Thick Section Laser Beam Welding of Structural Steels: Methods for Improving Welding Efficiency
Sokolov, Mikhail (2015-08-28)
Väitöskirja
Sokolov, Mikhail
28.08.2015
Lappeenranta University of Technology
Acta Universitatis Lappeenrantaensis
Julkaisun pysyvä osoite on
https://urn.fi/URN:ISBN:978-952-265-839-5
https://urn.fi/URN:ISBN:978-952-265-839-5
Tiivistelmä
Laser beam welding (LBW) is applicable for a wide range of industrial sectors and has
a history of fifty years. However, it is considered an unusual method with
applications typically limited to welding of thin sheet metal. With a new generation of
high power lasers there has been a renewed interest in thick section LBW (also known
as keyhole laser welding). There was a growing body of publications during 2001-2011
that indicates an increasing interest in laser welding for many industrial applications,
and in last ten years, an increasing number of studies have examined the ways to
increase the efficiency of the process.
Expanding the thickness range and efficiency of LBW makes the process a possibility
for industrial applications dealing with thick metal welding: shipbuilding, offshore
structures, pipelines, power plants and other industries. The advantages provided by
LBW, such as high process speed, high productivity, and low heat input, may
revolutionize these industries and significantly reduce the process costs. The research
to date has focused on either increasing the efficiency via optimizing process
parameters, or on the process fundamentals, rather than on process and workpiece
modifications.
The argument of this thesis is that the efficiency of the laser beam process can be
increased in a straightforward way in the workshop conditions. Throughout this
dissertation, the term “efficiency” is used to refer to welding process efficiency,
specifically, an increase in efficiency refers an increase in weld’s penetration depth
without increasing laser power level or decreasing welding speed. These methods are:
modifications of the workpiece – edge surface roughness and air gap between the
joining plates; modification of the ambient conditions – local reduction of the pressure in the welding zone; modification of the welding process – preheating of the welding
zone. Approaches to improve the efficiency are analyzed and compared both
separately and combined. These experimentally proven methods confirm previous
findings and contribute additional evidence which expand the opportunities for laser
beam welding applications.
The focus of this research was primarily on the effects of edge surface roughness
preparation and pre-set air gap between the plates on weld quality and penetration
depth. To date, there has been no reliable evidence that such modifications of the
workpiece give a positive effect on the welding efficiency. Other methods were tested
in combination with the two methods mentioned above. The most promising -
combining with reduced pressure method - resulted in at least 100% increase in
efficiency.
The results of this thesis support the idea that joining those methods in one modified
process will provide the modern engineering with a sufficient tool for many novel
applications with potential benefits to a range of industries.
a history of fifty years. However, it is considered an unusual method with
applications typically limited to welding of thin sheet metal. With a new generation of
high power lasers there has been a renewed interest in thick section LBW (also known
as keyhole laser welding). There was a growing body of publications during 2001-2011
that indicates an increasing interest in laser welding for many industrial applications,
and in last ten years, an increasing number of studies have examined the ways to
increase the efficiency of the process.
Expanding the thickness range and efficiency of LBW makes the process a possibility
for industrial applications dealing with thick metal welding: shipbuilding, offshore
structures, pipelines, power plants and other industries. The advantages provided by
LBW, such as high process speed, high productivity, and low heat input, may
revolutionize these industries and significantly reduce the process costs. The research
to date has focused on either increasing the efficiency via optimizing process
parameters, or on the process fundamentals, rather than on process and workpiece
modifications.
The argument of this thesis is that the efficiency of the laser beam process can be
increased in a straightforward way in the workshop conditions. Throughout this
dissertation, the term “efficiency” is used to refer to welding process efficiency,
specifically, an increase in efficiency refers an increase in weld’s penetration depth
without increasing laser power level or decreasing welding speed. These methods are:
modifications of the workpiece – edge surface roughness and air gap between the
joining plates; modification of the ambient conditions – local reduction of the pressure in the welding zone; modification of the welding process – preheating of the welding
zone. Approaches to improve the efficiency are analyzed and compared both
separately and combined. These experimentally proven methods confirm previous
findings and contribute additional evidence which expand the opportunities for laser
beam welding applications.
The focus of this research was primarily on the effects of edge surface roughness
preparation and pre-set air gap between the plates on weld quality and penetration
depth. To date, there has been no reliable evidence that such modifications of the
workpiece give a positive effect on the welding efficiency. Other methods were tested
in combination with the two methods mentioned above. The most promising -
combining with reduced pressure method - resulted in at least 100% increase in
efficiency.
The results of this thesis support the idea that joining those methods in one modified
process will provide the modern engineering with a sufficient tool for many novel
applications with potential benefits to a range of industries.
Kokoelmat
- Väitöskirjat [1064]