Effective power of a constricted welding arc with heteropolar current pulses


Cite item

Full Text

Abstract

The authors reviewed the research works on the effective power of direct and reverse polarity welding arcs with a non-consumable electrode in argon. The study shows that it is difficult to use the arc effective efficiency for effective power determination. It applies to the constricted arc more than to the free one. Based on data analysis for the effective power of polarities and the effective efficiency of a constricted arc burning toward the cooper heat flow calorimeter, the authors calculated the specific effective power of polarities and arc stresses. The maximum values are 23.2 W/A for the reverse polarity arc; and 14.2 W/A for the direct polarity arc. The study identified that the decrease in the specific effective power of polarities at the current increase within 100–150 A is well described by linear dependencies. With the current increase, there is a linear decrease in the direct polarity arc stress, while the reverse polarity arc stress remains constant. The spread of data for the specific effective power of polarities is about two times less than the spread for effective efficiency. Using a 2D mathematical model of the constricted arc column in a closed area, the authors calculated the power absorbed by plasma-forming argon and nozzle walls. As a result, the authors obtained the dependencies of the power transferred by argon on the nozzle channel length and the arc current. The specific effective power of argon flow for analyzed current densities and argon consumption shows poor dependence on the arc current and is equal to 5.5 W/A approximately. The power contribution of plasma-forming argon to the effective power of the constricted arc increases with the current increase.

About the authors

Vladimir P. Sidorov

Togliatti State University, Togliatti (Russia)

Author for correspondence.
Email: vladimir.sidorov.2012@list.ru
ORCID iD: 0000-0001-6191-2888

Doctor of Sciences (Engineering), Professor, professor of Chair “Welding, Pressure Treatment of Materials and Allied Processes”

Russian Federation

Dmitry E. Sovetkin

Togliatti State University, Togliatti (Russia)

Email: fake@neicon.ru
ORCID iD: 0000-0002-6942-4501

senior lecturer of Chair “Welding, Pressure Treatment of Materials and Allied Processes”

Russian Federation

References

  1. Grinyuk A.A., Korzhik V.E., Shevchenko E.N., Babich A.A., Peleshenko S.I., Chayka V.G., Tishchenko A.F., Kovbasenko G.V. Main tendencies in development of plasma-arc welding of aluminum alloys. Automatic Welding, 2015, no. 11, pp. 39–50. doi: 10.15407/tpwj2015.11.04.
  2. Wang L.L., Wei J.H., Xue J.X., DebRoy T. A pathway to microstructural refinement through double pulsed gas metal arc welding. Scripta Materialia, 2017, vol. 134, pp. 61–65. DOI: 1016/j.scriptamat.2017.02.034.
  3. Wang Y., Qi B., Cong B., Zhu M., Lin S. Keyhole welding of AA2219 aluminum alloy with double-pulsed variable polarity gas tungsten arc welding. Journal of Manufacturing Processes, 2018, vol. 34, pp. 179–186. doi: 10.1016/j.jmapro.2018.06.006.
  4. Savinov A.V., Lapin I.E., Lysak V.I. Dugovaya svarka neplavyashchimsya elektrodom [Arc welding with a non-consumable electrode]. Moscow, Mashinostroenie Publ., 2011. 477 p.
  5. Wang Y., Qi B., Cong B., Yang M., Liu F. Arc characteristics in double-pulsed VP-GTAW for aluminum alloy. Journal of Materials Processing Technology, 2017, vol. 249, pp. 89–95. doi: 10.1016/j.jmatprotec.2017.05.027.
  6. Haelsig A., Kusch M., Mayer P. New findings on the efficiency of gas shielded arc welding. Welding in the World, 2012, vol. 56, no. 11-12, pp. 98–104. doi: 10.1007/BF03321400.
  7. Yarmuch M.A.R., Patchett B.M. Variable AC polarity GTAW fusion behavior in 5083 aluminum. Welding Journal, 2007, vol. 86, no. 7, pp. 196–200.
  8. Nasiri M.B., Behzadinejad M., Latifi H., Martikeinen J. Investigation on the influence of various welding parameters on the arc thermal efficiency of the GTAW process by calorimetric method. Journal of Mechanical Science and Technology, 2014, vol. 28, no. 8, pp. 3255–3261. doi: 10.1007/s12206-014-0736-8.
  9. Korotkova G.M. Istochniki pitaniya peremennogo toka dlya svarki neplavyashchimsya electrodom alyuminievykh splavov [AC power supplies for TIG welding of aluminum alloys]. Togliatti, TGU Publ., 2009. 335 p.
  10. Jeong H., Park K., Cho J. Numerical analysis of variable polarity arc weld pool. Journal of Mechanical Science and Technology, 2016, vol. 30, no. 9, pp. 4307–4313. doi: 10.1007/s12206-016-0845-7.
  11. Jeong H., Park K., Baek S., Cho J. Thermal efficiency decision of variable polarity aluminum arc welding through molten pool analysis. International Journal of Heat and Mass Transfer, 2019, vol. 138, pp. 729–737.
  12. Draper N., Smit H. Prikladnoy regressionny analiz [Applied Regression Analysis]. Moscow, Dialektika Publ., 2016. 912 p.
  13. Wang L.L., Wei J.H., Wang Z.M. Numerical and experimental investigations of variable polarity gas tungsten arc welding. International Journal of Advanced Manufacturing Technology, 2018, vol. 95, no. 5-8, pp. 2421–2428. doi: 10.1007/s00170-017-1387-6.
  14. Sidorov V.P., Sovetkin D.E., Borisov N.A. Concerning the melting of an aluminium electrode by the argon arc of straigt polarity. Science Vector of Togliatti State University, 2019, no. 4, pp. 52–57. doi: 10.18323/2073-5073-2019-4-52-57.
  15. Sidorov V.P., Kovtunov A.I., Bochkarev A.G., Sovetkin D.E. Effective power of the reverse polarity welding arc when surfacing aluminum with a consumable electrode. Science Vector of Togliatti State University, 2020, no. 4, pp. 34–42. doi: 10.18323/2073-5073-2020-4-34-42.
  16. Sidorov V.P., Sovetkin D.E. Effective power of bipolar argon arc with a tungsten electrode for aluminum welding. Bulletin of Perm National Research Polytechnic University. Mechanical engineering, Materials Science, 2021, vol. 23, no. 1, pp. 5–12. doi: 10.15593/2224-9877/2021.1.01.
  17. Jiang F., Li Ch., Chen Sh. Experimental investigation on heat transfer of different phase in variable polarity plasma arc welding. Welding in the World, 2019, vol. 63, no. 4, pp. 1153–1162. doi: 10.1007/s40194-019-00722-3.
  18. Sidorov V.P., Stolbov V.I., Kurkin I.P. Determination of the effective power of the heating source when welding with a plasma three-phase arc. Svarochnoe proizvodstvo, 1988, no. 5, pp. 30–32.
  19. Fizika i tekhnika nizkotemperaturnoy plazmy [Low-temperature plasma physics and technology]. Moscow, Atomizdat Publ., 1972. 352 p.
  20. Rykalin N.N., Nikolaev A.V., Asonov A.N. Electrical and energy characteristics of a plasma arc with current modulation. Automatic welding, 1975, no. 11, pp. 1–5.
  21. Evans D.M., Huang D., McClure J.C., Nunes A.C. Arc efficiency of Plasma Arc Welding. Welding Journal, 1998, vol. 77, no. 2, pp. 53–58.

Supplementary files

Supplementary Files
Action
1. JATS XML
Download

Copyright (c)



This website uses cookies

You consent to our cookies if you continue to use our website.

About Cookies