Jak wyszukiwać?
wyszukiwanie zaawansowane

Obiekt

Experimental study of the temperature distribution and microstructure of plunge stage in friction stir welding process by the tool with triangle pin

Pobierz

Tytuł: Experimental study of the temperature distribution and microstructure of plunge stage in friction stir welding process by the tool with triangle pin

Autorzy:

Bisadi, Hossain ; Rasaee, Sajad ; Farahmand, Mohammad

Data:

2014

Typ:

Artykuły / Articles

Tytuł czasopisma:

Archive of Mechanical Engineering

Rocznik:

2014

Wolumin:

vol. 61

Numer:

No 3

Zakres:

483-493

Opis:

Archive of Mechanical Engineering is an international journal publishing works of wide significance, originality and relevance in most branches of mechanical engineering. The journal is peer-reviewed and is published both in electronic and printed form. Archive of Mechanical Engineering publishes original papers which have not been previously published in other journal, and are not being prepared for publication elsewhere.

Archive of Mechanical Engineering is an Open Access journal. The journal does not have article processing charges (APCs) nor article submission charges.

Original papers on the following topics are preferred:

  • Mechanics of Solids and Structures,
  • Fluid Dynamics,
  • Thermodynamics, Heat Transfer and Combustion,
  • Machine Design,
  • Computational Methods in Mechanical Engineering,
  • Robotics, Automation and Control,
  • Mechatronics and Micro-mechanical Systems,
  • Aeronautics and Aerospace Engineering,
  • Heat and Power Engineering.

All submissions to the AME should be made electronically via Editorial System - an online submission and peer review system at: https://www.editorialsystem.com/ame
More detailed instructions for Authors can be found there.

IMPACT FACTOR 2022: 0.7

CiteScore 2021: 1.7
SCImago Journal Rank ( SJR) 2021: 0.22
Source Normalized Impact per Paper ( SNIP) 2021: 0.69


Abstrakt:

Considering the developing role of the friction stir welding in manufacturing industry, a complete study on the process is necessary. Studies on each stage of the process in particular, provide a better understanding of friction stir welding, and specially friction stir spot welding. In this study, plunge stage has been studied by experimental methods for investigating the temperature distribution around the tool during the plunge stage and microstructure changes of the workpiece. Experiments were performed on aluminium 7050 plates with coincident measurement of temperature. In the study, the tool which has a triangle pin is used. The results of this study are used as initial conditions for theoretical analysis of welding process. The results show that the temperature distribution around the tool is quite asymmetric. The asymmetric distribution of temperature is due to nonuniform load distribution underneath the tool and tilt angle of it. The temperatures of the points behind the tool are higher compared with points located forward the tool. Microstructural studies showed that four regions with different microstructures are formed around the tool during the process. These areas were separated based on differences in grain size and elongations. Grains near the tool are elongated in a particular direction that show the material flow direction.

Kontakt:

ARCHIVE OF MECHANICAL ENGINEERING

Editorial Office:

Institute of Aeronautics and Applied Mechanics, Warsaw University of Technology

Nowowiejska 24, Room 132, 00-665 Warsaw, Poland

Phone:  (+48) 22 234 7448, fax: (+48) 22 628 25 87,

E-mail: ame.eo@meil.pw.edu.pl

https://www.editorialsystem.com/ame

https://journals.pan.pl/ame

Redaktorzy:

Editor-in-Chief

Prof. Marek Wojtyra, Warsaw University of Technology, Poland

 

Editorial Board

Prof. Janusz T. Cieśliński, Gdańsk University of Technology, Poland

Prof. Antonio Delgado, LSTM University of Erlangen-Nuremberg, Germany

Prof. Peter Eberhard, University of Stuttgart, Germany

Prof. Krzysztof Fidkowski, University of Michigan, United States

Prof. Janusz Frączek, Warsaw University of Technology, Poland

Prof. Zbigniew Kowalewski, Institute of Fundamental Technological Research, Polish Academy of Sciences, Poland

Prof. Maciej Marek, Czestochowa University of Technology, Poland

Prof. Zenon Mróz, Institute of Fundamental Technological Research, Polish Academy of Sciences, Poland

Dr. Andrzej F. Nowakowski, The University of Sheffield, United Kingdom

Prof. Tomasz Wiśniewski, Warsaw University of Technology, Poland

Prof. Günter Wozniak, Chemnitz University of Technology, Germany

 

Assistant to the Editor

Małgorzata Broszkiewicz, Warsaw University of Technology, Poland

 

Editorial Advisory Board

Prof. Alberto Carpinteri, Politecnico di Torino, Italy

Prof. Feng Gao, Shanghai Jiao Tong University, P.R. China

Prof. Jerzy Maciej Floryan, The University of Western Ontario, Canada

Prof. Emmanuel E. Gdoutos, Democritus University of Thrace, Greece

Prof. Gregory Glinka, University of Waterloo, Ontario, Canada

Prof. Andrius Marcinkevicius, Vilnius Gedeminas Technical University, Lithuania

Prof. Manuel José Moreira De Freitas, Instituto Superior Tecnico, Portugal

Prof. Andrzej Neimitz, Kielce University of Technology, Poland

Prof. Thierry Palin-Luc, Arts et Métiers ParisTech, Institut Carnot Arts, France

Prof. Andre Pineau, Centre des Matériaux, Ecole des Mines de Paris, France

Prof. Narayanaswami Ranganathan, LMR, Ecole Polytechnique de l'Université de Tours, France

Prof. Andrzej J. Nowak, Silesian University of Technology, Poland

Prof. Jerzy Sąsiadek, Carleton University, Canada

Prof. Adelia Sequeira, Technical University of Lisbon, Portugal,

Prof. Jacek Szumbarski, Warsaw University of Technology, Poland

Prof. Edmund Wittbrodt, Gdańsk University of Technology, Poland

Prof. Jens Wittenburg, Karlsruhe Institute of Technology, Germany

Prof. Stanisław Wojciech, University of Bielsko-Biała, Poland

 

Language Editor

Lech Śliwa, Institute of Physiology and Pathology of Hearing, Warsaw, Poland

  

Instrukcja dla autorów:

About the Journal
Archive of Mechanical Engineering is an international journal publishing works of wide significance, originality and relevance in most branches of mechanical engineering. The journal is peer-reviewed and is published both in electronic and printed form. Archive of Mechanical Engineering publishes original papers which have not been previously published in other journal, and are not being prepared for publication elsewhere. The publisher will not be held legally responsible should there be any claims for compensation. The journal accepts papers in English.

Archive of Mechanical Engineering is an Open Access journal. The journal does not have article processing charges (APCs) nor article submission charges.

Original high quality papers on the following topics are preferred:

  • Mechanics of Solids and Structures,
  • Fluid Dynamics,
  • Thermodynamics, Heat Transfer and Combustion,
  • Machine Design,
  • Computational Methods in Mechanical Engineering,
  • Robotics, Automation and Control,
  • Mechatronics and Micro-mechanical Systems,
  • Aeronautics and Aerospace Engineering,
  • Heat and Power Engineering.

All submissions to the AME should be made electronically via Editorial System - an online submission and peer review system at: https://www.editorialsystem.com/ame

More detailed instructions for Authors can be found there.

Open Access:

Archive of Mechanical Engineering jest czasopismem wydawanym w wolnym dostępie na licencji CC BY 4.0. <a href=" https://creativecommons.org/licenses/by/4.0/"> https://creativecommons.org/licenses/by/4.0/</a></p>Archive of Mechanical Engineering is an open access journal with all content available with no charge in full text version. The journal content is available under the licencse CC BY 4.0 <a href=" https://creativecommons.org/licenses/by/4.0/"> https://creativecommons.org/licenses/by/4.0/</a>.

Wydawca:

Polish Academy of Sciences, Committee on Machine Building

Identyfikator:

oai:journals.pan.pl:84917 ; DOI: 10.2478/meceng-2014-0028 ; ISSN 0004-0738, e-ISSN 2300-1895

Źródło:

Archive of Mechanical Engineering; 2014; vol. 61; No 3; 483-493

Polityka Open Access:

Archive of Mechanical Engineering is an open access journal with all content available with no charge in full text version.


The journal content is available under the license CC BY 4.0 https://creativecommons.org/licenses/by/4.0/.

Temat i słowa kluczowe:

friction stir welding plunge stage triangle pin temperature distribution Nauki Techniczne

Kolekcje, do których przypisany jest obiekt:

Data ostatniej modyfikacji:

16 gru 2025

Data dodania obiektu:

9 lut 2017

Liczba wyświetleń treści obiektu:

$number.toString().replaceAll("[0-9](?=(?:[0-9]{3})+(?![0-9]))", "$0 ")

Wszystkie dostępne wersje tego obiektu:

https://journals.pan.pl/publication/98480

Wyświetl opis w formacie RDF:

RDF

Wyświetl opis w formacie OAI-PMH:

OAI-PMH

Nazwa wydania Data
Experimental Study of the Temperature Distribution and Microstructure of Plunge Stage in Friction Stir Welding Process by the Tool with Triangle Pin 16 gru 2025

Obiekty

Podobne

Examinations of steel overlap joints obtained using the friction stir welding technology

W. Więckowski P. Lacki J. Adamus
Archives of Metallurgy and Materials | 2019 | vol. 64 | No 1 | 393-399 | DOI: 10.24425/amm.2019.126265
Słowa kluczowe friction stir welding FSW 1.4541 steel
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

The aim of the study was to analyse mechanical properties and microstructure of joints obtained using friction stir welding (FSW) technology. The focus of the study was on overlap linear FSW joints made of 1.4541 DIN 17441 steel sheets with thickness of 1.2 mm. Tools used during friction stir welding of steel joints were made of W-Re alloy. The joints were subjected to visual inspection and their load bearing capacity was evaluated by means of the tensile strength test with analysis of joint breaking mechanism. Furthermore, the joints were also tested during metallographic examinations. The analysis performed in the study revealed that all the samples of the FSW joints were broken outside the joint area in the base material of the upper sheet metal, which confirms its high tensile strength. Mean load capacity of the joints was 15.8 kN. Macroscopic and microscopic examinations of the joints did not reveal significant defects on the joint surface and in the cross-sections.
Przejdź do artykułu

Autorzy i Afiliacje

W. Więckowski
P. Lacki
J. Adamus

Numerical Simulations for Bobbin Tool Friction Stir Welding of Aluminum 6082-T6

C. Hamilton S. Dymek A. Węglowska A. Pietras
Archives of Metallurgy and Materials | 2018 | vol. 63 | No 3 | 1115-1123 | DOI: 10.24425/123784
Słowa kluczowe friction stir welding bobbin tool aluminum simulation temperature
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

Aluminum 6082-T6 panels were joined by friction stir welding utilizing a bobbin tool. A thermal simulation of the process was developed based upon machine torque and the temperature dependent yield stress utilizing a slip factor and an assumed coefficient of friction. The torque-based approach was compared to another simulation established on the shear layer methodology (SLM), which does not require the slip factor or coefficient of friction as model inputs. The SLM simulation, however, only models heat generation from the leading edges of the tool. Ultimately, the two approaches yielded matching temperature predictions as both methodologies predicted the same overall total heat generation from the tool. A modified shear layer approach is proposed that adopts the flexibility and convenience of the shear layer method, yet models heat generation from all tool/workpiece interfaces.
Przejdź do artykułu

Autorzy i Afiliacje

C. Hamilton
S. Dymek
A. Węglowska
A. Pietras

EFFECT OF PROCESS PARAMETERS ON MICROSTRUCTURE AND MECHANICAL PROPERTIES OF RFSSW LAP JOINTS OF THIN AL7075-T6 SHEETS

J. Andres A. Wrońska T. Gałaszczyński G. Luty R. Burek
Archives of Metallurgy and Materials | 2018 | vol. 63 | No 1 | DOI: 10.24425/118906
Słowa kluczowe refill friction stir welding lap joining aerostructures aluminum alloy alclad
Pobierz PDF Pobierz RIS Pobierz Bibtex

Autorzy i Afiliacje

J. Andres
A. Wrońska
T. Gałaszczyński
G. Luty
R. Burek

The numerical simulation of aviation structure joined by FSW

P. Lacki K. Adamus J. Winowiecka
Archives of Metallurgy and Materials | 2019 | vol. 64 | No 1 | 387-392 | DOI: 10.24425/amm.2019.126264
Słowa kluczowe Aviation structure friction stir welding FSW thermomechanical simulations FEM
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

This work presents a numerical simulation of aviation structure joined by friction stir welding, FSW, process. The numerical simulation of aviation structure joined by FSW was created. The simulation uses thermomechanical coupled formulation. Th model required creation of finite elements representing sheets, stiffeners and welds, definition of material models and boundary conditions. The thermal model took into account heat conduction and convection assigned to appropriate elements of the structure. Time functions were applied to the description of a heat source movement. The numerical model included the stage of welding and the stage of releasing clamps. The output of the simulation are residual stresses and deformations occurring in the panel. Parameters of the global model (the panel model) were selected based on the local model (the single joint model), the experimental verification of the local model using the single joint and the geometry of the panel joints.
Przejdź do artykułu

Autorzy i Afiliacje

P. Lacki
K. Adamus
J. Winowiecka

The investigation of suitable welding parameters in polypropylene sheets joined with friction stir welding

İ. Küçükrendeci
Bulletin of the Polish Academy of Sciences Technical Sciences | 2019 | 67 | No. 1 | 133-140 | DOI: 10.24425/bpas.2019.127342
Słowa kluczowe friction stir welding polypropylene sheets Charpy impact test Shore hardness
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

Welding strength is very important in safe use of polypropylene sheets. The determination of welding parameters and design of the welding tool has an impact on the weld strength. The welding parameters can be determined experimentally. In this study, Charpy impact test is used to determine suitable welding parameters in welding of polypropylene sheets with FSW method. At the same time, the weld zone microstructure is examined and Shore hardness measurements are made. The impact tests were performed on samples cut from the welded sheets. The impact tests values and hardness values were presented graphically. According to the test results, some welded parts behaved similar to the matrix material. In some welding parameters, Charpy impact test values were obtained close to values of the main materials. The suitable welding parameters were determined for polypropylene sheets welding.
Przejdź do artykułu

Autorzy i Afiliacje

İ. Küçükrendeci

Research on the post-weld explosive hardening of AA7075-T651 friction stir welded butt joints

Robert Kosturek Rafał Lewczuk Janusz Torzewski Marcin Wachowski Piotr Słabik Andrzej Maranda
Bulletin of the Polish Academy of Sciences Technical Sciences | 2023 | 71 | 4 | e145685 | DOI: 10.24425/bpasts.2023.145685
Słowa kluczowe aluminum friction stir welding explosives mechanical properties post-weld treatment
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

In this paper, the post-weld explosive hardening of a 5 mm AA7075-T651 plate welded via FSW was performed. To investigate the possibility of increasing FSW joint mechanical properties, the welded plate was explosively treated with four various explosive materials (ammonal, emulsion explosive, FOX-7, and PBX) in two different hardening systems. As part of the investigation, the observations of the surface and macrostructure of the treated plates were described. The obtained microhardness distribution allowed us to register the increase in hardness of the SZ up to 6%, but no increase in hardness of the LHZ was reported. In most cases, the influence of explosive treatment on the mechanical properties of the welded joint was disadvantageous as ultimate tensile strength and ductility were reduced. The only positive effect which was observed is the increase in the value of yield strength up to 27% corresponding to 77 MPa, achieved by explosive materials with detonation velocity below 3000 m/s.
Przejdź do artykułu

Autorzy i Afiliacje

Robert Kosturek
1
ORCID: ORCID
Rafał Lewczuk
2
Janusz Torzewski
1
Marcin Wachowski
1
ORCID: ORCID
Piotr Słabik
2
Andrzej Maranda
2
  1. Faculty of Mechanical Engineering, Military University of Technology, 2 gen. S. Kaliskiego St., Warsaw, Poland
  2. Łukasiewicz Research Network – Institute of Industrial Organic Chemistry, 6 Annopol St., Warsaw, Poland

Optimization of process parameters of friction stir welded AA5082-AA7075 butt joints using resonance fatigue properties

Gaurav Kumar Rajeev Kumar Ratnesh Kumar
Bulletin of the Polish Academy of Sciences Technical Sciences | 2020 | 68 | No. 1 | 99-108 | DOI: 10.24425/bpasts.2020.131830
Słowa kluczowe friction stir welding Dissimilar Al Welding Resonance Fatigue Analysis Fracture Surface Analysis ANOVA
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

In this work, experiments were carried out to quantify the behaviour of friction stir welded (FSW) AA5082-AA7075 butt joints under tensile loading and completely reversed fatigue loading. Different samples were prepared to identify optimum tool rotational and travel speeds to produce FSW AA5082-AA7075 butt joints with the maximum fatigue life. ANOVA was performed, which confirmed that both tool speed and tool rotational speed affect the tensile strength of the weld. The samples exhibit a considerable difference in their fatigue life and tensile strength. This difference can be accounted to the presence of welding defects such as surface defects and porosity. S-N curve plotted for the sample shows a significantly high fatigue life at the lower stress ranges. Fracture surfaces were also analysed under scanning electron microscope (SEM). Study of the fracture surface of the sample that failed under fatigue loading showed that the surface was mainly divided in two zones. The first zone was the area of fatigue crack growth where each stress cycle, slowly and gradually, helped in the growth of the crack. The second zone was the region of fast fracture where the crack growth resulted in the failure of the joint instantaneously. The fracture surface study of the sample that failed under tensile loading showed that the mode of failure was ductile in nature.
Przejdź do artykułu

Autorzy i Afiliacje

Gaurav Kumar
Rajeev Kumar
Ratnesh Kumar

Computed Tomography and Scanning Electron Microscopy Analysis of a Friction Stir Welded Al-Cu Joint

Wojciech P. Depczyński Damian Bańkowski Piotr S. Młynarczyk
Archives of Foundry Engineering | 2023 | vol. 23 | No 4 | 65-71 | DOI: 10.24425/afe.2023.146680
Słowa kluczowe friction stir welding Non-destructive testing Radiographic inspection Computed tomography
Pobierz PDF Pobierz RIS Pobierz Bibtex

Abstrakt

The study aimed touse3D computed tomography (CT) to analyse a joint between two dissimilar materials produced by friction stir welding (FSW). As the materials joined, i.e., aluminum and copper, differ in properties (e.g., density and melting point), the weld is predicted to have an inhomogeneous microstructure. The investigations involved applying microfocus computed tomography (micro-CT) to visualize and analyze the volumetric structure of the joint. Volume rendering is extremely useful because, unlike computer modelling, which requires many simplifications, it helps create highly accurate representations of objects. Image segmentation into regions was performed through global gray-scale thresholding. The analysis also included elemental mapping of the weld cross-sections using scanning electron microscopy (SEM) and examination of its surface morphology by means of optical microscopy (OP). The joint finds its use in developing elements used in the chemical, energetics and aerospace industries, due to the excellent possibilities of combining many different properties, and above all, reducing the weight of the structure.
Przejdź do artykułu

Bibliografia

[1] Zhao, Y., You, J., Qin, J., Dong, C., Liu, L., Liu, Z. & Miao, S. (2022). Stationary shoulder friction stir welding of Al–Cu dissimilar materials and its mechanism for improving the microstructures and mechanical properties of joint. Materials Science & Engineering A 837, 142754. https://doi.org/10.1016/j.msea.2022.142754. [2] Zhou, L., Li, G.H., Zhang, R.X., Zhou, W.L., He, W.X., Huang, Y.X. & Song, X.G. (2019). Microstructure evolution and mechanical properties of friction stir spot welded dissimilar aluminum-copper joint. Journal of Alloys and Compounds. 775(15), 372-382. https://doi.org/10.1016/ j.jallcom.2018.10.045. [3] Tong, L., Xie, J.N., Liu, L., Chang, G. & Ojo, O.O. (2020). Microscopic appraisal and mechanical behavior of hybrid Cu/Al joints fabricated via friction stir spot welding-brazing and modified friction stir clinching-brazing. Journal of Materials Research and Technology. 9(6),13239-13249. https://doi.org/10.1016/j.jmrt.2020.09.042. [4] Tian, W.H., Su, H. & Wu, C.S. (2020). Effect of ultrasonic vibration on thermal and material flow behavior, microstructure and mechanical properties of friction stir welded al/cu joints. International Journal of Advanced Manufacturing Technology. 107(1), 59-71. https://doi.org/10.1007/s00170-020-05019-0. [5] Pilarczyk, J. (2005). Engineer's Handbook 2, Welding. Warszawa: Wydawnictwo Naukowo-Techniczne. (in Polish). [6] Rajak, D.K., Pagar, D.D., Menezes, P.L. & Eyvazian, A. (2020). Friction-based welding processes: friction welding and friction stir welding. Journal of Adhesion Science and Technology. 34(24), 2613-2637. https://doi.org/10.1080/ 01694243.2020.1780716. [7] Schneider, J., Chen, P. & Nunes, A.C. (2019). Entrapped oxide formation in the friction stir weld (FSW) process. Metallurgical and Materials Transactions A, 50, 257-270 https://doi.org/10.1007/s11661-018-4974-8. [8] Rams, B., Pietras, A., & Mroczka K. (2014). Friction stir welding of elements made of cast aluminium alloys. Archives of Foundry Engineering. 59(1), 385-392. [9] Martinsen, K., Hu, S.J. & Carlson, B.E. (2015). Joining of dissimilar materials. CIRP Annals. 64(2), 679-699. https://doi.org/10.1016/j.cirp.2015.05.006. [10] Weman, K. (2011). Welding processes handbook. New York: Elsevier. [11] Singh, R., Kumar, R., Feo, L., et al. (2016). Friction welding of dissimilar plastic/polymer materials with metal powder reinforcement for engineering applications. Composites Part B: Engineering. 101, 77-86. https://doi.org/10.1016/ j.compositesb.2016.06.082. [12] Rajak, D.K., Pagar, D.D., Menezes, P.L., et al. (2019). Fiber-reinforced polymer composites: manufacturing, properties, and applications. Polymers. 11(10), 1667. https://doi.org/10.3390/polym11101667. [13] Lee, H.S., Lee, Y.R., Min, K.J. (2016). Effects of friction stir welding speed on AA2195 alloy. In: MATEC Web of Conferences. Vol. 45, France: EDP Sciences. [14] Ramnath, B.V., Subramanian, S.A., Rakesh, R. et al. (2018). A review on friction stir welding of aluminium metal matrix composites. In IOP Conference Series: Materials Science and Engineering. 8-9 March 2018. IOP Publishing; 012103. [15] Bankowski, D., Spadlo, S. (2017). Vibratory tumbling of elements made of Hardox400 steel. In 26th International Conference on Metallurgy and Materials (pp. 725-730). [16] Karrar, G., Galloway, A., Toumpis, A., Li, H.J. & Al-Badouc, F. (2020). Microstructural characterisation and mechanical properties of dissimilar aa5083-copper joints produced by friction stir welding. Journal of Materials Research and Technology. 9(5), 11968-11979. https://doi.org/10.1016/j.jmrt.2020.08.073. [17] Galvao, I., Loureiro, A. & Rodrigues, D.M. (2016). Critical review on friction stir welding of aluminium to copper. Science and Technology of Welding and Joining. 21(7), 523-546. https://doi.org/10.1080/13621718.2015.1118813. [18] Ouyang, J., Yarrapareddy, E. & Kovacevic, R. (2006). Microstructural evolution in the friction stir welded 6061 aluminum alloy (T6-temper condition) to copper. Journal of Materials Processing Technology. 172(1), 110-122. https://doi.org/10.1016/j.jmatprotec.2005.09.013. [19] Mehta, K.P. & Badheka, V.J. (2016). A review on dissimilar friction stir welding of copper to aluminum: process, properties, and variants. Materials and Manufacturing Processes. 31(3), 233-254. https://doi.org/10.1080/10426914.2015.1025971. [20] Cao, F.J., Li, J.P., Hou, W.T., Shen, Y.F., Ni, R. (2021). Microstructural evolution and mechanical properties of the friction stir welded Al Cu dissimilar joint enhanced by post-weld heat treatment. Materials Characterization. 174, 110998. https://doi.org/10.1016/j.matchar.2021.110998. [21] Hou, W.T., Shen, Z.K., Huda, N., Oheil, M., Shen, Y.F., Jahed, H. & Gerlich, A.P. (2021). Enhancing metallurgical and mechanical properties of friction stir butt welded joints of Al–Cu via cold sprayed Ni interlayer. Materials Science and Engineering: A. 809, 140992. https://doi.org/10.1016/j.msea.2021.140992. [22] Mao, Y., Ni, Y., Qin, X.D.P. & Li, F. (2020). Microstructural characterization and mechanical properties of micro friction stir welded dissimilar al/cu ultra-thin sheets. Journal of Manufacturing Processes. 60, 356-365. https://doi.org/10.1016/j.jmapro.2020.10.064. [23] Patel, N.P., Parlikar, P., Dhari, R.S., Mehta, K. & Pandya, M. (2019). Numerical modelling on cooling assisted friction stir welding of dissimilar Al-Cu joint. Journal of Manufacturing Processes. 47, 98-109. https://doi.org/10.1016/j.jmapro.2019.09.020. [24] Mehta, K.P. & Badheka, V.J. (2017). Hybrid approaches of assisted heating and cooling for friction stir welding of copper to aluminum joints. Journal of Materials Processing Technology. 239, 336-345. https://doi.org/10.1016/ j.jmatprotec.2016.08.037. [25] You, J.Q., Zhao, Y.Q., Dong, C.L., Wang, C.G., Miao, S., Yi, Y.Y. & Hai, Y.H. (2020). Microstructure characteristics and mechanical properties of stationary shoulder friction stir welded 2219-t6 aluminium alloy at high rotation speeds. The International Journal of Advanced Manufacturing Technology. 108, 987-996. https://doi.org/10.1007/s00170-019-04594-1. [26] Li, D.X., Yang, X.Q., Cui, L., He, F.Z. & Zhang, X. (2015). Investigation of stationary shoulder friction stir welding of aluminum alloy 7075-t651. Journal of Materials Processing Technology. 222, 391-398. https://doi.org/10.1016/ j.jmatprotec.2015.03.036. [27] Depczynski, W., Spadlo, S., Mlynarczyk, P., Ziach, E., Hepner P. (2015). The selected properties of porous layers formed by pulse microwelding technique. In METAL 2015: 24TH International Conference on Metallurgy and Materials, 3 - 5 June 2015 (pp.1087-1092). Brno, Czech Republic. [28] Bańkowski D. & Młynarczyk P. (2020). Visual testing of castings defects after vibratory machining. Archives of Foundry Engineering. 20(4), 72-76. DOI: 10.24425/afe.2020.133350. [29] Mlynarczyk, P., Spadlo, S. (2016). The analysis of the effects formation iron - tungsten carbide layer on aluminum alloy by electrical discharge alloying process. In METAL 2016: 25th Anniversary International Conference on Metallurgy and Materials, 25 – 27 May 2016 (pp.1109-1114). Brno, Czech Republic. [30] Depczynski, W. Jasionowski, R., Mlynarczyk, P. (2018). The impact of process variables on the connection parameters during pulse micro-welding of the H800 superalloy. In METAL 2018: 27TH International Conference on Metallurgy and Materials, 23 – 25 May 2018 (pp. 1506-1512). Brno, Czech Republic. [31] Bankowski, D. & Spadlo, S. (2019). The use of abrasive waterjet cutting to remove flash from castings. Archives of Foundry Engineering. 19(3), 94-98. DOI: 10.24425/afe.2019.129617. [32] Spadlo, S., Depczynski, W. & Mlynarczyk, P. (2017). Selected properties of high velocity oxy liquid fuel (HVOLF) - sprayed nanocrystalline WC-Co Infralloy(TM) S7412 coatings modified by high energy electric pulse. Metalurgija. 56(3-4), 412-414. [33] Bonarski, J.T., Kania, B., Bolanowski, K. & Karolczuk, A. (2015). Utility of stress-texture characteristics of structural materials by X-ray. Archives of Metallurgy and Materials. 60(3), 2247-2252. DOI: 10.1515/amm-2015-0370. [34] Jezierski, G. (1993). Industrial radiography. Warszawa: Wydawnictwa Naukowo-Techniczne. (in Polish). [35] Cierniak, R. (2005). Computed tomography. Construction of CT devices. Reconstruction algorithms. Warszawa: Akademicka Oficyna Wydawnicza EXIT. (in Polish). [36] Kielczyk, J. (2006). Industrial radiography. Wydawnictwo Gamma. (in Polish). [37] Ratajczak, E. (2012). X-ray computed tomography (CT) for industrial tasks. Pomiary Automatyka Robotyka. 5, 104-113. (in Polish). [38] Cullity, B.D. (1959). Elements of X-Ray diffraction. London: Addison-Wesley Publising Company. Inc. [39] Axon, H.J., Hume-Rothery, W. (1948). Proc. R. Soc. (London), Ser. A 193, 1. [40] Pearson, W.B. (1958).: ÑA Handbook of Lattice Spacings and Structures of Metals and Alloysì. Oxford: Pergamon Press.  
Przejdź do artykułu

Autorzy i Afiliacje

Wojciech P. Depczyński
1
ORCID: ORCID
Damian Bańkowski
1
ORCID: ORCID
Piotr S. Młynarczyk
1
ORCID: ORCID
  1. Radiography and Computed Tomography Laboratory, Department of Metal Science and Manufacturing Processes, Faculty of Mechatronics and Mechanical Engineering, Kielce University of Technology, al. Tysiąclecia Państwa Polskiego 7, 25-314 Kielce, Poland
Więcej
×

Cytowanie

Styl cytowania: [1] Zhao, Y., You, J., Qin, J., Dong, C., Liu, L., Liu, Z. & Miao, S. (2022). Stationary shoulder friction stir welding of Al–Cu dissimilar materials and its mechanism for improving the microstructures and mechanical properties of joint. Materials Science & Engineering A 837, 142754. https://doi.org/10.1016/j.msea.2022.142754. [2] Zhou, L., Li, G.H., Zhang, R.X., Zhou, W.L., He, W.X., Huang, Y.X. & Song, X.G. (2019). Microstructure evolution and mechanical properties of friction stir spot welded dissimilar aluminum-copper joint. Journal of Alloys and Compounds. 775(15), 372-382. https://doi.org/10.1016/ j.jallcom.2018.10.045. [3] Tong, L., Xie, J.N., Liu, L., Chang, G. & Ojo, O.O. (2020). Microscopic appraisal and mechanical behavior of hybrid Cu/Al joints fabricated via friction stir spot welding-brazing and modified friction stir clinching-brazing. Journal of Materials Research and Technology. 9(6),13239-13249. https://doi.org/10.1016/j.jmrt.2020.09.042. [4] Tian, W.H., Su, H. & Wu, C.S. (2020). Effect of ultrasonic vibration on thermal and material flow behavior, microstructure and mechanical properties of friction stir welded al/cu joints. International Journal of Advanced Manufacturing Technology. 107(1), 59-71. https://doi.org/10.1007/s00170-020-05019-0. [5] Pilarczyk, J. (2005). Engineer's Handbook 2, Welding. Warszawa: Wydawnictwo Naukowo-Techniczne. (in Polish). [6] Rajak, D.K., Pagar, D.D., Menezes, P.L. & Eyvazian, A. (2020). Friction-based welding processes: friction welding and friction stir welding. Journal of Adhesion Science and Technology. 34(24), 2613-2637. https://doi.org/10.1080/ 01694243.2020.1780716. [7] Schneider, J., Chen, P. & Nunes, A.C. (2019). Entrapped oxide formation in the friction stir weld (FSW) process. Metallurgical and Materials Transactions A, 50, 257-270 https://doi.org/10.1007/s11661-018-4974-8. [8] Rams, B., Pietras, A., & Mroczka K. (2014). Friction stir welding of elements made of cast aluminium alloys. Archives of Foundry Engineering. 59(1), 385-392. [9] Martinsen, K., Hu, S.J. & Carlson, B.E. (2015). Joining of dissimilar materials. CIRP Annals. 64(2), 679-699. https://doi.org/10.1016/j.cirp.2015.05.006. [10] Weman, K. (2011). Welding processes handbook. New York: Elsevier. [11] Singh, R., Kumar, R., Feo, L., et al. (2016). Friction welding of dissimilar plastic/polymer materials with metal powder reinforcement for engineering applications. Composites Part B: Engineering. 101, 77-86. https://doi.org/10.1016/ j.compositesb.2016.06.082. [12] Rajak, D.K., Pagar, D.D., Menezes, P.L., et al. (2019). Fiber-reinforced polymer composites: manufacturing, properties, and applications. Polymers. 11(10), 1667. https://doi.org/10.3390/polym11101667. [13] Lee, H.S., Lee, Y.R., Min, K.J. (2016). Effects of friction stir welding speed on AA2195 alloy. In: MATEC Web of Conferences. Vol. 45, France: EDP Sciences. [14] Ramnath, B.V., Subramanian, S.A., Rakesh, R. et al. (2018). A review on friction stir welding of aluminium metal matrix composites. In IOP Conference Series: Materials Science and Engineering. 8-9 March 2018. IOP Publishing; 012103. [15] Bankowski, D., Spadlo, S. (2017). Vibratory tumbling of elements made of Hardox400 steel. In 26th International Conference on Metallurgy and Materials (pp. 725-730). [16] Karrar, G., Galloway, A., Toumpis, A., Li, H.J. & Al-Badouc, F. (2020). Microstructural characterisation and mechanical properties of dissimilar aa5083-copper joints produced by friction stir welding. Journal of Materials Research and Technology. 9(5), 11968-11979. https://doi.org/10.1016/j.jmrt.2020.08.073. [17] Galvao, I., Loureiro, A. & Rodrigues, D.M. (2016). Critical review on friction stir welding of aluminium to copper. Science and Technology of Welding and Joining. 21(7), 523-546. https://doi.org/10.1080/13621718.2015.1118813. [18] Ouyang, J., Yarrapareddy, E. & Kovacevic, R. (2006). Microstructural evolution in the friction stir welded 6061 aluminum alloy (T6-temper condition) to copper. Journal of Materials Processing Technology. 172(1), 110-122. https://doi.org/10.1016/j.jmatprotec.2005.09.013. [19] Mehta, K.P. & Badheka, V.J. (2016). A review on dissimilar friction stir welding of copper to aluminum: process, properties, and variants. Materials and Manufacturing Processes. 31(3), 233-254. https://doi.org/10.1080/10426914.2015.1025971. [20] Cao, F.J., Li, J.P., Hou, W.T., Shen, Y.F., Ni, R. (2021). Microstructural evolution and mechanical properties of the friction stir welded Al Cu dissimilar joint enhanced by post-weld heat treatment. Materials Characterization. 174, 110998. https://doi.org/10.1016/j.matchar.2021.110998. [21] Hou, W.T., Shen, Z.K., Huda, N., Oheil, M., Shen, Y.F., Jahed, H. & Gerlich, A.P. (2021). Enhancing metallurgical and mechanical properties of friction stir butt welded joints of Al–Cu via cold sprayed Ni interlayer. Materials Science and Engineering: A. 809, 140992. https://doi.org/10.1016/j.msea.2021.140992. [22] Mao, Y., Ni, Y., Qin, X.D.P. & Li, F. (2020). Microstructural characterization and mechanical properties of micro friction stir welded dissimilar al/cu ultra-thin sheets. Journal of Manufacturing Processes. 60, 356-365. https://doi.org/10.1016/j.jmapro.2020.10.064. [23] Patel, N.P., Parlikar, P., Dhari, R.S., Mehta, K. & Pandya, M. (2019). Numerical modelling on cooling assisted friction stir welding of dissimilar Al-Cu joint. Journal of Manufacturing Processes. 47, 98-109. https://doi.org/10.1016/j.jmapro.2019.09.020. [24] Mehta, K.P. & Badheka, V.J. (2017). Hybrid approaches of assisted heating and cooling for friction stir welding of copper to aluminum joints. Journal of Materials Processing Technology. 239, 336-345. https://doi.org/10.1016/ j.jmatprotec.2016.08.037. [25] You, J.Q., Zhao, Y.Q., Dong, C.L., Wang, C.G., Miao, S., Yi, Y.Y. & Hai, Y.H. (2020). Microstructure characteristics and mechanical properties of stationary shoulder friction stir welded 2219-t6 aluminium alloy at high rotation speeds. The International Journal of Advanced Manufacturing Technology. 108, 987-996. https://doi.org/10.1007/s00170-019-04594-1. [26] Li, D.X., Yang, X.Q., Cui, L., He, F.Z. & Zhang, X. (2015). Investigation of stationary shoulder friction stir welding of aluminum alloy 7075-t651. Journal of Materials Processing Technology. 222, 391-398. https://doi.org/10.1016/ j.jmatprotec.2015.03.036. [27] Depczynski, W., Spadlo, S., Mlynarczyk, P., Ziach, E., Hepner P. (2015). The selected properties of porous layers formed by pulse microwelding technique. In METAL 2015: 24TH International Conference on Metallurgy and Materials, 3 - 5 June 2015 (pp.1087-1092). Brno, Czech Republic. [28] Bańkowski D. & Młynarczyk P. (2020). Visual testing of castings defects after vibratory machining. Archives of Foundry Engineering. 20(4), 72-76. DOI: 10.24425/afe.2020.133350. [29] Mlynarczyk, P., Spadlo, S. (2016). The analysis of the effects formation iron - tungsten carbide layer on aluminum alloy by electrical discharge alloying process. In METAL 2016: 25th Anniversary International Conference on Metallurgy and Materials, 25 – 27 May 2016 (pp.1109-1114). Brno, Czech Republic. [30] Depczynski, W. Jasionowski, R., Mlynarczyk, P. (2018). The impact of process variables on the connection parameters during pulse micro-welding of the H800 superalloy. In METAL 2018: 27TH International Conference on Metallurgy and Materials, 23 – 25 May 2018 (pp. 1506-1512). Brno, Czech Republic. [31] Bankowski, D. & Spadlo, S. (2019). The use of abrasive waterjet cutting to remove flash from castings. Archives of Foundry Engineering. 19(3), 94-98. DOI: 10.24425/afe.2019.129617. [32] Spadlo, S., Depczynski, W. & Mlynarczyk, P. (2017). Selected properties of high velocity oxy liquid fuel (HVOLF) - sprayed nanocrystalline WC-Co Infralloy(TM) S7412 coatings modified by high energy electric pulse. Metalurgija. 56(3-4), 412-414. [33] Bonarski, J.T., Kania, B., Bolanowski, K. & Karolczuk, A. (2015). Utility of stress-texture characteristics of structural materials by X-ray. Archives of Metallurgy and Materials. 60(3), 2247-2252. DOI: 10.1515/amm-2015-0370. [34] Jezierski, G. (1993). Industrial radiography. Warszawa: Wydawnictwa Naukowo-Techniczne. (in Polish). [35] Cierniak, R. (2005). Computed tomography. Construction of CT devices. Reconstruction algorithms. Warszawa: Akademicka Oficyna Wydawnicza EXIT. (in Polish). [36] Kielczyk, J. (2006). Industrial radiography. Wydawnictwo Gamma. (in Polish). [37] Ratajczak, E. (2012). X-ray computed tomography (CT) for industrial tasks. Pomiary Automatyka Robotyka. 5, 104-113. (in Polish). [38] Cullity, B.D. (1959). Elements of X-Ray diffraction. London: Addison-Wesley Publising Company. Inc. [39] Axon, H.J., Hume-Rothery, W. (1948). Proc. R. Soc. (London), Ser. A 193, 1. [40] Pearson, W.B. (1958).: ÑA Handbook of Lattice Spacings and Structures of Metals and Alloysì. Oxford: Pergamon Press.  

Ta strona wykorzystuje pliki 'cookies'. Więcej informacji