Stringent requirements on creep strength and corrosion/oxidation resistance mean that nickel-based superalloys will be the material of choice for high- temperature and high-pressure (HT/HP) applications in the future. Components for these HT/HP processes in turbines, housings or piping are often characterized by their large dimensions and wall thicknesses of ≥20 mm. Because of the high material costs and difficult machinability of Ni-based components in comparison to steel components, an efficient and reliable welding technology that produces crack free weld seams is a necessary precondition for economic manufacturing. Conventional arc welding technologies require low welding speeds, large quantities of filler material and large input energy per unit length which can result in damages to microstructure and consequently diminished high-temperature properties. Laser-multi-pass-narrow-gap-welding (Laser-MPNG) is the solution to this problem.

This paper presents the technological approach of Laser-MPNG which uses a brilliant fiber laser with a maximum laser power of 4 kW and remoweld®MPNG, a welding head that was specifically developed to join the nickel superalloy Alloy 617occ as a promising candidate for future industrial welding applications in pipe elements of up to 72.5 mm wall thickness in modern power stations.

Topics
Power plants, Lasers, Corrosion, Alloys, Welding
1.
Göbel
,
G.
 et al.: “
New Application possibilities for fiber laser welding
”,
Proc. of 26th ICALEO
,
2007
,
USA
Google Scholar
 
2.
Schedewy
R..
 et al.: “
MULTI-PASS-Narrow- Gap-LASER-BEAM-Welding of Hot Crack Sensitive Thick Aluminum Plates
”,
Proc. of 32nd ICALEO
,
2013
,
USA
Google Scholar
 
3.
Standfuss
 et al:
“LASER-MULTI-PASS-WELDING OF ALUMINIUN AND STEEL WITH SHEET THICKNESS ABOVE 50 MM
,
Proc. of 34th ICALEO
,
2015
,
USA
Google Scholar
 
4.
Klenk
,
A.
: “
Anforderungen an Schweißverbindungen in Hocheffizienzkraftwerken
”,
Cluster-Forum Schweißtechnik im Kraftwerksbau
,
SLV München
20.10.2009
5.
Knezevic
,
V.
 et al.:
Creep Behaviour of Thick-Wall Alloy 617 Seamless Pipes for 700°C Power Plant Technology
, In:
Procedia Engineering
(
2013
) Nr.
55
, p.
240
245
https://doi.org/10.1016/j.proeng.2013.03.249
Google Scholar
 
6.
Kuhn
,
B.
 et al.: “
Beurteilung des Stress-Relaxation-/ Strain-Age-Cracking- Verhaltens von Alloy 6178 und dessen Schweißverbindungen
”, FVW/FVHT, 34. Vortragsveranstaltung, 25.11.2011
7.
Mentz
,
J.
 et al.: “
Einfluss der Wärmebehandlung auf die Relaxationsrissneigung und die Heißrissneigung von Alloy 617B
8.
Xu
,
H.
 et al.: “
Evolution of carbides and its characterization in HAZ during NG-TIG welding of Alloy 617B
” In:
Materials Characterization
(
2017
), Vol.
130
, p.
270
277
https://doi.org/10.1016/j.matchar.2017.06.021
Google Scholar
 
9.
Schmidt
,
K.
: “
MARCKO 700: Werkstoffqualifizierung für das 700/720°-Kraftwerk
”, Abschlussbericht, Juni
2010
10.
Speicher
,
M.
 et al.: „
Experimental investigations and numerical simulation accompanying the HWT test loop operation
“ In:
Advances in Materials Technology for Fossil Power Plants, Proc. of 8. Int. Con., Albufeira
,
2016
,
Portugal
Google Scholar
 
11.
Brenner
,
B
 et al:
Laser Multi Pass Narrow Gap Welding – A New Technology for Joining Thick Walled Components of Power Stations; VGB- Workshop
Materials and Quality Assurance 2017
”, Mai 18/19 th 2017, Maria Enzersdorf,
Austria
12.
N.N.
:
Hochwarmfeste
Nickelbasislegierung NiCr23Co12Mo; Werkstoff-Nr. 2.4673 Stab, Schmiedestück - WB 573
;
Verband der TÜV e. V.
,
Köln
,
2013
Google Scholar
 
13.
Ream
,
S.
: “
Trends & Keys to Success In Laser Welding
”,
Int. Laser Symposium
, 23./24.02.2016,
Dresden
This content is only available via PDF.
© 2018 Laser Institute of America.
2018
Laser Institute of America
You do not currently have access to this content.