Change search
Refine search result
1 - 7 of 7
CiteExportLink to result list
Permanent 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
Rows per page
  • 5
  • 10
  • 20
  • 50
  • 100
  • 250
Sort
  • Standard (Relevance)
  • Author A-Ö
  • Author Ö-A
  • Title A-Ö
  • Title Ö-A
  • Publication type A-Ö
  • Publication type Ö-A
  • Issued (Oldest first)
  • Issued (Newest first)
  • Created (Oldest first)
  • Created (Newest first)
  • Last updated (Oldest first)
  • Last updated (Newest first)
  • Disputation date (earliest first)
  • Disputation date (latest first)
  • Standard (Relevance)
  • Author A-Ö
  • Author Ö-A
  • Title A-Ö
  • Title Ö-A
  • Publication type A-Ö
  • Publication type Ö-A
  • Issued (Oldest first)
  • Issued (Newest first)
  • Created (Oldest first)
  • Created (Newest first)
  • Last updated (Oldest first)
  • Last updated (Newest first)
  • Disputation date (earliest first)
  • Disputation date (latest first)
Select
The maximal number of hits you can export is 250. When you want to export more records please use the Create feeds function.
  • 1.
    Bates, William P.
    et al.
    University West, Department of Engineering Science.
    Patel, Vivek
    University West, Department of Engineering Science, Division of Welding Technology.
    Rana, Harikrishna
    Department of Engineering, University of Palermo,Palermo (ITA).
    Andersson, Joel
    University West, Department of Engineering Science, Division of Welding Technology.
    De Backer, Jeroen
    University West, Department of Engineering Science, Division of Welding Technology. Friction Welding Process Section, TWI Ltd., Cambridge, CB21 (GBR).
    Igestrand, Mattias
    University West, Department of Engineering Science, Division of Welding Technology.
    Fratini, Livan
    Department of Engineering, University of Palermo, Palermo (ITA).
    Correction to: Properties Augmentation of Cast Hypereutectic Al–Si Alloy Through Friction Stir Processing (Metals and Materials International, (2022), 10.1007/s12540-022-01207-7)2023In: Metals and Materials International, ISSN 1598-9623, E-ISSN 2005-4149, Vol. 29, article id 876Article in journal (Other academic)
    Abstract [en]

    The graphic abstract was missing from this article and it has been given in this correction. The original article has been corrected. © 2022, The Author(s) under exclusive licence to The Korean Institute of Metals and Materials.

    Download full text (pdf)
    fulltext
  • 2.
    Bates, William P.
    et al.
    Department of Engineering Science, University West, Trollhättan (SWE).
    Patel, Vivek
    University West, Department of Engineering Science, Division of Welding Technology.
    Rana, Harikrishna
    Department of Engineering, University of Palermo, Palermo (ITA).
    Andersson, Joel
    University West, Department of Engineering Science, Division of Welding Technology.
    De Backer, Jeroen
    University West, Department of Engineering Science, Division of Production Systems. Friction Welding Process Section, TWI Ltd., Cambridge (GBR).
    Igestrand, Mattias
    University West, Department of Engineering Science, Division of Welding Technology.
    Fratini, Livan
    Department of Engineering, University of Palermo, Palermo (ITA).
    Properties Augmentation of Cast Hypereutectic Al-Si Alloy Through Friction Stir Processing2022In: Metals and Materials International, ISSN 1598-9623, E-ISSN 2005-4149Article in journal (Refereed)
    Abstract [en]

    The present endeavour is to augment mechanical attributes via friction stir processing (FSP) in hypereutectic aluminium-silicon castings by the means of microstructural modifications and defects reduction. Wherein, the study proceeds with mainly two approaches namely, alteration in tool revolution (TR) and the number of FSP passes. The prepared specimens were evaluated investigating volume fraction of porosities, microstructural characterizations and microhardness. Therefrom, the specimen with highest number of passes delivered most uniform properties resulting from the reduction in casting porosities and refined silicon particle uniform distribution throughout friction stir processed zone. This endeavour may be considered as a footstep towards more industrial readied material transformation.

    Download full text (pdf)
    Springer
  • 3. Harati, Ebrahim
    et al.
    Jose, Bibu
    University West, Department of Engineering Science, Division of Welding Technology.
    Igestrand, Mattias
    University West, Department of Engineering Science, Division of Welding Technology.
    Wire arc additive manufacturing using high-strength steel tubular and solid wires2024In: Welding International, ISSN 0950-7116, Vol. 38, no 5, p. 329-334Article in journal (Refereed)
    Abstract [en]

    Wire Arc Additive Manufacturing (WAAM) utilizes wire as the feedstock and welding arc as the heat source. While Solid Wires (SW) are common, exploration of tubular wires such as Metal Cored Wires (MCW) in Additive Manufacturing (AM) is limited. MCW offers flexibility for alloy design, but both SW and MCW can create silicon islands on welds, affecting mechanical properties and processability. This study uses Gas Metal Arc Welding (GMAW) in Cold Metal Transferred (CMT) mode to compare SW and MCW deposits with different gases. MCW shows more uniform penetration, potentially reducing lack of fusion in AM layers. A novel approach is then used to modify the MCW to minimize silicate formation, reducing islands on the surface. Comparative analysis shows a significant reduction and change in the location of silicates with modified MCW compared to standard, with mechanical properties in as-welded and after post-weld heat treatment (PWHT) remaining comparable to the standard wire.

    Download full text (pdf)
    fulltext
  • 4.
    Högström, Mats
    et al.
    University West, Department of Engineering Science, Division of Welding Technology.
    Fadaei, Amirhosein
    University West, Department of Engineering Science.
    Rahimi, Amin
    University West, Department of Engineering Science, Division of Welding Technology.
    Li, Peigang
    University West, Department of Engineering Science, Division of Welding Technology.
    Igestrand, Mattias
    University West, Department of Engineering Science, Division of Welding Technology.
    Andersson, Joel
    University West, Department of Engineering Science, Division of Welding Technology.
    Scotti, Americo
    University West, Department of Engineering Science, Division of Welding Technology.
    Proposal and Assessment of a Multiple Cycle-Continuous Cooling Transformation (MC-CCT) Diagram for Wire Arc Additive Manufacturing of Thin Walls2023In: Metals, ISSN 2075-4701, Vol. 13, no 9, article id 1533Article in journal (Refereed)
    Abstract [en]

    Continuous cooling transformation (CCT) diagrams of base metals are common in welding. They can be built using physical or numerical simulations, each with advantages and limitations. However, those are not usual for weld metal, considering its variable composition due to the dilution of the weld into the base metal. Wire Arc Additive Manufacturing (WAAM) is a distinctive casein which the interest in materials comparable with weld composition raises attention to estimating their mechanical properties. Notwithstanding, this concept is still not used in WAAM. Therefore, the aim of this work was to address a methodology to raise MC-CCT (Multiple Cycle ContinuousCooling Transformation) diagrams for WAAM by combining physical and numerical simulations. A high-strength low-alloy steel (HSLA) feedstock (a combination of a wire and a shielding gas) was used as a case study. To keep CCT as representative as possible, the typical multiple thermal cycles for additive manufacturing thin walls were determined and replicated in physical simulations (Gleeble dilatometry). The start and end transformations were determined by the differential linear variation approach for each thermal cycle. Microstructure analyses and hardness were used to characterise the product after the multiple cycles. The same CCT diagram was raised by a commercial numerical simulation package to determine the shape of the transformation curves. A range of austenitic grain sizes was scanned for the curve position matching the experimental results. Combining the experimental data and numerically simulated curves made estimating the final CCT diagram possible.

    Download full text (pdf)
    fulltext
  • 5.
    Patel, Vivek
    et al.
    University West, Department of Engineering Science, Division of Welding Technology.
    De Backer, Jeroen
    University West, Department of Engineering Science, Division of Production Systems. Friction Welding Process Section, TWI Ltd., CB21 6AL Cambridge (GBR).
    Hindsefelt, Henrik
    Hydro Extruded Solutions AB, Finspång (SWE).
    Igestrand, Mattias
    University West, Department of Engineering Science, Division of Welding Technology.
    Azimi, Saeed
    Volvo Car corporation, Gothenburg (SWE).
    Andersson, Joel
    University West, Department of Engineering Science, Division of Welding Technology.
    Säll, Jörgen
    ESAB, Laxå (SWE).
    High speed friction stir welding of AA6063-T6 alloy in lightweight battery trays for EV industry: Influence of tool rotation speeds2022In: Materials letters (General ed.), ISSN 0167-577X, E-ISSN 1873-4979, Vol. 318, article id 132135Article in journal (Refereed)
    Abstract [en]

    Present work demonstrates high speed friction stir welding (HSFSW) of light weight battery trays assembly in electric vehicle (EV). Despite of solid-state and green nature of FSW, it suffers from the relatively low welding speed. With the help of suitable tool design and machine tool parameters, we successfully achieved defect-free welds at high welding speed of 4.0 and 4.5 m/min. Good quality welds are produced in 3 mm thick AA6063-T6 extruded aluminium alloy at such a high welding speeds by implementing violent material mixing i.e., higher tool rotation speeds (3500–4500 rpm) and plunge force (8.5–10.5 kN). The HSFSW cross-section registered curious hardness profile of ‘U’ shape. HSFSW resulted softening of weld stir zone (∼60 HV) along with HAZ (∼50 HV). The highest joint efficiency of 72 % was found for the weld produced at 4.0 m/min and 3500 rpm.

    Download full text (pdf)
    fulltext
  • 6.
    Patel, Vivek
    et al.
    University West, Department of Engineering Science, Division of Welding Technology.
    De Backer, Jeroen
    University West, Department of Engineering Science, Division of Production Systems. Friction Welding Process Section, TWI Ltd., Cambridge (GBR).
    Hindsefelt, Henrik
    Hydro Extruded Solutions AB, Finspång (SWE).
    Igestrand, Mattias
    University West, Department of Engineering Science, Division of Welding Technology.
    Azimi, Saeed
    Volvo Car corporation, Gothenburg (SWE).
    Andersson, Joel
    University West, Department of Engineering Science, Division of Welding Technology.
    Säll, Jörgen
    SAB, Laxå (SWE).
    High-speed friction stir welding in light weight battery trays for the EV industry2022In: Science and technology of welding and joining, ISSN 1362-1718, E-ISSN 1743-2936, Vol. 27, no 4, p. 250-255Article in journal (Refereed)
    Abstract [en]

    Present work aims to achieve high welding speed during friction stir welding of lightweight battery trays in the electric vehicle industry. This study reports high-speed friction stir welding (HSFSW) up to 4.0 m mi -1 in AA6063-T6 alloys. The defect-free HSFSW joints are produced by adopting aggressive material mixing, i.e. higher tool rotation and plunge force. HSFSW weld cross-section reported an unusual hardness profile of "U"shape instead of "W"shape in conventional FSW of AA6xxx alloys. HSFSW resulted softening of weld stir zone (~60HV) along with HAZ (~53HV) against the base material (BM) hardness of ~90HV. The HSFSW at 4.0 m min -1 obtained good joint strength of 71% of the BM. Microstructure evolutions across the fractured weld cross-section are discussed using EBSD analysis.

    Download full text (pdf)
    T&F
  • 7.
    Patel, Vivek
    et al.
    University West, Department of Engineering Science, Division of Welding Technology.
    Wouters, Hendrik
    University West, Department of Engineering Science.
    Baghdadchi, Amir
    University West, Department of Engineering Science, Division of Welding Technology.
    De Backer, Jeroen
    University West, Department of Engineering Science, Division of Production Systems. Friction & Forge Processes, TWI, Cambridge (GBR).
    Igestrand, Mattias
    University West, Department of Engineering Science, Division of Welding Technology.
    Azimi, Saeed
    Volvo Car Corporation, Gothenburg (SWE).
    Andersson, Joel
    University West, Department of Engineering Science, Division of Welding Technology.
    Robotic friction stir welding in lightweight battery assembly of extrusion-cast aluminium alloys2023In: Journal of Advanced Joining Processes, ISSN 2666-3309, Vol. 8, article id 100156Article in journal (Refereed)
    Abstract [en]

    The present study focuses on developing lightweight assembly of two different aluminium alloys extruded and high pressure die cast (HPDC) for battery frame assembly in BEV. The goal is to produce defect-free welds in lap configuration with smooth surface finish. Stationary shoulder friction stir welding (SSFSW) was employed with welding speeds of 3–15 mm/s. EBSD analysis revealed two groups of grains in the stir zone (SZ) due to dynamic recrystallization. Moreover, the grain size of the SZ significantly decreased compared to both alloys. The cast alloy contains large iron particles, and that were broken by the rotating probe, and the stirred material consisted of fine dispersed precipitates. Tensile-shear test found the fracture location at the hook area near to cast, and a model representing fracture behavior is also discussed. With increasing welding speed from 3 to 5 mm/s, the tensile strength found ∼95 and ∼100 MPa, respectively without any significance difference in the fracture behavior and location. Overall, this study provides valuable insights such as materials mixing, grain refinement, and joint strength in dissimilar joining using SSFSW. The findings could be useful in developing optimized welding parameters and improving the overall quality and productivity of the SSFSW process for battery pack assembly in BEV.

    Download full text (pdf)
    fulltext
1 - 7 of 7
CiteExportLink to result list
Permanent 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