Applications and Benefits of Adaptive Pulsed GMAW
Mvola Belinga, Eric Martial; B. Mvola (2012)
Diplomityö
2012
Julkaisun pysyvä osoite on
https://urn.fi/URN:NBN:fe-fe2012120310124
https://urn.fi/URN:NBN:fe-fe2012120310124
Tiivistelmä
In ship and offshore terminal construction, welded cross sections are thick and the
number of welds very high. Consequently, there are two aspects of great
importance; cost and heat input. Reduction in the welding operation time
decreases the costs of the work force and avoids excessive heat, preventing
distortion and other weld defects. The need to increase productivity while using a
single wire in the GMAW process has led to the use of a high current and voltage
to improve the melting rate. Unfortunately, this also increases the heat input.
Innovative GMAW processes, mostly implemented for sheet plate sections, have
shown significant reduction in heat input (Q), low distortion and increase in
welding speed.
The aim of this study is to investigate adaptive pulsed GMAW processes and
assess relevant applications in the high power range, considering possible benefits
when welding thicker sections and high yield strength steel. The study
experimentally tests the usability of adaptive welding processes and evaluates
their effects on weld properties, penetration and shapes of the weld bead.The study first briefly reviews adaptive GMAW to evaluate different approaches
and their applications and to identify benefits in adaptive pulsed. Experiments are
then performed using Synergic Pulsed GMAW, WiseFusionTM and Synergic
GMAW processes to weld a T-joint in a horizontal position (PB). The air gap
between the parts ranges from 0 to 2.5 mm. The base materials are structural steel
grade S355MC and filler material G3Si1. The experiment investigates heat input,
mechanical properties and microstructure of the welded joint.
Analysis of the literature reveals that different approaches have been suggested
using advanced digital power sources with accurate waveform, current, voltage,
and feedback control. In addition, studies have clearly indicated the efficiency of
lower energy welding processes. Interest in the high power range is growing and a
number of different approaches have been suggested. The welding experiments in
this study reveal a significant reduction of heat input and a weld microstructure
with the presence of acicular ferrite (AF) beneficial for resistance to crack
propagation. The WiseFusion bead had higher dilution, due to the weld bead
shape, and low defects.
Adaptive pulse GMAW processes can be a favoured choice when welding
structures with many welded joints. The total heat reduction mitigates residual
stresses and the bead shape allows a higher amperage limit. The stability of the arc
during the process is virtually spatter free and allows an increase in welding
speed.
number of welds very high. Consequently, there are two aspects of great
importance; cost and heat input. Reduction in the welding operation time
decreases the costs of the work force and avoids excessive heat, preventing
distortion and other weld defects. The need to increase productivity while using a
single wire in the GMAW process has led to the use of a high current and voltage
to improve the melting rate. Unfortunately, this also increases the heat input.
Innovative GMAW processes, mostly implemented for sheet plate sections, have
shown significant reduction in heat input (Q), low distortion and increase in
welding speed.
The aim of this study is to investigate adaptive pulsed GMAW processes and
assess relevant applications in the high power range, considering possible benefits
when welding thicker sections and high yield strength steel. The study
experimentally tests the usability of adaptive welding processes and evaluates
their effects on weld properties, penetration and shapes of the weld bead.The study first briefly reviews adaptive GMAW to evaluate different approaches
and their applications and to identify benefits in adaptive pulsed. Experiments are
then performed using Synergic Pulsed GMAW, WiseFusionTM and Synergic
GMAW processes to weld a T-joint in a horizontal position (PB). The air gap
between the parts ranges from 0 to 2.5 mm. The base materials are structural steel
grade S355MC and filler material G3Si1. The experiment investigates heat input,
mechanical properties and microstructure of the welded joint.
Analysis of the literature reveals that different approaches have been suggested
using advanced digital power sources with accurate waveform, current, voltage,
and feedback control. In addition, studies have clearly indicated the efficiency of
lower energy welding processes. Interest in the high power range is growing and a
number of different approaches have been suggested. The welding experiments in
this study reveal a significant reduction of heat input and a weld microstructure
with the presence of acicular ferrite (AF) beneficial for resistance to crack
propagation. The WiseFusion bead had higher dilution, due to the weld bead
shape, and low defects.
Adaptive pulse GMAW processes can be a favoured choice when welding
structures with many welded joints. The total heat reduction mitigates residual
stresses and the bead shape allows a higher amperage limit. The stability of the arc
during the process is virtually spatter free and allows an increase in welding
speed.