Welding of 304L Stainless Steel with Activated Tungsten Inert Gas Process (A-TIG)
[1] S. Kou, Welding metallurgy: LibreDigital, 2003.
[2] A. H. Kokabi, P. Farhang, A. Adab Avazeh: welding
dictionary, 1th Eddition, Azadeh, (2004).
[3] C. Dong, S. Katayama:The 57th Annual Assembly
of the International Institute of Welding, Osaka,
(2004), 371.
[4] S. MARYA: Mech. Mater. Eng., 1(2006), 1.
[5] P. J. Modenesi, E. R. Apolinario, I. M. Pereira: J.
Mater. Sci. Technol, 99(2000), 260.
[6] M. M. Sawickij, G. M. Mielniczuk, A. F. Lupan, A.
M. Sawickij: Weld. Int., 15(2001), 677.
[7] D. S. Howes and W. Lucas: Weld. Met. Fabr, Vol.
68, pp. 11-17, 2000.
[8] Chern, T.S., Tseng, K.H., Tsai, H.L, “Study of
the characteristics of duplex stainless steel activated
tungsten inert gas welds”, Materials and Design, Vol.
32, pp. 255-263, 2011.
[9] T. Sándor, J. Dobránszky, “The experiences of
activated tungsten inert gas (ATIG) welding applied
on 1.4301 type stainless steel plates,”, Vol. 3, pp. 63-
70, 2007.
[10] Ch. Yang, S. Lin, F. Liu, Q. Zhang, “Reaserch
on the mechanism of penetration increase by flux in
A-TIG welding”, Material Science and Technology,
Vol. 19, pp. 225-227, 2003.
[11] Sh. Lu, H. Fuji, H. Sugiyama, K. Nogi,
“Mechanism and Optimization of Oxide Fluxes for
Deep Penetration in Gas Tungsten Arc Welding”,
Metallurgical and Materials Transactions A, Vol. 34,
pp. 1901-1907, 2003.
[12] J. J. Lowke, M. Tanaka, M. Ushio, “Mechanisms
giving increased weld depth due to a flux”, Physics D:
Applied physics, Vol. 38, pp. 3438-3445, 2005.
[13] M. M. Sawickij, G. M. Mielniczuk, A. F. Lupan, A.
M. Sawickij, O. I. Olejnik, “Activating fluxes in inert
gas-shield welding of steels”, Welding International,
Vol. 15, pp. 677-683, 2010.
[14] S. Leconte, P. Paillard, P. Chapelle, G. Henrion,
J. Saindrenan, “ Effects of flux containing fluorides
on TIG welding process”, Science and Technology of
Welding and Joining, Vol. 12, pp. 120-126, 2007.
[15] S. Lu, H. Fujii, K. Nogi, “Marangoni convection
and welding penetration in A-TIG welding”,
Theoretical and Applied Fracture Mechanics, Vol. 48,
pp. 178-186, 2007.
[16] L. Qing-ming, W. X. Hong, Z. Zeng, W. Jun,
“Effect of activating flux on arc shape and arc voltage
in tungsten inert gas welding,” Transactions of
Nonferrous Metals Society of China, vol. 17, pp. 486-
490, 2007.
[17] Y. Ogawa, “Effect of active flux on anode
reaction”, Document XII-1797-04, National Institute
of Advanced Industrial Science and Technology,
Japan.
[18] Y. Wang, Q. Shi, H. L. Tsai, “Modeling of the
Effects of Surface-Active Elements on Flow Patterns
and Weld Penetration”, Metallurgial and Materials
Transaction B, Vol. 32, pp. 145-161, 2001.
[19] A. Traidia, F.Roger, E. Guyot, “Optimal
parameters for pulsed gas tungsten arc welding in
partially and fully penetrated weld pools”, Thermal
Sciences, Vol. 49, pp. 1197-1208, 2010.
[20] R. Zhang and D. Fan, “Numerical simulation
of effects of activating flux on flow patterns and
weld penetration in ATIG welding,” Science and
Technology of Welding & Joining, vol. 12, pp. 15-23,
2007.
[21] K. Prasad Rao, A. Uma Maheshwar Rao, G.
J. Gururaja, “Effect of delta ferrite content on the
corrosion resistance of type 316 clad metals”,
Materials and Corrosion, Vol. 39, pp. 135-142, 1988.
[22] J. C. Lippold, D. J. Kotecki, “Welding metallurgy
and weldability of stainless steels”, Wiley Interscience;
1 edition, ISBN 9780471473794, 2005.
[23] V. Shankar, T. P. Gill, S. L. Mannan, “Solidification
cracking in austenitic stainless steel welds”, Sadhana,
Vol. 28, pp. 359-382, 2003.
[24] P. Sejč, R. Kubíček, “Influence of Heat Input
on the Content of Delta Ferrite in the Structure of
304L Stainless Steel GTA Welded Joints”, Scientific
Proceedings Faculty of Mechanical Engineering STU
in Bratislava, Vol. 19, pp. 8-14, 2012.
[25] R. J. Fowless, S. E. Blake, “Influence of Heat
Input on Austenitic Stainless Steel Weld properties”,
African fusion, Vol. 1, pp. 17-24, 2008.
[26] A. Rodrigues, A. Loureiro, A. C. Batista, “Phase
formation in austenitic stainless steel A-TIG welds”,
Materials Science Forum, Vol. 514/516, pp. 549-553,
2006.
[2] A. H. Kokabi, P. Farhang, A. Adab Avazeh: welding
dictionary, 1th Eddition, Azadeh, (2004).
[3] C. Dong, S. Katayama:The 57th Annual Assembly
of the International Institute of Welding, Osaka,
(2004), 371.
[4] S. MARYA: Mech. Mater. Eng., 1(2006), 1.
[5] P. J. Modenesi, E. R. Apolinario, I. M. Pereira: J.
Mater. Sci. Technol, 99(2000), 260.
[6] M. M. Sawickij, G. M. Mielniczuk, A. F. Lupan, A.
M. Sawickij: Weld. Int., 15(2001), 677.
[7] D. S. Howes and W. Lucas: Weld. Met. Fabr, Vol.
68, pp. 11-17, 2000.
[8] Chern, T.S., Tseng, K.H., Tsai, H.L, “Study of
the characteristics of duplex stainless steel activated
tungsten inert gas welds”, Materials and Design, Vol.
32, pp. 255-263, 2011.
[9] T. Sándor, J. Dobránszky, “The experiences of
activated tungsten inert gas (ATIG) welding applied
on 1.4301 type stainless steel plates,”, Vol. 3, pp. 63-
70, 2007.
[10] Ch. Yang, S. Lin, F. Liu, Q. Zhang, “Reaserch
on the mechanism of penetration increase by flux in
A-TIG welding”, Material Science and Technology,
Vol. 19, pp. 225-227, 2003.
[11] Sh. Lu, H. Fuji, H. Sugiyama, K. Nogi,
“Mechanism and Optimization of Oxide Fluxes for
Deep Penetration in Gas Tungsten Arc Welding”,
Metallurgical and Materials Transactions A, Vol. 34,
pp. 1901-1907, 2003.
[12] J. J. Lowke, M. Tanaka, M. Ushio, “Mechanisms
giving increased weld depth due to a flux”, Physics D:
Applied physics, Vol. 38, pp. 3438-3445, 2005.
[13] M. M. Sawickij, G. M. Mielniczuk, A. F. Lupan, A.
M. Sawickij, O. I. Olejnik, “Activating fluxes in inert
gas-shield welding of steels”, Welding International,
Vol. 15, pp. 677-683, 2010.
[14] S. Leconte, P. Paillard, P. Chapelle, G. Henrion,
J. Saindrenan, “ Effects of flux containing fluorides
on TIG welding process”, Science and Technology of
Welding and Joining, Vol. 12, pp. 120-126, 2007.
[15] S. Lu, H. Fujii, K. Nogi, “Marangoni convection
and welding penetration in A-TIG welding”,
Theoretical and Applied Fracture Mechanics, Vol. 48,
pp. 178-186, 2007.
[16] L. Qing-ming, W. X. Hong, Z. Zeng, W. Jun,
“Effect of activating flux on arc shape and arc voltage
in tungsten inert gas welding,” Transactions of
Nonferrous Metals Society of China, vol. 17, pp. 486-
490, 2007.
[17] Y. Ogawa, “Effect of active flux on anode
reaction”, Document XII-1797-04, National Institute
of Advanced Industrial Science and Technology,
Japan.
[18] Y. Wang, Q. Shi, H. L. Tsai, “Modeling of the
Effects of Surface-Active Elements on Flow Patterns
and Weld Penetration”, Metallurgial and Materials
Transaction B, Vol. 32, pp. 145-161, 2001.
[19] A. Traidia, F.Roger, E. Guyot, “Optimal
parameters for pulsed gas tungsten arc welding in
partially and fully penetrated weld pools”, Thermal
Sciences, Vol. 49, pp. 1197-1208, 2010.
[20] R. Zhang and D. Fan, “Numerical simulation
of effects of activating flux on flow patterns and
weld penetration in ATIG welding,” Science and
Technology of Welding & Joining, vol. 12, pp. 15-23,
2007.
[21] K. Prasad Rao, A. Uma Maheshwar Rao, G.
J. Gururaja, “Effect of delta ferrite content on the
corrosion resistance of type 316 clad metals”,
Materials and Corrosion, Vol. 39, pp. 135-142, 1988.
[22] J. C. Lippold, D. J. Kotecki, “Welding metallurgy
and weldability of stainless steels”, Wiley Interscience;
1 edition, ISBN 9780471473794, 2005.
[23] V. Shankar, T. P. Gill, S. L. Mannan, “Solidification
cracking in austenitic stainless steel welds”, Sadhana,
Vol. 28, pp. 359-382, 2003.
[24] P. Sejč, R. Kubíček, “Influence of Heat Input
on the Content of Delta Ferrite in the Structure of
304L Stainless Steel GTA Welded Joints”, Scientific
Proceedings Faculty of Mechanical Engineering STU
in Bratislava, Vol. 19, pp. 8-14, 2012.
[25] R. J. Fowless, S. E. Blake, “Influence of Heat
Input on Austenitic Stainless Steel Weld properties”,
African fusion, Vol. 1, pp. 17-24, 2008.
[26] A. Rodrigues, A. Loureiro, A. C. Batista, “Phase
formation in austenitic stainless steel A-TIG welds”,
Materials Science Forum, Vol. 514/516, pp. 549-553,
2006.
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