Thermal and metal transfer behaviours in pulsed current gas metal arc weld deposition of Al–Mg alloy

Abstract: The control of pulsed current gas metal arc (GMA) welding is highly critical owing to the simultaneous influence of the pulse parameters on thermal and metal transfer behaviours of the process. An analytical model has been developed to provide a theoretical understanding of the influence of pulse parameters on the behaviour of metal transfer and thermal characteristics in pulsed current GMA welding using Al-Mg filler wire. The variations in thermal and metal transfer behaviours with changes in pulse parameters… Show more

“…Thus, it may facilitate a thorough study concerning the influence of thermal behaviour on the characteristics of weld joint with respect to varying heat input and f in the cases of GMAW and P-GMAW respectively. Besides heat input the variation in f more precisely controls the thermal behaviour of weld joint through regulation of heat built up in weld pool due to its significant influence on energy distribution in the welding process dictated by the interactive pulse parameters [8][9][10]13) …”

“…[5][6][7][8][9][10] However, the involvement of large number of simultaneously interactive pulse current parameters in P-GMAW, that includes pulsed current (I p ), base current (I b ), pulse time (t p ), pulse off time (t b ) and pulse frequency (f), introduces certain degree of complexity in controlling the process for desired welding. [5][6][7][8][9][10] It is reported with ample justification that the complexity of the process primarily arising due to criticality in selection of pulse parameters can be largely solved with the help of correlation of the weld characteristics with a summarized influence of pulse parameters defined by a dimensionless hypothetical factor fϭ[(I b /I p )ft b ] derived from the energy balance concept of the process, where t b is expressed as [(1/f)Ϫt p ]. [8][9][10] In spite of its great potentialities hardly any systematic work has been reported so far on the joining of stainless steel sheet by controlled use of P-GMAW process in consideration of a summarized influence of pulse parameters.…”

“…[5][6][7][8][9][10] It is reported with ample justification that the complexity of the process primarily arising due to criticality in selection of pulse parameters can be largely solved with the help of correlation of the weld characteristics with a summarized influence of pulse parameters defined by a dimensionless hypothetical factor fϭ[(I b /I p )ft b ] derived from the energy balance concept of the process, where t b is expressed as [(1/f)Ϫt p ]. [8][9][10] In spite of its great potentialities hardly any systematic work has been reported so far on the joining of stainless steel sheet by controlled use of P-GMAW process in consideration of a summarized influence of pulse parameters.…”

“…11,12) The pulsed current welding, as it is schematically shown in Fig. 2, was performed at a low heat input with a variation in f from 0.12 to 0.41 to further favourably manipulate thermal behaviour [8][9][10] of the weld producing a sound joint. The low heat input of the P-GMAW process was decided in reference to the successfully tried lowest heat input of the conventional GMAW to produce flawless sound weld joint.…”

Pulsed Current GMAW for Superior Weld Quality of Austenitic Stainless Steel Sheet

“…Thus, it may facilitate a thorough study concerning the influence of thermal behaviour on the characteristics of weld joint with respect to varying heat input and f in the cases of GMAW and P-GMAW respectively. Besides heat input the variation in f more precisely controls the thermal behaviour of weld joint through regulation of heat built up in weld pool due to its significant influence on energy distribution in the welding process dictated by the interactive pulse parameters [8][9][10]13) …”

“…[5][6][7][8][9][10] However, the involvement of large number of simultaneously interactive pulse current parameters in P-GMAW, that includes pulsed current (I p ), base current (I b ), pulse time (t p ), pulse off time (t b ) and pulse frequency (f), introduces certain degree of complexity in controlling the process for desired welding. [5][6][7][8][9][10] It is reported with ample justification that the complexity of the process primarily arising due to criticality in selection of pulse parameters can be largely solved with the help of correlation of the weld characteristics with a summarized influence of pulse parameters defined by a dimensionless hypothetical factor fϭ[(I b /I p )ft b ] derived from the energy balance concept of the process, where t b is expressed as [(1/f)Ϫt p ]. [8][9][10] In spite of its great potentialities hardly any systematic work has been reported so far on the joining of stainless steel sheet by controlled use of P-GMAW process in consideration of a summarized influence of pulse parameters.…”

“…[5][6][7][8][9][10] It is reported with ample justification that the complexity of the process primarily arising due to criticality in selection of pulse parameters can be largely solved with the help of correlation of the weld characteristics with a summarized influence of pulse parameters defined by a dimensionless hypothetical factor fϭ[(I b /I p )ft b ] derived from the energy balance concept of the process, where t b is expressed as [(1/f)Ϫt p ]. [8][9][10] In spite of its great potentialities hardly any systematic work has been reported so far on the joining of stainless steel sheet by controlled use of P-GMAW process in consideration of a summarized influence of pulse parameters.…”

“…11,12) The pulsed current welding, as it is schematically shown in Fig. 2, was performed at a low heat input with a variation in f from 0.12 to 0.41 to further favourably manipulate thermal behaviour [8][9][10] of the weld producing a sound joint. The low heat input of the P-GMAW process was decided in reference to the successfully tried lowest heat input of the conventional GMAW to produce flawless sound weld joint.…”

Pulsed Current GMAW for Superior Weld Quality of Austenitic Stainless Steel Sheet

“…Mas o controle das características do arco e do comportamento da transferência de metal pela seleção apropriada dos parâmetros do pulso é bastante difícil devido à infl uência simultânea de um número relativamente grande de parâmetros durante a soldagem [8]. Isso envolve os parâmetros de pulso como corrente média (I m ), corrente de pico (I p ), corrente de base (I b ), tempo de pico (t p ), tempo de base (t b ), frequência de pulso (f), assim como a tensão do arco (V).…”

Análise da oscilação da poça de solda em P-GMAW por meio de processamento de imagens obtidas por perfilografia

Concept of Pulse Current Gas Metal Arc Welding Process