prediction and Control the Bead Width in the Robotic Arc-Welding
Process. Journal of Materials Processing Technology, 164-165, 1134-
1139.
Yakobashvili, S.B. (1970) Inter-phase tension at the boundary. Armco iron
and ANF –IP flux. Automatic Welding, 23 (6): 20-23.
Yang, L.J. Chandel, R.S., and Bibby, M.J. (1993) The effects of process
variables on the weld deposit area of submerged arc weld. Welding
Journal, 72 (1): 11s-18s.
Yang, L.J., Bibby, M.J. and Chandel, R.S. (1993) Linear regression
equations for modeling the submerged-arc welding process. Journal of
Materials Processing Technology, 39: 33-42.
Yang, L.J., Chandel, R.S. and Bibby, M.J. (1992) The effects of process
variables on the bead width of submerged-arc weld deposits. Journal of
Materials Processing Technology, 29(1): 133-134.
Yang, W.H. and Tarng, Y.S. (1998) Design Optimization of Cutting
Parameters for Turing Operations Based on the Taguchi Method.
Journal of Material Processing Technology, 84: 122-129.
222
Zhang, X.P. and Dorn, L. (1999) Investigation on the possibility of using the
microshear test as a surveillance method to estimate the mechanical
properties and fracture toughness of nuclear pressure vessel steel,
A508CL3, and its joints welded by narrow-gap submerged-arc
welding. International Journal of Pressure Vessels and Piping, 76: 35–
41.