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2017 | OriginalPaper | Buchkapitel

3. Basic Nature of Pulse Current GMA Welding

verfasst von : Prakriti Kumar Ghosh

Erschienen in: Pulse Current Gas Metal Arc Welding

Verlag: Springer Singapore

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Abstract

The governance of pulse characteristics to exploit the merits of P-GMAW in welding of various ferrous and nonferrous metals to produce superior quality welds to those prepared by the conventional GMAW process has been discussed. Control of the simultaneously interacting pulse parameters by considering their summarised influence addressed through a hypothetically developed dimensionless factor ϕ has been critically described. Considering this factor as a primary feature that governs the basic nature of process characteristics of P-GMAW, the behaviour of arcing with respect to its profile, stiffness, efficiency and stability during welding of different metals has been thoroughly discussed. The nature of shielding environment as a function of ϕ during welding of different metals has been addressed. The behaviour of metal transfer has been theoretically analysed and correlated to the factor ϕ in order to realise its desired control by regulating the pulse parameters. The transfer behaviour has been finally discussed taking example of using aluminium, stainless steel and mild steel.

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Vorheriges Kapitel Concept of Pulse Current Gas Metal Arc Welding Process

Nächstes Kapitel Thermal Behaviour of Pulse Current Gas Metal Arc Weld

Ghosh, P.K., Rai, B.K.: Characteristics of pulsed current bead on plate deposit in flux cored GMAW process. ISIJ Int. 36(8), 1036–1045 (1996)CrossRef

Ghosh, P.K.: An analysis of weld characteristics as a function of pulse current MIG welding parameters. Int. J. Join. Mater. 8(4), 157–161 (1996)

Quintino, L., Allum, C.J.: Pulsed GMAW: Interactions between process parameters. Part I Weld. Metal Fab. 16(4), 126–129 (1984)

Ghosh, P.K., Gupta, S.R., Gupta, P.C., Rathi, R.: Fatigue characteristics of pulsed MIG welded Al–Zn–Mg alloy. J. Mat. Sci. 26, 6161–6170 (1991)CrossRef

Ghosh, P.K., Dorn, L., Issler, L.: Fatigue crack growth behaviour of pulsed current MIG weld of Al–Zn–Mg alloy. Int. J. Join. Mater. 6(4), 163–168 (1994)

Potluri, N.B., Ghosh, P.K., Gupta, P.C., Reddy, Y.S.: Studies on weld metal characteristics and their influence on tensile and fatigue properties of pulse current GMA welded Al–Zn–Mg alloy. Weld. J. 75(2), 62s–70s (1996)

Matsuda, F., Nakata, K., Tsukamoto, K., Tohgan, S.: Combined effect of current pulsation and Zr addition on improvement of solidification cracking of AI–Zn–Mg alloy weld metal. Trans. IWRI 14(2), 99–104 (1985)

Ghosh, P.K., Gupta, P.C.: Influence of pulsed current MIG welding on the characteristics of Al–Zn–Mg alloy weldments. Trans. Indian Inst. Met. 44(4), 317–326 (1991)

Ghosh, P.K., Dorn, L., Goecke, S.F.: Universality of correlationships among pulse parameters for different MIG welding power sources. Int. J. Join. Mater. 13(2), 40–47 (2001)

10.

Ghosh, P.K.: Decide pulse parameters for desired properties of pulsed current GMAW weld. In: International Welding Conference (IWC 99) on Welding and Allied Technology—Challenges in 21st century, pp. 18–28. New Delhi, Feb. 15–17 (1999)

11.

Randhawa, H.S., Ghosh, P.K., Gupta, S.R.: Geometric characteristics of pulsed current positional GMA weld. ISIJ Int. 38(4), 276–284 (1998)CrossRef

12.

Ghosh, P.K., Rai, B.K.: Correlations of pulse parameters and bead characteristics in pulsed current flux cored GMAW process. Ind. Weld. J. 31(4), 30–39 (1998)

13.

Ghosh, P.K., Gupta, S.R., Randhawa, H.S.: Characteristics and criticality of pulsed current vertical up GMA weld in steel. Int. J. Join. Mater. 11(4), 99–110 (1999)

14.

Randhawa, H.S., Ghosh, P.K., Gupta, S.R.: Some basic aspects of geometrical characteristics of pulsed current vertical up GMA weld. ISIJ Int. 40(1), 71–76 (2000)CrossRef

15.

Ghosh, P.K., Hussain, H.M.: Morphology and porosity content of multipass pulsed current GMA weld of Al–Zn–Mg alloy. Int. J. Join. Mater. 14(1/2), 16–27 (2002)

16.

Ghosh, P.K., Randhawa, H.S., Gupta, S.R.: Characteristics of a pulsed-current, vertical-up gas metal arc weld in steel. Met. Mater. Trans. A 31A(9), 2247–2259 (2000)CrossRef

17.

Ghosh, P.K., Dorn, L., Hübner, M., Goyal, V.K.: Arc characteristics and behaviour of metal transfer in pulsed current GMA welding of aluminium alloy. J. Mater. Process. Tech. 194(4), 163–175 (2007)CrossRef

18.

Ghosh, P.K., Dorn, L., Kulkarni, S.G., Hofman, F.: Arc characteristics and behaviour of metal transfer in pulsed current GMA welding of stainless steel. J. Mater. Process. Tech. 209, 1262–1274 (2009)CrossRef

19.

Ghosh, P.K., Dorn, L., Devakumaran, K., Hofmann, F.: Pulsed current gas metal arc welding under different shielding and pulse parameters; Part-1: Arc characteristics. ISIJ Int. 49(2), 251–260 (2008)CrossRef

20.

Ghosh, P.K., Dorn, L., Devakumaran, K., Hofmann, F.: Pulsed current gas metal arc welding under different shielding and pulse parameters; Part-2: behaviour of metal transfer. ISIJ Int. 49(2), 261–269 (2009)CrossRef

21.

Ghosh, P.K., Agrawal, B.: Extra narrow gap gas metal arc welding of thick high strength low alloy steel. Proceedings of the 2nd South East European IIW International Conference, Pipeline welding current topic of the region, Sofia, Bulgaria, 21–24 Oct., 168–173 (2010)

22.

Choi, S.K., Yoo, C.D., Kim, Y.S.: The dynamic analysis of metal transfer in pulsed current gas metal arc welding. J. Phys. D Appl. Phys. 31, 207–215 (1998)CrossRef

23.

Wang, G., Huang, P.G., Zhang, Y.M.: Numerical analysis of metal transfer in gas metal arc welding under modified pulsed current conditions. Met. Mater. Trans. B 35B(10), 857–866 (2004)CrossRef

24.

Liu, Anhua, Tang, Xinhua, Fenggui, Lu: Arc profile characteristics of Al alloy in double-pulsed GMAW. Int. J. Adv. Manuf. Technol. 65, 1–7 (2013)CrossRef

25.

Welding Alcoa Aluminum: Aluminum Company of America. Pittsburgh, Pennsylvania (1972)

26.

Ghosh, P.K., Devakumaran, K., Goyal, V.K., Kulkarni, S.G., Ghosh, Aritra K.: Proceedings of the 14th ISME International Conference. Mechanical Engineering in knowledge and age, New Delhi, India, December, Delhi college of engineering, Paper 338 (2005)

27.

Goyal, V.K., Ghosh, P.K., Saini, J.S.: Analytical studies on thermal behaviour and geometry of weld pool in pulsed current gas metal arc welding. J. Mater. Process. Tech. 209, 1318–1336 (2009)CrossRef

28.

Pires, I., Quintino, L., Miranda, R.M.: Analysis of the influence of shielding gas mixtures on the gas metal arc welding metal transfer modes and fume formation rate. Mater. Des. 28, 1623–1631 (2007)CrossRef

29.

Dillenbeck, V.R., Castagno, L.: The effects of various shielding gases and associated mixtures in GMA welding of mild steel. Weld. J. 66(9), 45–49 (1987)

30.

Goyal, V.K., Ghosh, P.K., Saini, J.S.: Process-controlled microstructure and cast morphology of dendrite in pulsed-current gas-metal arc weld deposits of aluminum and Al-Mg alloy. Met. Mater. Trans. A 38(8), 1794–1805 (2007)CrossRef

31.

Goyal, V.K.: Effect of thermal and solidification behaviour on characteristics of pulsed current GMA weld. Ph.D. thesis, Indian Institute of Technology Roorkee, India (2007)

32.

Lancaster, J.F.: The Physics of Welding, 1st Ed., pp. 134–230. IIW, Pergamon Press, New York (1984)

33.

Lin, M.L., Eagar, W.: Influence of arc pressure on weld pool geometry. Weld. J. 64(6), 163s–169s (1985)

34.

Kodama, S., Ikuno, Y.: Process modeling of short-circuiting GMA welding and its application to arc sensor control, Nippon Steel Technical Report No. 95 January, 71–75 (2007)

35.

Murphy, A.B., Tanaka, M., Yamamoto, K., Tashiro, S., Sato, T., Lowke, J.J.: Modelling of thermal plasmas for arc welding: the role of the shielding gas properties and of metal vapour, J. Phys. D Appl. Phys. 42(19), 194006 (2009)

36.

Jenney, C.L., O’Brien, A.: AWS welding handbook’, 9th Ed. 1, 110–154 (2001)

37.

Radaj, D.: Heat Effects of Welding’, 1st Ed. Springer, Berlin (1992)

38.

Rhee, S., Asibu, E.K.: Analysis of arc pressure effect on metal transfer in gas metal arc welding. J. Appl. Phys. 70(9), 5068–5075 (1991)CrossRef

39.

Kulkarni, S.G.: Effect of narrow gap welding on characteristics of weld joint of austenitic stainless steel. Ph.D. Thesis, Indian Institute of Technology Roorkee, India (2009)

40.

Heat Flow in Welding, Suranaree University of Technology, Sep-Dec (2007)

41.

Praveen, P., Kang, M.J., Yarlagadda, P.K.D.V.: Arc voltage behavior in GMAW-P under different drop transfer modes. J. Achievements Mater. Manuf. Eng. 32(2), 196–202 (2009)

42.

Subramanium, S., White, D.R., Lyons, D.W.: Experimental approach to selection of pulsing parameters in pulsed GMAW, AWS. Weld. J. 78, 166s–172s (1999)

43.

Praveen, P., Yarlagadda, P.K.D.V., Kang, M.J.: Advancements in pulse gas metal arc welding. J. Mater. Process. Technol. 164–165, 1113–1119 (2005)CrossRef

44.

Lienhard, J.H. IV, Lienhard, J.H. V: A Heat Transfer Text Book, 3rd Ed. Phlogiston Press, Cambridge, Massachusetts, USA (2008)

45.

Redding, C.J.: Fume model for gas metal arc welding. Weld. J. 81(6), 95s–103s (2002)

46.

Gery, D., Long, H., Maropoulos, P.: Effects of welding speed, energy input and heat source distribution on temperature variations in butt joint welding. J. Mater. Process. Technol. 167, 393–401 (2005)CrossRef

47.

Joseph, A., Harwig, D., Farson, D., Richardson, R.: Measurement and calculation of arc power and heat transfer efficiency in pulsed gas metal arc welding. Sci. Technol. Weld. J. 8(6), 400–406 (2003)CrossRef

48.

Hu, J., Tsai, H.L.: Heat and mass transfer in gas metal arc welding. Part II. The metal. Int. J. Heat Mass Transf. 50(5/6), 808–820 (2007)CrossRef

49.

Goyal, V.K., Ghosh, P.K., Saini, J.S.: Influence of pulse parameters on characteristics of bead-on-plate weld deposits of aluminium and its alloy in the pulsed gas metal arc welding process. Met. Mater. Trans. A 39A(12), 3260–3275 (2008)CrossRef

50.

Eager, T.W.: The physics of arc welding process, Advanced Joining Technologies, T. H. North Ed., London, pp. 61–68 (1990)

51.

Bellan, P.M.: Fundamentals of Plasma Physics. Cambridge, pp. 1–22 (2004)

52.

Nasir Ahmed: New Developments in Advanced Welding, Woodhead Publishing Ltd, Abington, pp. 9–13 (2005)

53.

Choi, S.K., Ko, S.H., Yoo, C.D., Kim, Y.S.: Dynamic simulation of metal transfer, Part II: Short circuit transfer modes. Weld. J. 77(1), 45s–51s (1998)

54.

Jacobsen, N.: Monopulse investigation of drop detachment in pulsed gas metal arc welding, Phys. D. Appl. Phys. 25, 783–797 (1992)

55.

Era, T., Ueyama, T.: Spatter reduction in GMAW by current waveform control. Weld. Int. 20(7), 496–501 (2007)CrossRef

56.

Rouffet, M.E., Wendt, M., Goett, G., Kozakov, R., Schoepp, H., Weltmann, K.D., Uhrlandt, D.: Spectroscopic investigation of the high-current phase of a pulsed GMAW process. J. Phys. D Appl. Phys. 43(43), 434003 (2010)

57.

Quinn, T.P., Madigan, R.B., Siewert, T.A.: An electrode extension model for gas metal arc welding. Weld. J. 73(10), 241s–248s (1994)

58.

Belinga, E.M.M.: Applictions and benefits of adaptive pulsed GMAW, Lappeenranta University of Technology, Faculty of Technology, Mechanical Engineering, Master’s Thesis (2012)

59.

Cantin, G.M.D., Francis, J.A.: Arc power and efficiency in gas tungsten arc welding of aluminium. Sci. Technol. Weld. Join. 10(2), 200–210 (2005)CrossRef

60.

Wu, C.S., Chen, M.A., Lu, Y.F.: Effect of current waveforms on metal transfer in pulsed gas metal arc welding. Meas. Sci. Tech. 16(12), 2459–2465 (2005)CrossRef

61.

Ghosh, P.K., Devakumaran, K., Piyush, M.: Arc stability of pulse current gas metal arc welding of low alloy steel under different pulse parameters and shielding gas compositions. Indian Weld. J. 44(4), 29–42 (2011)

62.

Ghosh, P.K., Dorn, L., Devakumaran, K., Hofmann, F.: Influence of welding parameters and shielding gas on arc characteristics and behavior of metal transfer in GMA welding of mild steel. Indian Weld. J., 41(2), 23–33 (2008)

63.

Allum, C.J., Quintino, L.: Control of fusion characteristics in pulsed current MIG welding, Part-II, Simple model of fusion characteristics. Metal Constr. 17(5), 314R–317R (1985)

64.

Allum, C.J., Quintino, L.: Control of fusion characteristics in pulsed current GMAW—Part II Development of model for arc welding. Tech. Report, IIW Doc. 212-589-84 (1984)

65.

Dilthey, U., Killing, R.: Heat input for pulse GMAW. Weld. Des. Fab. 63(9), 51–53 (1990)

66.

Cornu, J.: Advanced Welding System, vol. 2, pp. 127–165. IFS Publication Ltd. UK (1988)

67.

Pal, K., Bhattacharya, S., Surjaya, K.P.: Prediction of metal deposition from arc sound and weld temperature signatures in pulsed MIG welding. Int. J. Adv. Manuf. Technol., 45(11/12), 1113–1130 (2009)

68.

Choi, S.K., Yoo, C.D., Kim, Y,S.: The dynamic analysis of metal transfer in pulsed current gas metal arc welding. J. Phys. D Appl. Phys. 31(2), 207–215 (1998)

69.

Waszink, J.H., Piena, M.J.: Experimental investigation of drop detachment and drop velocity in GMAW. Weld. J. 65(11), 289s–298s (1986)

70.

Pintard, J.: Some experimental data on short circuit transfer, in Physics of the Welding Arc. Institute of welding, London (1966)

71.

Alum, C.J.: Metal transfer in arc welding as a varicose instability: I. Varicose instabilities in a current carrying liquid cylinder with surface charge. J. Phys. D Appl. Phys. 18, 1431–1446 (1985)CrossRef

72.

Lancaster, J.F., Metallurgy of Welding, pp. 144–229. Allen and Unwin (Publishers) Ltd. (1987)

73.

Melton, G.B.: Proc. Euro join2, Florence, Italy, 16–18 May, Italian Institute of Welding, 249–258 (1994)

74.

Subramanium, S., White, D.R., Jones, J.E., Lyons, D.W.: Droplet transfer in pulsed gas metal arc welding of aluminium. Weld. J. 77(11), 458s–464s (1998)

75.

Kim, Y.S., Eagar, T.W.: Metal transfer in pulsed current gas metal arc welding. Weld. J. 72(7), 279s–287s (1993)

76.

Rajasekharan, S., Kulkarni, S.D., Mallya, U.D., Chaturvedi, R.C.: Molten droplet detachment characteristics in steady and pulsed current GMA welding AIMg alloys. In: Proceedings of the 6th International Conference on Aluminum Weldrnents, pp. 207–214. Cleveland, Ohio (1995)

77.

Kim, I.S., Basu, A.: A mathematical model of heat transfer and fluid flow in gas metal arc welding process. J. Mater. Process. Technol. 77, 17–24 (1998)CrossRef

Titel: Basic Nature of Pulse Current GMA Welding
verfasst von: Prakriti Kumar Ghosh
Verlag: Springer Singapore
Buch: Pulse Current Gas Metal Arc Welding
Print ISBN: 978-981-10-3556-2

Electronic ISBN: 978-981-10-3557-9

Copyright-Jahr: 2017
DOI: https://doi.org/10.1007/978-981-10-3557-9_3

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