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The International Journal of Advanced Manufacturing Technology
Erschienen in: The International Journal of Advanced Manufacturing Technology 1-2/2020

17.02.2020 | ORIGINAL ARTICLE

Effect of tilt angle in FSW of polycarbonate sheets in butt configuration

verfasst von: F. Lambiase, V. Grossi, A. Paoletti

Erschienen in: The International Journal of Advanced Manufacturing Technology | Ausgabe 1-2/2020

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Abstract

The influence of the tilt angle on the quality of Friction Stir welds made on polycarbonate sheets is investigated, experimentally. Welding tests were conducted by varying the tilt angle and the welding speed to determine possible interactions between these process parameters. Temperature distribution, material flow, and processing loads were analyzed. The quality of the welds was assessed by means of mechanical characterization and morphological analysis. The results indicated that the processing loads and temperature increased when higher tilt angles were adopted. Under low welding speed (20 mm/s), this enabled to improve the mechanical behavior of the welds. On the other hand, high tilting involved different issues. The tensile strength of the welds was severely compromised as high tilting produced severe thinning of the weld seam. In addition, tilt angles higher than 2° involved great amount of material ejection. This material formed a coherent side flash, which required subsequent machining, and worsened the surface appearance of the welds.
Vorheriger Artikel A data-driven model for weld bead monitoring during the laser welding assisted by magnetic field
Nächster Artikel A review on vibration analysis and control of machine tool feed drive systems

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Literatur
1.
Troughton M (2008) Handbook of plastics joining: a practical guide. USA
2.
Katayama S (2013) Handbook of laser welding technologies. Woodhead Publishing
3.
Li P, Li J, Tan W, Liu H, Wang X (2018) Experimental study on the laser transmission joining of polystyrene and titanium. Materials (Basel) 11
4.
Jiao J, Jia S, Xu Z, Ye Y, Sheng L, Zhang W (2019) Laser direct joining of CFRTP and aluminium alloy with a hybrid surface pre-treating method. Compos Part B 173:106911CrossRef
5.
Yeh R-Y, Hsu R-Q (2016) Development of ultrasonic direct joining of thermoplastic to laser structured metal. Int J Adhes Adhes 65:28–32CrossRef
6.
Lionetto F, Balle F, Maffezzoli A (2017) Hybrid ultrasonic spot welding of aluminum to carbon fiber reinforced epoxy composites. J Mater Process Technol 247:289–295CrossRef
7.
Lionetto F, Mele C, Leo P, D’Ostuni S, Balle F, Maffezzoli A (2018) Ultrasonic spot welding of carbon fiber reinforced epoxy composites to aluminum: mechanical and electrochemical characterization. Compos Part B 144:134–142CrossRef
8.
Lambiase F, Genna S (2017) Laser-assisted direct joining of AISI304 stainless steel with polycarbonate sheets: thermal analysis, mechanical characterization, and bonds morphology. Opt Laser Technol 88:205–214CrossRef
9.
Lambiase F, Paoletti A, Di Ilio A (2018) Forces and temperature variation during friction stir welding of aluminum alloy AA6082-T6. Int J Adv Manuf Technol 99:337–346CrossRef
10.
Lambiase F, Paoletti A, Grossi V, Di Ilio A (2019) Analysis of loads, temperatures and welds morphology in FSW of polycarbonate. J Mater Process Technol 266:639–650CrossRef
11.
Eslami S, de Figueiredo MAV, Tavares PJ, Moreira PMGP (2017) Parameter optimisation of friction stir welded dissimilar polymers joints. Int J Adv Manuf Technol 94:1759–1770CrossRef
12.
Moreno-Moreno M, Macea Romero Y, Rodríguez Zambrano H, Restrepo-Zapata NC, Afonso CRM, Unfried-Silgado J (2018) Mechanical and thermal properties of friction-stir welded joints of high density polyethylene using a non-rotational shoulder tool. Int J Adv Manuf Technol 97:2489–2499CrossRef
13.
Mostafapour A, Taghizad Asad F (2016) Investigations on joining of Nylon 6 plates via novel method of heat assisted friction stir welding to find the optimum process parameters. Sci Technol Weld Join 21:660–669CrossRef
14.
Hoseinlaghab S, Mirjavadi SS, Sadeghian N, Jalili I, Azarbarmas M, Besharati Givi MK (2015) Influences of welding parameters on the quality and creep properties of friction stir welded polyethylene plates. Mater Des 67:369–378CrossRef
15.
Derazkola HA, Simchi A (2018) Experimental and thermomechanical analysis of the effect of tool pin profile on the friction stir welding of poly (methyl methacrylate) sheets. J Manuf Process 34:412–423CrossRef
16.
Sahu SK, Mishra D, Mahto RP, Sharma VM, Pal SK, Pal K, Banerjee S, Dash P (2018) Friction stir welding of polypropylene sheet. Eng Sci Technol Int J 21:245–254CrossRef
17.
Panneerselvam K, Lenin K (2014) Joining of Nylon 6 plate by friction stir welding process using threaded pin profile. Mater Des 53:302–307CrossRef
18.
Sheikh-Ahmad JY, Ali DS, Deveci S, Almaskari F, Jarrar F (2019) Friction stir welding of high density polyethylene—carbon black composite. J Mater Process Technol 264:402–413CrossRef
19.
Kumar R, Singh R, Ahuja IPS (2019) Friction stir welding of ABS-15Al sheets by introducing compatible semi-consumable shoulder-less pin of PA6-50Al. Measurement 131:461–472CrossRef
20.
Rezaee Hajideh M, Farahani M, Molla Ramezani N (2018) Reinforced dissimilar friction stir weld of polypropylene to acrylonitrile butadiene styrene with copper nanopowder. J Manuf Process 32:445–454CrossRef
21.
Gao J, Li C, Shilpakar U, Shen Y (2016) Microstructure and tensile properties of dissimilar submerged friction stir welds between HDPE and ABS sheets. Int J Adv Manuf Technol 87:919–927CrossRef
22.
Yan Y, Shen Y, Hou W, Li J (2018) Friction stir spot welding thin acrylonitrile butadiene styrene sheets using pinless tool. Int J Adv Manuf Technol 97:2749–2755CrossRef
23.
Moochani A, Omidvar H, Ghaffarian SR, Goushegir SM (2018) Friction stir welding of thermoplastics with a new heat-assisted tool design: mechanical properties and microstructure. Weld World 63:181–190CrossRef
24.
Banjare PN, Sahlot P, Arora A (2017) An assisted heating tool design for FSW of thermoplastics. J Mater Process Technol 239:83–91CrossRef
25.
Vijendra B, Sharma A (2015) Induction heated tool assisted friction-stir welding (i-FSW): a novel hybrid process for joining of thermoplastics. J Manuf Process 20:234–244CrossRef
26.
Aghajani Derazkola H, Simchi A (2017) Experimental and thermomechanical analysis of friction stir welding of poly(methyl methacrylate) sheets. Sci Technol Weld Join 23:209–218CrossRef
27.
Eslami S, Mourão L, Viriato N, Tavares PJ, Moreira PMGP (2018) Multi-axis force measurements of polymer friction stir welding. J Mater Process Technol 256:51–56CrossRef
28.
Lambiase F, Paoletti A, Di Ilio A (2016) Effect of tool geometry on loads developing in friction stir spot welds of polycarbonate sheets. Int J Adv Manuf Technol 87:2293–2303CrossRef
29.
Simões F, Rodrigues DM (2014) Material flow and thermo-mechanical conditions during friction stir welding of polymers: literature review, experimental results and empirical analysis. Mater Des 59:344–351CrossRef
30.
Mendes N, Loureiro A, Martins C, Neto P, Pires JN (2014) Effect of friction stir welding parameters on morphology and strength of acrylonitrile butadiene styrene plate welds. Mater Des 58:457–464CrossRef
31.
Mendes N, Loureiro A, Martins C, Neto P, Pires JN (2014) Morphology and strength of acrylonitrile butadiene styrene welds performed by robotic friction stir welding. Mater Des 64:81–90CrossRef
32.
Paoletti A, Lambiase F, Di Ilio A (2015) Optimization of friction stir welding of thermoplastics. Procedia CIRP 563–568
33.
Derazkola HA, Simchi A, Lambiase F (2019) Friction stir welding of polycarbonate lap joints: relationship between processing parameters and mechanical properties. Polym Test 79:105999CrossRef
34.
Paoletti A, Lambiase F, Di Ilio A (2016) Analysis of forces and temperatures in friction spot stir welding of thermoplastic polymers. Int J Adv Manuf Technol 83:1395–1407CrossRef
35.
Lambiase F, Paoletti A, Di Ilio A (2017) Effect of tool geometry on mechanical behavior of friction stir spot welds of polycarbonate sheets. Int J Adv Manuf Technol 88:3005–3016CrossRef
36.
Lambiase F, Paoletti A, Di Ilio A (2017) Friction spot stir welding of polymers: control of plunging force. Int J Adv Manuf Technol 90:2827–2837CrossRef
37.
Lambiase F, Paoletti A, Di Ilio A (2015) Mechanical behaviour of friction stir spot welds of polycarbonate sheets. Int J Adv Manuf Technol 80:301–314CrossRef
Metadaten
Titel
Effect of tilt angle in FSW of polycarbonate sheets in butt configuration
verfasst von
F. Lambiase
V. Grossi
A. Paoletti
Publikationsdatum
17.02.2020
Verlag
Springer London
Erschienen in
The International Journal of Advanced Manufacturing Technology / Ausgabe 1-2/2020
Print ISSN: 0268-3768
Elektronische ISSN: 1433-3015
DOI
https://doi.org/10.1007/s00170-020-05106-2

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