Abstract
This paper investigates the principle and ways for heat and temperature distribution in thermal processes. It provides a review of achieved theoretical explanations and contributions while indicating on mismatches, previews, and even mistakes. Mistakes made in equations in this area that are noticed in investigations in the previous years have been corrected. Special focus is aimed at surface and volume heat treatment in electrothermia for which the necessary analytical dependencies should be developed and proved.
Similar content being viewed by others
References
Korn GA, Korn TM (1968) Mathematical handbook for scientists and engineers. McGraw Hill Book Company, New York
Mitrinović DS, Kečkić JD (1972) Equations for Mathematical Physics. Edition Gradjevinska knjiga, Belgrade (in Serbian)
Slukhotskii AE, Ryskin SE (1974) Inductors for induction heating. Edition Energoatomizdat, Leningrad (in Russian)
Ivković Z (1972) Introduction to the theory of probability, stochastical processes and mathematical statistics. Edition Gradjevinska knjiga, Belgrade (in Serbian)
Nemkov VS, Demidovitch VB (1988) Theory and calculation of induction heating systems. Edition Energoatomizdat, Leningrad 1988 (in Russian)
Shamov AN, Lunin IV, Ivanov VN (1977) High frequency welding of metals. Edition Mashinostroenie, Leningrad (in Russian)
Ivanov VN, Lunin IV, Kulzhinski VL (1979) High frequency welding of metals. Mashinostroenie, Leningrad (in Russian)
Gluhanov NP, Bogdanov VN (1962) Metal welding with high fequency heating. Edition Mashgiz, Leningrad (in Russian)
Peysachovitch VA (1988) High frequency welding treatment of metals. Edition Energoatomizdat, Leningrad (in Russian)
Gaultois MW Jr (2015) Design principles for oxide thermoelectric materials. Ph.D. thesis, University of California, Santa Barbara, USA
Milićević M, Jovanović T, Nejković V (2013) Defects identification of high frequency inductive welding, Mining & Metall Eng Bor 2:195–218. https://doi.org/10.5937/mmeb1302195m
Wright J (1997) Principles of high frequency induction tube welding. Electronic Heating Equipement Inc., Sumner
Li X, Ma N, Xu X, Murakawa H (2013) Theoretical prediction of thermal cycles and hardness of HAZ due to twin wire submerged arc welding. Q J Jpn Weld Soc 31(4):109s–115s. https://doi.org/10.2207/qjjws.31.109s
Milićević M et al (2015) Computers regulation HF inductive welding. Zavarivanje i zavarenekonstrukcije 3(2015):109–124 (in Serbian)
Lindstrom P (2015) Improved CWM platform for modelling welding procedures and their effects on structural behaviour. Ph.D. thesis, University West, Trollhattan, Sweden. ISBN 978–91–87531-08-8
Merchant SY (2015) Investigation on effect of welding current on welding speed and hardness of HAZ and weld metal of mild steel. Int J Res Eng, Technol (IJRET) 04(03):44–48
Rudnev IV (1997) Induction Heat Treatment, Steel Heat Treatment Handbook, New York, Basel, Hong Kong
Ruffini RS, Ruffini RT, Nemkov VS (1998) Advanced design of induction heat treating processes and work coils. Heat Treat Met 26(4):84–89
Likov LA (1967) Heat conduction theory. Edition Visshaya shkola, Moscow (in Russian)
Milićević M, Milićević V (2002) Impeder for HF inductive welding of steel tubes. IEE Proc Sci Meas Technol 149(3):113–116
Milićević M, Radaković Z (2006) Quality improvement of steel pipes by seam welding with new magneto-dielectric impeder, materials transactions. Jpn Inst Metals 47(06):1464–1468
Milićević M (2010) The application of a new formula of Nakaoka coefficient in HF inductive welding. J Mech Eng 56(7–8):483–488
Author information
Authors and Affiliations
Corresponding author
Additional information
Recommended for publication by Study Group 212 - The Physics of Welding
Rights and permissions
About this article
Cite this article
Nejković, V.M., Milićević, M.S. & Radaković, Z. Temperature distribution in thermal processes. Weld World 63, 583–589 (2019). https://doi.org/10.1007/s40194-018-0672-9
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s40194-018-0672-9