Change search
CiteExportLink to record
Permanent link

Direct link
Cite
Citation style
  • apa
  • ieee
  • modern-language-association-8th-edition
  • vancouver
  • Other style
More styles
Language
  • de-DE
  • en-GB
  • en-US
  • fi-FI
  • nn-NO
  • nn-NB
  • sv-SE
  • Other locale
More languages
Output format
  • html
  • text
  • asciidoc
  • rtf
Directed Energy Deposition Additive Manufacturing and Welding of Duplex Stainless Steel using Laser Beam
University West, Department of Engineering Science, Division of Welding Technology. (KAMPT)ORCID iD: 0000-0002-6820-4312
2024 (English)Doctoral thesis, comprehensive summary (Other academic)
Abstract [en]

Duplex stainless steels (DSSs), with a ferritic-austenitic microstructure, are used in a wide range of applications thanks to their high corrosion resistance and good mechanical properties. However, efficient and successful production and joining of DSS require precise control of processes and an in-depth understanding of the relations between composition, processing thermal cycles, resulting microstructures and properties. In this study welding and direct energy deposition of DSS using a laser beam, resulting weld and component microstructures, and properties are explored.

In the first part a lean FDX 27 DSS, showing the transformation-induced plasticity (TRIP) effect, was autogenously laser welded and laser reheated using pure argon or pure nitrogen as shielding gas. The weld metal austenite fraction was 22% for argon-shielding and 39% for nitrogen-shielding in the as-welded conditions. Less nitrides were found with nitrogen-shielding compared to argon-shielding. Laser reheating did not significantly affect nitride content or austenite fraction for argon-shielding. However, laser reheating of the nitrogen shielded weld removed nitrides and increased the austenite fraction to 57% illustrating the effectiveness of this approach.

Phase fraction analysis is important for DSS since the balance between ferrite and austenite affects the properties. For TRIP steels the risk of austenite-to-martensite transformation during sample preparation also has to be considered. Ferrite, austenite and martensite were identified and quantified using light optical microscopy (LOM) and electron backscatter diffraction (EBSD) analysis. It was found that mechanical polishing produced up to 26% strain-induced martensite, while no martensite was observed after electrolytic polishing.

In the second part a systematic four-stage methodology was applied to develop procedures for additive manufacturing of standard 22% Cr DSS components employing direct energy deposition using a laser beam and wire feedstock (DED-LB/w) combined with the hot wire technology. In the four stages, single-bead passes, a single-bead wall, a block, and finally a cylinder with an inner diameter of 160 mm, thickness of 30 mm, and height of 140 mm were produced. Implementing this methodology with a stepwise increase in the deposited volume and geometrical complexity can successfully be used when developing additive manufacturing procedures for significantly sized metallic components. The as-deposited microstructure was inhomogeneous and repetitive including highly ferritic regions with nitrides and regions with high fractions of austenite. Heat treatment for 1 hour at 1100°C homogenized the microstructure, dissolved the nitrides, and almost balanced the ferrite and austenite phase fractions. Strength, ductility, and toughness were at a high level for the cylinder, comparable to those of wrought type 2205 steel, both as-deposited and after heat treatment. The pitting corrosion resistance revealed that microstructural differences, including ferrite-to-austenite ratio, alloying element distribution in ferrite and austenite , and the presence of nitrides, affected the corrosion resistance of DED-LB/w DSS. It was also shown that alongside the decomposition of ferrite into Fe-rich (α) and Cr-rich (αʹ) phases, clustering of Ni, Mn, and Si atoms are contributing to the 475°C -embrittlement of DSS manufactured by DED-LB/w.

This study has illustrated that a laser beam can successfully be used as heat source in processing of DSS both for welding and additive manufacturing. However, challenges like nitrogen loss, low austenite fractions and nitride formation have to be handled by precise process control and/or heat treatment.

Abstract [sv]

Duplexa rostfria stål (DSS) med en ferritisk-austenitisk mikrostruktur används inom ett brett spektrum av tillämpningar tack vare hög korrosionsbeständighet och goda mekaniska egenskaper. Effektiv och framgångsrik produktion och sammanfogning av DSS kräver noggrann kontroll av processer och en djupgående förståelse av sambanden mellan kemisk sammansättning, termiska cykler, resulterande mikrostrukturer och egenskaper. I detta arbete studerades svetsning och metalldeponering (direct energy deposition) av DSS med hjälp av laseroch resulterande mikrostrukturer samt egenskaper utvärderades.

I den första delen svetsades ett lägre legerat FDX 27 duplex rostfritt stål, som har en TRIP-effekt (transformation-induced plasticity), med laser och laseruppvärmdes med ren argon eller ren kvävgas som skyddsgas. Svetsgodsets austenitandel var 22% för argonskydd och 39% för kvävgasskydd under svetsningen. Färre nitrider observerades med kvävgasskydd jämfört med argonskydd. Laseruppvärmning påverkade inte signifikant nitrid- eller austenitandelen för argonskydd. Dock resulterade laseruppvärmningen av svetsen med kvävgasskydd i minskad nitridandel samtidigt som austenitandelen ökade till 57%, vilket visar effektiviteten av detta tillvägagångssätt.

Analys av fasfraktion är viktig för DSS eftersom balansen mellan ferrit och austenit påverkar egenskaperna. För TRIP-stål måste risken för martensitomvandling av austenit under provberedningen också beaktas. Ferrit, austenit och martensit identifierades och kvantifierades med hjälp av ljusoptisk mikroskopi (LOM) och analys med hjälp av diffraktion av bakåtspridda elektroner (EBSD electron backscatter diffraction). Det visade sig att mekanisk polering gav upp till 26% deformationsinducerad martensit, medan ingen martensit observerades efter elektrolytisk polering.

I den andra delen användes en systematisk metodik i fyra steg för att utveckla procedurer för additiv tillverkning av standardkomponenter i 22% krom DSS med metalldeponering och laser med svetstråd som tillsatsmaterial (DED-LB/w), kombinerad med varmtrådteknologi. I de fyra stegen tillverkades enkelsträngar, enkelväggar, ett block och slutligen en cylinder med en inre diameter på 160 mm, tjocklek på 30 mm och höjd på 140 mm. Genom att implementera denna metodik med en stegvis ökning av den deponerade volymen och geometrisk komplexitet kan additiva tillverkningsprocedurer framgångsrikt användas för utveckling av metallkomponenter med betydande storlekar. Den deponerade mikrostrukturen var ojämn och innehöll upprepade områden med hög ferrithalt och nitrider samt områden med hög andel av austenit. Värmebehandling i 1 timme vid 1100°C homogeniserade mikrostrukturen, löste upp nitriderna och jämnade nästan ut ferrit- och austenitandelarna. Hållfasthet, duktilitet och seghet var goda för cylindern, jämförbara med de av smidda typer av 2205 DSS, både som deponerad och efter värmebehandling. Gropfrätning och korrosionsmotstånd visade att mikrostrukturella skillnader, inklusive förhållande ferrit till austenit, fördelning av legeringselement i ferrit och austenit och närvaro av nitrider, påverkade korrosionsmotståndet för DED-LB/w DSS. Det visades också att, tillsammans med sönderfallet av ferrit till Fe-rika (α) och Cr-rika (αʹ) faser, bidrar kluster av Ni, Mn och Si-atomer till sprödhet vid 475°C hos DSS tillverkade av DED-LB/w.

Detta arbete har visat att en laser framgångsrikt kan användas som värmekälla vid tillverkning av DSS både för svetsning och additiv tillverkning. Utmaningar som kväveutarmning, låga austenitandelar och bildning av nitrider måste dock hanteras genom noggrann processtyrning och/eller värmebehandling.

Place, publisher, year, edition, pages
Trollhättan: University West , 2024. , p. 90
Series
PhD Thesis: University West ; 63
Keywords [en]
Duplex stainless steel; Laser welding; Additive manufacturing; Direct Energy Deposition using a Laser Beam; Microstructure characterization
Keywords [sv]
Duplexa rostfria stål; Lasersvetsning; Additiv tillverkning; Metalldeponering med laser; Mikrostruktur
National Category
Manufacturing, Surface and Joining Technology
Research subject
Production Technology
Identifiers
URN: urn:nbn:se:hv:diva-21251ISBN: 978-91-89325-71-5 (print)ISBN: 978-91-89325-70-8 (electronic)OAI: oai:DiVA.org:hv-21251DiVA, id: diva2:1839301
Public defence
2024-04-22, C118, Gustava Melins gata, Trollhättan, 10:00 (English)
Opponent
Supervisors
Note

All papers are CC BY 4.0

Paper F is  submitted.

Available from: 2024-03-11 Created: 2024-02-20
List of papers
1. Promoting austenite formation in laser welding of duplex stainless steel-impact of shielding gas and laser reheating
Open this publication in new window or tab >>Promoting austenite formation in laser welding of duplex stainless steel-impact of shielding gas and laser reheating
2021 (English)In: Welding in the World, ISSN 0043-2288, E-ISSN 1878-6669, Vol. 65, p. 499-511Article in journal (Refereed) Published
Abstract [en]

Avoiding low austenite fractions and nitride formation are major challenges in laser welding of duplex stainless steels (DSS). The present research aims at investigating efficient means of promoting austenite formation during autogenous laser welding of DSS without sacrificing productivity. In this study, effects of shielding gas and laser reheating were investigated in welding of 1.5-mm-thick FDX 27 (UNS S82031) DSS. Four conditions were investigated: Ar-shielded welding, N2-shielded welding, Ar-shielded welding followed by Ar-shielded laser reheating, and N2-shielded welding followed by N2-shielded laser reheating. Optical microscopy, thermodynamic calculations, and Gleeble heat treatment were performed to study the evolution of microstructure and chemical composition. The austenite fraction was 22% for Ar-shielded and 39% for N2-shielded as-welded conditions. Interestingly, laser reheating did not significantly affect the austenite fraction for Ar shielding, while the austenite fraction increased to 57% for N2-shielding. The amount of nitrides was lower in N2-shielded samples compared to in Ar-shielded samples. The same trends were also observed in the heat-affected zone. The nitrogen content of weld metals, evaluated from calculated equilibrium phase diagrams and austenite fractions after Gleeble equilibrating heat treatments at 1100 °C, was 0.16% for N2-shielded and 0.11% for Ar-shielded welds, confirming the importance of nitrogen for promoting the austenite formation during welding and especially reheating. Finally, it is recommended that combining welding with pure nitrogen as shielding gas and a laser reheating pass can significantly improve austenite formation and reduce nitride formation in DSS laser welds. © 2020, The Author(s).

Keywords
Austenite; Duplex stainless steel; Heat affected zone; Heat treatment; Industrial heating; Microstructural evolution; Nitrides; Nitrogen; Shielding; Welding, Austenite formation; Autogenous laser welding; Chemical compositions; Duplex stainless steel (DSS); Equilibrium phase diagrams; Nitride formation; Nitrogen content; Thermodynamic calculations, Argon lasers
National Category
Manufacturing, Surface and Joining Technology
Research subject
Production Technology
Identifiers
urn:nbn:se:hv:diva-16028 (URN)10.1007/s40194-020-01026-7 (DOI)000587932200001 ()2-s2.0-85095716448 (Scopus ID)
Funder
EU, European Research Council, H2020-MSCA-RISE-2018 Number 823786
Note

Open access funding provided by University West. James Oliver and Ravi Vishnu from the Outokumpu Stainless AB (Avesta, Sweden) are appreciatively acknowledged for their help and support. This study received great support from the EU-project H2020-MSCA-RISE-2018 Number 823786, i-Weld, and the Swedish Agency for Economic and Regional Growth through the European Union – European Development Fund.

Creative CommonsAttribution 4.0 International License

Available from: 2020-11-16 Created: 2020-11-16 Last updated: 2024-02-20Bibliographically approved
2. Identification and quantification of martensite in ferritic-austenitic stainless steels and welds
Open this publication in new window or tab >>Identification and quantification of martensite in ferritic-austenitic stainless steels and welds
2021 (English)In: Journal of Materials Research and Technology, ISSN 2238-7854, E-ISSN 2214-0697, Vol. 15, p. 3610-3621Article in journal (Refereed) Published
Abstract [en]

This paper aims at the phase identification and quantification in transformation induced plasticity duplex stainless steel (TDSS) base and weld metal containing ferrite, austenite, and martensite. Light optical microscopy (LOM) and electron backscatter diffraction (EBSD) analysis were employed to analyze phases. Samples were either mechanically or electrolytically polished to study the effect of the preparation technique. Mechanical polishing produced up to 26% strain-induced martensite. Electrolytic polishing with 150 g citric acid, 300 g distilled water, 600 mL H3PO4, and 450 mL H2SO4 resulted in martensite free surfaces, providing high-quality samples for EBSD analysis. Martensite identification was challenging both with LOM, due to the similar etching response of ferrite and martensite, and with EBSD, due to the similar lattice structures of ferrite and martensite. An optimized Beraha color etching procedure was developed that etched martensite distinctively. A novel step-by-step EBSD methodology was also introduced considering grain size and orientation, which successfully identified and quantified martensite as well as ferrite and austenite in the studied TDSS. Although here applied to a TDSS, the presented EBSD methodology is general and can, in combination with knowledge of the metallurgy of the specific material and with suitable adaption, be applied to a multitude of multiphase materials. It is also general in the sense that it can be used for base material and weld metals as well as additive manufactured materials.

Place, publisher, year, edition, pages
Elsevier Editora Ltda, 2021
Keywords
Duplex stainless steel, Mechanical polishing, Electrolytic polishing, Phase analysis, Martensite, Electron backscatter diffraction
National Category
Metallurgy and Metallic Materials Other Materials Engineering
Research subject
Production Technology
Identifiers
urn:nbn:se:hv:diva-17790 (URN)10.1016/j.jmrt.2021.09.153 (DOI)000712162500008 ()2-s2.0-85117073816 (Scopus ID)
Note

 This study received support from the EU-project H2020-MSCA-RISE-2018 Number 823786, i-Weld, and the Swedish Agency for Economic and Regional Growth through the European Union–European Development Fund

Available from: 2021-12-22 Created: 2021-12-22 Last updated: 2024-09-02
3. Wire laser metal deposition of 22% Cr duplex stainless steel: as-deposited and heat-treated microstructure and mechanical properties
Open this publication in new window or tab >>Wire laser metal deposition of 22% Cr duplex stainless steel: as-deposited and heat-treated microstructure and mechanical properties
Show others...
2022 (English)In: Journal of Materials Science, ISSN 0022-2461, E-ISSN 1573-4803, Vol. 57, no 21, p. 9556-9575Article in journal (Refereed) Published
Abstract [en]

Duplex stainless steel (DSS) blocks with dimensions of 150 × 70x30 mm3 were fabricated by Laser Metal Deposition with Wire (LMDw). Implementation of a programmable logic control system and the hot-wire technology provided a stable and consistent process producing high-quality and virtually defect-free deposits. Microstructure and mechanical properties were studied for as-deposited (AD) material and when heat-treated (HT) for 1 h at 1100 °C. The AD microstructure was inhomogeneous with highly ferritic areas with nitrides and austenitic regions with fine secondary austenite occurring in a periodic manner. Heat treatment produced a homogenized microstructure, free from nitrides and fine secondary austenite, with balanced ferrite and austenite fractions. Although some nitrogen was lost during LMDw, heat treatment or reheating by subsequent passes in AD allowed the formation of about 50% austenite. Mechanical properties fulfilled common requirements on strength and toughness in both as-deposited and heat-treated conditions achieving the highest strength in AD condition and best toughness and ductility in HT condition. Epitaxial ferrite growth, giving elongated grains along the build direction, resulted in somewhat higher toughness in both AD and HT conditions when cracks propagated perpendicular to the build direction. It was concluded that high-quality components can be produced by LMDw and that deposits can be used in either AD or HT conditions. The findings of this research provide valuable input for the fabrication of high-performance DSS AM components

Keywords
A-stable; Build direction; Defect-free; Heat treated condition; High quality; Hot wires; Laser metal deposition; Microstructures and mechanical properties; Programmable logic control system; Secondary austenite
National Category
Manufacturing, Surface and Joining Technology Metallurgy and Metallic Materials
Research subject
Production Technology
Identifiers
urn:nbn:se:hv:diva-18106 (URN)10.1007/s10853-022-06878-6 (DOI)000744401200004 ()2-s2.0-85123120534 (Scopus ID)
Available from: 2022-02-07 Created: 2022-02-07 Last updated: 2024-04-12Bibliographically approved
4. Wire laser metal deposition additive manufacturing of duplex stainless steel components -Development of a systematic methodology
Open this publication in new window or tab >>Wire laser metal deposition additive manufacturing of duplex stainless steel components -Development of a systematic methodology
Show others...
2021 (English)In: Materials, E-ISSN 1996-1944, Vol. 14, no 23, article id 7170Article in journal (Refereed) Published
Abstract [en]

A systematic four-stage methodology was developed and applied to the Laser Metal Deposition with Wire (LMDw) of a duplex stainless steel (DSS) cylinder > 20 kg. In the four stages, single-bead passes, a single-bead wall, a block, and finally a cylinder were produced. This stepwise approach allowed the development of LMDw process parameters and control systems while the volume of deposited material and the geometrical complexity of components increased. The as-deposited microstructure was inhomogeneous and repetitive, consisting of highly ferritic regions with nitrides and regions with high fractions of austenite. However, there were no cracks or lack of fusion defects; there were only some small pores, and strength and toughness were comparable to those of the corresponding steel grade. A heat treatment for 1 h at 1100 degrees (C) was performed to homogenize the microstructure, remove nitrides, and balance the ferrite and austenite fractions compensating for nitrogen loss occurring during LMDw. The heat treatment increased toughness and ductility and decreased strength, but these still matched steel properties. It was concluded that implementing a systematic methodology with a stepwise increase in the deposited volume and geometrical complexity is a cost-effective way of developing additive manufacturing procedures for the production of significantly sized metallic components.

Place, publisher, year, edition, pages
MDPI, 2021
Keywords
Additives; Austenite; Cost effectiveness; Cylinders (shapes); Deposition; Ferrite; Heat treatment; Metals; Microstructure; Nitrides; Stainless steel, Geometrical complexity; Laser metal deposition; Methodology; Microstructure characterization; Process parameters; Stainless steel cylinders; Steel components; Stepwise approach; Systematic methodology; Wires process, 3D printers
National Category
Manufacturing, Surface and Joining Technology Metallurgy and Metallic Materials
Research subject
Production Technology
Identifiers
urn:nbn:se:hv:diva-17911 (URN)10.3390/ma14237170 (DOI)000735440900001 ()2-s2.0-85120057286 (Scopus ID)
Funder
Knowledge Foundation, 20170060
Available from: 2021-12-30 Created: 2021-12-30 Last updated: 2024-07-04
5. Corrosion resistance and microstructure analysis of additively manufactured 22% chromium duplex stainless steel by laser metal deposition with wire
Open this publication in new window or tab >>Corrosion resistance and microstructure analysis of additively manufactured 22% chromium duplex stainless steel by laser metal deposition with wire
Show others...
2023 (English)In: Journal of Materials Research and Technology, ISSN 2238-7854, E-ISSN 2214-0697, Vol. 26, p. 6741-6756Article in journal (Refereed) Published
Abstract [en]

Microstructure characteristics and pitting corrosion of a duplex stainless steel (DSS) manufactured by laser metal deposition with wire (LMDw) were studied. The layer-by-layer LMDw process resulted in a mixed microstructure of predominantly ferrite with 2% austenite and chromium-rich nitrides, and reheated regions with ~33% austenite. The high cooling rate of LMDw restricted the distribution of Cr, Mo, and Ni, in ferrite and austenite, while N diffuses from ferrite to austenite. Subsequent heat treatment at 1100 C for 1 h resulted in homogenized microstructure, dissolution of nitrides, and balanced ferrite/austenite ratio. It also led to the redistribution of Cr and Mo to ferrite, and Ni and N to austenite. At room temperature, cyclic potentiodynamic polarization measurements in 1.0 M NaCl solution showed no significant differences in corrosion resistance between the as-deposited and heat-treated samples, despite the differences in terms of ferrite to austenite ratio and elemental distribution. Critical pitting temperature (CPT) was the lowest (60 C) for the predominantly ferritic microstructure with finely dispersed chromium-rich nitrides; while reheated area with ~33% austenite in as-deposited condition achieved higher critical temperature comparable to what was obtained after heat treatment (73 and 68 C, respectively). At temperatures above the CPT, selective dissolution of the ferrite after deposition was observed due to depletion of N, while after heat treatment, austenite preferentially dissolved due to Cr and Mo concentrating in ferrite. In summary, results demonstrate how microstructural differences in terms of ferrite-to-austenite ratio, distribution of corrosion-resistant elements, and presence of nitrides affect corrosion resistance of LMDw DSS.

Keywords
Additive manufacturing, Duplex stainless steel, Laser metal deposition, Localized corrosion, Microstructure-property relation
National Category
Manufacturing, Surface and Joining Technology
Research subject
Production Technology
Identifiers
urn:nbn:se:hv:diva-20883 (URN)10.1016/j.jmrt.2023.09.037 (DOI)001139454200001 ()2-s2.0-85171616425 (Scopus ID)
Note

CC BY 4.0

Available from: 2023-12-28 Created: 2023-12-28 Last updated: 2024-09-02

Open Access in DiVA

fulltext(60049 kB)319 downloads
File information
File name FULLTEXT01.pdfFile size 60049 kBChecksum SHA-512
a4786c52a1a06f5ae1682fa5bbf38c19bfb51370d4d23ac71f4427f98486d58c57f1fd3d130bbdb5ab4850016acc75e6f0366e33dec08b28c973e4764d12624b
Type fulltextMimetype application/pdf
fulltext(1499 kB)64 downloads
File information
File name FULLTEXT02.pdfFile size 1499 kBChecksum SHA-512
94c2f878e612a325052bc4206bc11bf28bf5f71623e5755e6bb91cb65786bbedab5f491c9f6ca1620c8b24a7de6f3b8ee674824ccbf587e223f0b0c58e6a8c86
Type fulltextMimetype application/pdf

Authority records

Baghdadchi, Amir

Search in DiVA

By author/editor
Baghdadchi, Amir
By organisation
Division of Welding Technology
Manufacturing, Surface and Joining Technology

Search outside of DiVA

GoogleGoogle Scholar
Total: 384 downloads
The number of downloads is the sum of all downloads of full texts. It may include eg previous versions that are now no longer available

isbn
urn-nbn

Altmetric score

isbn
urn-nbn
Total: 1295 hits
CiteExportLink to record
Permanent link

Direct link
Cite
Citation style
  • apa
  • ieee
  • modern-language-association-8th-edition
  • vancouver
  • Other style
More styles
Language
  • de-DE
  • en-GB
  • en-US
  • fi-FI
  • nn-NO
  • nn-NB
  • sv-SE
  • Other locale
More languages
Output format
  • html
  • text
  • asciidoc
  • rtf