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Published in: The International Journal of Advanced Manufacturing Technology 1-4/2019

14-05-2019 | ORIGINAL ARTICLE

Effect of high-frequency micro-vibration on microstructure and properties of laser cladding aluminum coatings

Authors: Chonggui Li, Shuai Li, Ming Zeng, Shuai Sun, Feifei Wang, You Wang

Published in: The International Journal of Advanced Manufacturing Technology | Issue 1-4/2019

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Abstract

Successful fabrication of AlSiTiNi coatings has been achieved by laser cladding assisted by high-frequency micro-vibration. Under the high-frequency micro-vibration, the dendrites in the coating are fractured and fine structure is formed. A typical bimodal structure is found in the coatings. The bimodal structure could improve the comprehensive properties of the coatings. The partially melted particles are found to be embedded in the fully melted structure at the vibration frequency of 551 Hz. The XRD and EDS investigations show that the coatings mainly consist of FeAl and FeNi phase. The composition distribution of the coatings is uniform due to the intensified convection in the molten pool during laser cladding. The micro-hardness of the coatings shows that the highest hardness of the coating reaches 781 HV0.2 and the average hardness is 725.2 HV0.2 when the vibration frequency is 551 Hz. The friction coefficient of the coating increases slightly and the running-in period decreases. In addition, the friction coefficient is stable and the stable wear time is also prolonged. Moreover, the main wear form of the coating is abrasive wear with slight adhesive wear. The tearing layer of the grinding defect and the wear loss of the coatings fabricated under the high-frequency micro-vibration are both decreased.

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Literature
1.
go back to reference Zhang Z, Yu T, Kovacevic R (2017) Erosion and corrosion resistance of laser cladding 420 stainless steel reinforced with VC. Appl Surf Sci 410:225–240CrossRef Zhang Z, Yu T, Kovacevic R (2017) Erosion and corrosion resistance of laser cladding 420 stainless steel reinforced with VC. Appl Surf Sci 410:225–240CrossRef
2.
go back to reference Liu HM, Li MB, Qin XP, Huang S, Hong F (2019) Numerical simulation and experimental analysis of wide-beam laser cladding. Int J Adv Manuf Technol 100(1–4):237–249CrossRef Liu HM, Li MB, Qin XP, Huang S, Hong F (2019) Numerical simulation and experimental analysis of wide-beam laser cladding. Int J Adv Manuf Technol 100(1–4):237–249CrossRef
3.
go back to reference Tanigawa D, Abe N, Tsukamoto M, Hayashi Y, Yamazaki H, Tatsumi Y, Yoneyama M (2017) The effect of particle size on the heat affected zone during laser cladding of Ni–Cr–Si–B alloy on C45 carbon steel. Opt Lasers Eng 101:23–27CrossRef Tanigawa D, Abe N, Tsukamoto M, Hayashi Y, Yamazaki H, Tatsumi Y, Yoneyama M (2017) The effect of particle size on the heat affected zone during laser cladding of Ni–Cr–Si–B alloy on C45 carbon steel. Opt Lasers Eng 101:23–27CrossRef
4.
go back to reference Fotovvati B, Namdari N, Dehghanghadikolaei A (2019) On coating techniques for surface protection: a review. J Manuf Mater Process 3:28 Fotovvati B, Namdari N, Dehghanghadikolaei A (2019) On coating techniques for surface protection: a review. J Manuf Mater Process 3:28
5.
go back to reference Wang XQ, Keya T, Chou K (2016) Build height effect on the Inconel 718 parts fabricated by selective laser melting. Proc Manuf 5:1006–1017 Wang XQ, Keya T, Chou K (2016) Build height effect on the Inconel 718 parts fabricated by selective laser melting. Proc Manuf 5:1006–1017
6.
go back to reference Farahmand P, Liu S, Zhang Z, Kovacevic R (2014) Laser cladding assisted by induction heating of Ni–WC composite enhanced by nano-WC and La2O3. Ceram Int 40(10):15421–15438CrossRef Farahmand P, Liu S, Zhang Z, Kovacevic R (2014) Laser cladding assisted by induction heating of Ni–WC composite enhanced by nano-WC and La2O3. Ceram Int 40(10):15421–15438CrossRef
7.
go back to reference Xu L, Cao HJ, Liu HL, Zhang YB (2017) Study on laser cladding remanufacturing process with FeCrNiCu alloy powder for thin-wall impeller blade. Int J Adv Manuf Technol 90(5–8):1383–1392 Xu L, Cao HJ, Liu HL, Zhang YB (2017) Study on laser cladding remanufacturing process with FeCrNiCu alloy powder for thin-wall impeller blade. Int J Adv Manuf Technol 90(5–8):1383–1392
8.
go back to reference Riveiro A, Mejías A, Lusquicos F (2014) Laser cladding of aluminium on AISI 304 stainless steel with high-power diode lasers. Surf Coat Technol 253:214–220CrossRef Riveiro A, Mejías A, Lusquicos F (2014) Laser cladding of aluminium on AISI 304 stainless steel with high-power diode lasers. Surf Coat Technol 253:214–220CrossRef
9.
go back to reference Lewis SR, Fretwell-Smith S, Goodwin PS (2016) Improving rail wear and RCF performance using laser cladding. Wear 366–367:268–278CrossRef Lewis SR, Fretwell-Smith S, Goodwin PS (2016) Improving rail wear and RCF performance using laser cladding. Wear 366–367:268–278CrossRef
10.
go back to reference He X, Song RG, Kong DJ (2019) Microstructure and corrosion behaviour of laser-cladding Al-Ni-TiC-CeO2 composite coatings on S355 offshore steel. J Alloys Compd 770:771–783CrossRef He X, Song RG, Kong DJ (2019) Microstructure and corrosion behaviour of laser-cladding Al-Ni-TiC-CeO2 composite coatings on S355 offshore steel. J Alloys Compd 770:771–783CrossRef
11.
go back to reference Chi YM, Gu GC, Yu HJ, Chen CZ (2018) Laser surface alloying on aluminum and its alloys: a review. Opt Lasers Eng 100:23–37CrossRef Chi YM, Gu GC, Yu HJ, Chen CZ (2018) Laser surface alloying on aluminum and its alloys: a review. Opt Lasers Eng 100:23–37CrossRef
12.
go back to reference Liu JL, Yua HJ, Chen CZ, Weng F, Optic DJJ (2017) Research and development status of laser cladding on magnesium alloys: a review. Laser Eng 93:195–210CrossRef Liu JL, Yua HJ, Chen CZ, Weng F, Optic DJJ (2017) Research and development status of laser cladding on magnesium alloys: a review. Laser Eng 93:195–210CrossRef
13.
go back to reference Emamian A, Corbin SF, Khajepour A (2010) Effect of laser cladding process parameters on clad quality and in-situ formed microstructure of Fe-TiC composite coatings. Surf Coat Technol 205:2007–2015CrossRef Emamian A, Corbin SF, Khajepour A (2010) Effect of laser cladding process parameters on clad quality and in-situ formed microstructure of Fe-TiC composite coatings. Surf Coat Technol 205:2007–2015CrossRef
14.
go back to reference Calleja A, Urbikain G, González H, Cerrillo I, Polvorosa R, Lamikiz A (2018) Inconel®718 superalloy machinability evaluation after laser cladding additive manufacturing process. Int J Adv Manuf Technol 97(5–8):2873–2885CrossRef Calleja A, Urbikain G, González H, Cerrillo I, Polvorosa R, Lamikiz A (2018) Inconel®718 superalloy machinability evaluation after laser cladding additive manufacturing process. Int J Adv Manuf Technol 97(5–8):2873–2885CrossRef
15.
go back to reference Riveiro A, Mejías A, Lusquinos F, DelVal J, Comesaña R, Pardo J, Pou J (2014) Laser cladding of aluminum on AISI 304 stainless steel with high-power diode lasers. Surf Coat Technol 253:214–220CrossRef Riveiro A, Mejías A, Lusquinos F, DelVal J, Comesaña R, Pardo J, Pou J (2014) Laser cladding of aluminum on AISI 304 stainless steel with high-power diode lasers. Surf Coat Technol 253:214–220CrossRef
16.
go back to reference Liu K, Li YJ, Wang J (2016) In-situ reactive fabrication and effect of phosphorus on microstructure evolution of Ni/Ni-Al intermetallic composite coating by laser cladding. Mater Des 105:171–178CrossRef Liu K, Li YJ, Wang J (2016) In-situ reactive fabrication and effect of phosphorus on microstructure evolution of Ni/Ni-Al intermetallic composite coating by laser cladding. Mater Des 105:171–178CrossRef
17.
go back to reference Zhang JF, Deng CM, Song JB (2013) MoB–CoCr as alternatives to WC–12Co for stainless steel protective coating and its corrosion behavior in molten zinc. Surf Coat Technol 235:811–818CrossRef Zhang JF, Deng CM, Song JB (2013) MoB–CoCr as alternatives to WC–12Co for stainless steel protective coating and its corrosion behavior in molten zinc. Surf Coat Technol 235:811–818CrossRef
18.
go back to reference Wang XH, Zhang M, Du BS (2013) Fabrication of multiple ceramic particle reinforced iron matrix coating by laser cladding. Mater Manuf Process 28(5):509–513CrossRef Wang XH, Zhang M, Du BS (2013) Fabrication of multiple ceramic particle reinforced iron matrix coating by laser cladding. Mater Manuf Process 28(5):509–513CrossRef
19.
go back to reference Bai LL, Li J, Chen JL, Song R, Shao JZ (2016) Effect of the content of B4C on microstructural evolution and wear behaviors of the laser-clad coatings fabricated on Ti6Al4V. Opt Laser Technol 76:33–45CrossRef Bai LL, Li J, Chen JL, Song R, Shao JZ (2016) Effect of the content of B4C on microstructural evolution and wear behaviors of the laser-clad coatings fabricated on Ti6Al4V. Opt Laser Technol 76:33–45CrossRef
20.
go back to reference Zhang HX, Yu HJ, Chen CZ (2015) In-situ forming composite coating by laser cladding C/B4C. Mater Manuf Process 30(6):743–747CrossRef Zhang HX, Yu HJ, Chen CZ (2015) In-situ forming composite coating by laser cladding C/B4C. Mater Manuf Process 30(6):743–747CrossRef
21.
go back to reference Weng F, Chen C, Yu H (2014) Research status of laser cladding on titanium and its alloys: a review. Mater Des 58:412–425CrossRef Weng F, Chen C, Yu H (2014) Research status of laser cladding on titanium and its alloys: a review. Mater Des 58:412–425CrossRef
22.
go back to reference Fotovvati B, Wayne SF, Lewis G, Asadi E (2018) A review on melt-pool characteristics in laser welding of metals. Adv Mater Sci Eng 2018: 4920718 Fotovvati B, Wayne SF, Lewis G, Asadi E (2018) A review on melt-pool characteristics in laser welding of metals. Adv Mater Sci Eng 2018: 4920718
23.
go back to reference Cheng YH, Cui R, Wang HZ, Han ZT (2018) Effect of processing parameters of laser on microstructure and properties of cladding 42CrMo steel. Int J Adv Manuf Technol 96:1715–1724CrossRef Cheng YH, Cui R, Wang HZ, Han ZT (2018) Effect of processing parameters of laser on microstructure and properties of cladding 42CrMo steel. Int J Adv Manuf Technol 96:1715–1724CrossRef
24.
go back to reference Chen SL, Hsu LL (1998) In-process vibration-assisted high power Nd:YAG pulsed laser ceramic–metal composite cladding on Al-alloys. Opt Laser Technol 30:263–273CrossRef Chen SL, Hsu LL (1998) In-process vibration-assisted high power Nd:YAG pulsed laser ceramic–metal composite cladding on Al-alloys. Opt Laser Technol 30:263–273CrossRef
25.
go back to reference Zhang N, Liu WW, Deng DW, Tang ZJ, Liu XY, Yan ZR, Zhang HC (2018) Effect of electric-magnetic compound field on the pore distribution in laser cladding process. Opt Laser Technol 108:247–254CrossRef Zhang N, Liu WW, Deng DW, Tang ZJ, Liu XY, Yan ZR, Zhang HC (2018) Effect of electric-magnetic compound field on the pore distribution in laser cladding process. Opt Laser Technol 108:247–254CrossRef
26.
go back to reference Liu HX, Xu Q, Wang CQ, Zhang XW (2015) Corrosion and wear behavior of Ni60CuMoW coatings fabricated by combination of laser cladding and mechanical vibration processing. J Alloys Compd 621:357–363CrossRef Liu HX, Xu Q, Wang CQ, Zhang XW (2015) Corrosion and wear behavior of Ni60CuMoW coatings fabricated by combination of laser cladding and mechanical vibration processing. J Alloys Compd 621:357–363CrossRef
27.
go back to reference Foroozmehr E, Lin DC, Kovacevic R (2009) Application of vibration in the laser powder deposition process. J Manuf Process 11:38–44CrossRef Foroozmehr E, Lin DC, Kovacevic R (2009) Application of vibration in the laser powder deposition process. J Manuf Process 11:38–44CrossRef
28.
go back to reference Li MY, Han B, Wang Y, Song LX, Guo LY (2016) Investigation on laser cladding high-hardness nano-ceramic coating assisted by ultrasonic vibration processing. Optik 127:4596–4600CrossRef Li MY, Han B, Wang Y, Song LX, Guo LY (2016) Investigation on laser cladding high-hardness nano-ceramic coating assisted by ultrasonic vibration processing. Optik 127:4596–4600CrossRef
29.
go back to reference Zhai LL, Ban CY, Zhang JW (2019) Microstructure, microhardness and corrosion resistance of NiCrBSi coatings under electromagnetic field auxiliary laser cladding. Surf Coat Technol 358:531–538CrossRef Zhai LL, Ban CY, Zhang JW (2019) Microstructure, microhardness and corrosion resistance of NiCrBSi coatings under electromagnetic field auxiliary laser cladding. Surf Coat Technol 358:531–538CrossRef
30.
go back to reference Li S, Li CG, Deng PR, Zhang YF, Zhang QS, Sun S, Yan H, Ma P, Wang Y (2018) Microstructure and properties of laser-cladded bimodal composite coatings derived by composition design. J Alloys Compd 745:483–489CrossRef Li S, Li CG, Deng PR, Zhang YF, Zhang QS, Sun S, Yan H, Ma P, Wang Y (2018) Microstructure and properties of laser-cladded bimodal composite coatings derived by composition design. J Alloys Compd 745:483–489CrossRef
Metadata
Title
Effect of high-frequency micro-vibration on microstructure and properties of laser cladding aluminum coatings
Authors
Chonggui Li
Shuai Li
Ming Zeng
Shuai Sun
Feifei Wang
You Wang
Publication date
14-05-2019
Publisher
Springer London
Published in
The International Journal of Advanced Manufacturing Technology / Issue 1-4/2019
Print ISSN: 0268-3768
Electronic ISSN: 1433-3015
DOI
https://doi.org/10.1007/s00170-019-03783-2

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