Identyfikatory
Warianty tytułu
Wpływ częstotliwości pulsującego prądu spawania metodą TIG na efekty oddziaływania ciepła w stali 301L
Języki publikacji
Abstrakty
The paper presents the influence of pulsation frequency on the results of pulsed current TIG welding based on two criteria: geometric parameters of weld and changes in microstructure. The investigations were carried out for 301L austenitic stainless steel with constant current parameters, constant welding speed, 50% duty cycle ratio and constant heat input. The results were referred to the commonly used methods for measuring the amount of heat input.
W pracy przedstawiono wpływ częstotliwości pulsacji prądu na wyniki nadtapiania metalu rodzimego przy metodzie spawania TIG prądem pulsującym w oparciu o dwa kryteria: ocenę parametrów geometrycznych nadtopień oraz ocenę zmian mikrostruktury. Badania przeprowadzono dla stali austenitycznej 301L przy stałych parametrach prądowych, stałej prędkości spawania, współczynniku wypełnienia impulsu 50% i stałej energii liniowej. Wyniki odniesiono do powszechnie stosowanych metod pomiaru ilości wprowadzonego ciepła do materiału na jednostkę długości spoiny.
Czasopismo
Rocznik
Tom
Strony
61--71
Opis fizyczny
Bibliogr. 26 poz., il., tab.
Twórcy
autor
- Railway Research Institute, Poland
autor
- Warsaw University of Technology, Poland
Bibliografia
- [1] Dzelnitzki D., Muendersbach, TIG Welding with High Frequency Pulses, an Interesting Process Variant. EWM Hightech Welding GmbH, 2000.
- [2] Yang M., Yang Z., Cong, B. And Qi B., A Study on The Surface Depression Of The Molten Pool With Pulsed Welding. Welding Journal, 2014, Vol. 93, August 312-319.
- [3] Qi B., Yang M., Cong B., Li W., Study on Fastconvert Ultrasonic Frequency Pulse TIG welding Arc Characteristics. Materials Science Forum 2012, Vols. 704-705, 745-751.
- [4] Qi B.J., Yang M.X., Cong B.Q., Liu F. J. The effect of arc behavior on weld geometry by high-frequency pulse GTAW process with 0Cr18Ni9Ti stainless steel. The International Journal of Advanced Manufacturing Technology 2013, Vol. 66(9-12), 1545–1553.
- [5] Arivarasu M., Devendranath Ramkumar K., Arivazhagan N., Comparative Studies of High and Low Frequency Pulsing on the Aspect Ratio of Weld Bead in Gas Tungsten Arc Welded AISI 304L Plates. Procedia Engineering, 2014, Vol. 97, 871-880.
- [6] Traidia A., Multiphysics modeling and numerical simulation of GTA weld pools (Ph. Thesis - 2011) HAL Archives Ouvertes.fr.
- [7] Ostromęcka M., Cegielski P., Kolasa A., Influence of pulse current frequency in the TIG method on selected aspects of heat supply during welding of 321 steel. Welding Technology Review, 2018, Vol. 90(3), 13-16.
- [8] Ugla A.A., A Comparative Study of Pulsed and Non-Pulsed Current on Aspect Ratio of Weld Bead and Microstructure Characteristics of AISI 304L Stainless Steel. Innovative Systems Design and Engineering, 2016, Vol. 7(4).
- [9] Ugla A.A., Characterisation of Metallurgical and Mechanical Properties of the Welded AISI 304L Using Pulsed and Non-Pulsed Current TIG Welding International Journal of Chemical, Molecular, Nuclear. Materials and Metallurgical Engineering, 2016, Vol. 10(4).
- [10] Wojsyk K., Macherzyński M., Determination of Welding Linear Energy by Measuring Cross-Sectional Areas of Welds. Biuletyn Instytutu Spawalnictwa, 2016, Vol. 60(5), 83-89.
- [11] Wojsyk K., Macherzyński M., Lis R., Evaluation of the amount of heat introduced into the welds and padding welds by means of their transverse fields measurement in conventional and hybrid welding processes. Welding Technology Review, 2017, Vol. 89(10), 67-82.
- [12] Cegielski P., Bugyi Ł., Selected aspects of welding defects identification in MIG/MAG arc welding. Welding Technology Review, 2017, Vol. 89(6), 30-35.
- [13] Klimpel A., Technology of welding and cutting. Publishing House of Silesian University of Technology, Gliwice 1997.
- [14] Arivarasu M., Kasinath D.R., Natarajan A., Effect of Continuous and Pulsed Current on the Metallurgical and Mechanical Properties of Gas Tungsten Arc Welded AISI 4340 Aeronautical and AISI 304L Austenitic Stainless Steel Dissimilar Joints. Materials Research, 2015, 18(I), 59-77.
- [15] Tasak E., Metallurgy of Welding, Cracow 2008.
- [16] Almoussawi M., Smith A., Faraji M., Carter S., Segregation of Mn, Si, Al and oxygen during friction stir welding of DH36 Steel. Metallography, Microstructure, and Analysis, 2017, Vol. 6(6), 569-576.
- [17] Lind M., Mechanism and Kinetics of Transformation of Alumina Inclusions In Steel By Calcium Treatment, Doctoral thesis, Helsinki University of technology, 2006.
- [18] Eagar T.W., The Physics of Arc Welding Processes. Advanced Joining Technologies, 1990.
- [19] Lancaster J.F., The Physics of Welding, Pergamon Press, 1984.
- [20] Lin M.L., Eagar T.W., Pressures Produced by Gas Tungsten Arcs, Metallurgical Transactions B, 1986, Vol. 17B(3).
- [21] Sorensen C.D., Eagar T.W., Measurement of oscillations in partially penetrated weld pools through spectral analysis’. J. Dyn. Syst. Meas. Contr., 1990, Vol. 112(3), 463-468.
- [22] Sorensen C.D., Eagar T.W., Modeling of oscillations in partially penetrated weld pools’. J. Dyn. Syst. Meas. Contr. 1990, Vol. 112(3), 469–474.
- [23] Xiao Y.H., Den Ouden G., A study of GTA weld pool oscillation. Welding Research Supplement, 1990, 69, 289-293.
- [24] Xiao Y.H., Den Ouden G., Weld pool oscillation during GTA welding of mild steel. Welding Research Supplement, 1993, 72, 428-434.
- [25] Ostromęcka M., Influence of the frequency of pulsating TIG welding current on the effects of heat in selected special steels. Doctoral thesis, Warsaw University of Technology, 2019.
- [26] Karpierz M., Basics of photonics. CSZ Warsaw University of Technology, Warsaw 2010.
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-9f01f1db-0de5-418e-98f2-487afead1bd5