Focusing on the problem of high-power laser welding of high reflectivity of copper, in this article, a physical model of energy absorption for the temperature field of hybrid laser deep penetration welding of copper materials is established by using a Gaussian rotating body heat source of 450 nm blue diode laser and 1060 nm fiber laser. The main factors are analyzed such as welding joint design, laser energy density, focal position, and shielding gas. When the 1000 W fiber laser is combined with a 300, 500, and 700 W blue diode laser to weld copper material, the relationship between the welding temperature field and the light source absorption rate is analyzed on the condition of a hybrid heat source distance of 2.2–6.2 mm and a welding speed of 10–30 mm/s. The results show that the absorption rate of a fiber laser welded by double-beam hybrid welding can be increased by 20% compared with that of a single light source; that is, 300, 500, and 700 W blue diode laser together with 1000 W fiber laser combines to weld copper materials, and the absorption rate of the light source reaches the highest when the hybrid heat source distance and the welding speed are 3.0 mm and 20 mm/s, respectively.

1.
M.
Forrest
and
F.
Lu
, “Advanced dual beam laser welding of zinc-coated steel sheets in lap joint configuration with zero gap at the interface,” in International Congress on Applications of Lasers & Electro-Optics, San Francisco, CA, 4–7 October 2004 LACATION San Francisco, California, USA.Conference date: October 4–7, 2004. (Laser Institute of America, 2004), Vol. 2004, p. P508.
2.
M.
Gualini
,
S.
Iqbal
, and
F.
Grassi
, “
Modified dual-beam method for welding galvanized steel sheets in lap configuration
,”
J. Laser Appl.
18
,
185
191
(
2006
).
3.
S.
Iqbal
,
M.
Gualini
, and
F.
Grassi
, “
Laser welding of zinc-coated steel with tandem beams: Analysis and comparison
,”
J. Mater. Process. Technol.
184
,
12
18
(
2007
).
4.
S.
Iqbal
,
M. M.
Gualini
, and
A.
ur Rehman
, “
Dual beam method for laser welding of galvanized steel: Experimentation and prospects
,”
Opt. Laser Technol.
42
,
93
98
(
2010
).
5.
S.
Engler
,
R.
Ramsayer
, and
R.
Poprawe
, “
Process studies on laser welding of copper with brilliant green and infrared lasers
,”
Phys. Procedia
12
,
339
346
(
2011
).
6.
S.
Liebl
,
R.
Wiedenmann
,
A.
Ganser
,
P.
Schmitz
, and
M.
Zaeh
, “
Laser welding of copper using multi mode fiber lasers at near infrared wavelength
,”
Phys. Procedia
56
,
591
600
(
2014
).
7.
M.
Haubold
,
A.
Ganser
,
T.
Eder
, and
M. F.
Zäh
, “
Laser welding of copper using a high power disc laser at green wavelength
,”
Procedia CIRP
74
,
446
449
(
2018
).
8.
G.
Ma
, “Study on welding characteristics and molten pool behavior of bifocal fiber laser,” Ph.D. thesis, Harbin Institute of Technology, 2017.
9.
A.
Hess
,
R.
Schuster
,
A.
Heider
,
R.
Weber
, and
T.
Graf
, “
Continuous wave laser welding of copper with combined beams at wavelengths of 1030 nm and of 515 nm
,”
Phys. Procedia
12
,
88
94
(
2011
).
10.
Y.
Cheng
, “Study on anti-bremsstrahlung absorption of plasma in laser deep penetration welding of aluminum alloy hole,” Master’s thesis, Hunan University, 2012.
11.
B.
Finke
,
P.
Kapadia
, and
J.
Dowden
, “
A fundamental plasma based model for energy transfer in laser material processing
,”
J. Phys. D: Appl. Phys.
23
,
643
(
1990
).
12.
J.
Chen
, “Study on laser absorption rate of materials during laser heat treatment,” Master’s thesis, Zhejiang University of Technology, 2008.
You do not currently have access to this content.