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Abstract

This study investigates the laser cladding (LC) of pure nickel onto AISI 410 stainless steel using a low-power pulsed diode laser. The process parameters included scanning speeds of 0.5–1.5 mm/s and average laser powers of 20–40 W, with a fixed pulse width of 110 ns and pulse frequency of 50 kHz. Microhardness, clad geometry, and microstructure at the clad-substrate interface were analyzed using optical microscopy, FE-SEM, and EDS. At 40 W, successful nickel deposition was achieved, demonstrating optimal metallurgical bonding. The clad depth decreased from 364.7 to 170.0 µm as the scanning speed increased, with the best microstructure and highest microhardness observed at 1 mm/s. A 3D finite element model was developed to complement the experimental findings and to gain a deeper understanding of the LC process, particularly in terms of temperature distribution, and the resulting clad geometry. The simulations revealed that increasing scanning speed significantly reduced the peak temperature, from 3121 K at 0.5 mm/s to 2445 K at 1.5 mm/s. The nickel deposition was unsuccessful at 20 and 30 W due to insufficient peak temperatures of 1468 and 1899 K, respectively. At 40 W, a peak temperature of 2879 K was achieved, aligning well with the experimental results and confirming the accuracy of the simulation in predicting the effects of processing parameters.

Keywords

Laser cladding numerical simulation pulse parameters clad depth microhardness

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References

Huang

Wang

, et al. An ideal ultrafine-grained structure for high strength and high ductility. Mater Res Lett 2015; 3: 88–94.

Shek

Lai

JKL

. Recent developments in stainless steels. Mater Sci Eng R Rep 2009; 65: 39–104.

Liang

Liu

Wang

Multi-pattern failure modes and wear mechanisms of WC-Co tools in dry turning Ti–6Al–4 V. Ceram Int, 2020;46:24512–24525.

Meng

Zeng

Hou

, et al. Effect of LC and laser-induction hybrid cladding coatings on the bending properties and fracture behavior of rails. Surf Coat Technol 2019; 374: 1038–1050.

Paydas

Mertens

Carrus

, et al. LC As repair technology for Ti–6Al–4 V alloy: Influence of building strategy on microstructure and hardness. Mater Des, 2015;85:497–510.

Davim

(ed.). Laser in manufacturing. John Wiley & Sons, Germany, March 2013.

Onwubolu

Davim

Oliveira

, et al. Prediction of clad angle in laser cladding by powder using response surface methodology and scatter search. Opt Laser Technol 2007; 39: 1130–1134.

Raj

Maity

Das

. State-of-the-art review on LC process as an in-situ repair technique. Proc Inst Mechan Eng E J Proc Mech Eng 2022; 236: 1194–1215.

Xiong

Lian

, et al. Modeling and optimization for LC via multi-objective quantum-behaved particle swarm optimization algorithm. Surf Coat Technol 2020; 381: 125129.

10.

Ferreiro

Larreina

Tena

, et al. Artificial intelligence methodology for smart and sustainable manufacturing industry. IFAC-Papers OnLine 2021; 54: 1041–1046.

11.

Peng

Zhao

, et al. Towards energy and material efficient laser cladding process: modeling and optimization using a hybrid TS-GEP algorithm and the NSGA-II. J Cleaner Prod 2019; 227: 58–69.

12.

Davim

. Sustainable and intelligent manufacturing: perceptions in line with 2030 agenda of sustainable development. BioResources 2024; 19: 4–5.

13.

Moradi

Ghorbani

Moghadam

, et al. Nd:YAG laser hardening of AISI 410 stainless steel: microstructural evaluation, mechanical properties, and corrosion behavior. J Alloys Compd 2019; 795: 213–222.

14.

Lai

Abrahams

Yan

, et al. Effects of preheating and carbon dilution on material characteristics of laser-cladded hypereutectoid rail steels. Mater Sci Eng A 2018; 712: 548–563.

15.

Wang

Zhang

Gong

, et al. Microstructures and corrosion resistance of Fe- based amorphous/nanocrystalline coating fabricated by LC. J Alloys Compd 2017; 728: 1116–1123.

16.

Zhang

Zou

, et al. Comparative study on continuous and pulsed wave fiber LC in-situ titanium–vanadium carbides reinforced Fe-based composite layer. Mater Lett 2015; 139: 255–257.

17.

Paul

Alemohammad

Toyserkani

, et al. Cladding of WC–12 Co on low carbon steel using a pulsed Nd:YAG laser. Mater Sci Eng A 2007; 464: 170–176.

18.

Sun

Durandet

Brandt

. Parametric investigation of pulsed Nd: YAG LC of stellite 6 on stainless steel. Surf Coat Technol 2005; 194: 225–231.

19.

Yan

Wang

Xiong

, et al. Microstructure and wear resistance of composite layers on a ductile iron with multicarbide by laser surface alloying. Appl Surf Sci 2010; 256: 7001–7009.

20.

Moradi

Karami Moghadam

Zarei

, et al. The effects of laser pulse energy and focal point position on laser surface hardening of AISI 410 stainless steel. Modares Mechan Eng 2017; 17: 311–318.

21.

Mahmoudi

Torkamany

Aghdam

ASR

, et al. Laser surface hardening of AISI 420 stainless steel treated by pulsed Nd: YAG laser. Mater Des (1980-2015) 2010; 31: 2553–2560.

22.

Wang

Deng

, et al. Influences of pulse laser parameters on properties of AISI316L stainless steel thin-walled part by laser material deposition. Opt Laser Technol 2017; 92: 5–14.

23.

Davim

Oliveira

Cardoso

. Predicting the geometric form of clad in laser cladding by powder using multiple regression analysis (MRA). Mater Des 2008; 29: 554–557.

24.

Khalili

Mojtahedi

Qaderi

, et al. Effect of pulse laser parameters on the microstructure of the in-situ Fe-TiC hard layer: simulation and experiment. Opt Laser Technol 2021; 135: 106693.

25.

Das

Prasad

Paradkar

. Evolution of microstructure in laser surface alloying of aluminium with nickel. Mater Sci Eng A 1994; 174: 75–84.

26.

Ghaini

Hamedi

Torkamany

, et al. Weld metal microstructural characteristics in pulsed Nd: YAG laser welding. Scr Mater 2007; 56: 955–958.

27.

Tariq

Hasan

Akhter

. Evolution of microstructure in Zr55Cu30Al10Ni5 bulk amorphous alloy by high power pulsed Nd: YAG laser. J Alloys Compd 2009; 485: 212–214.

28.

Davim

Oliveira

Cardoso

. Laser cladding: an experimental study of geometric form and hardness of coating using statistical analysis. Proc Inst Mech Eng Part B J Eng Manufact 2006; 220: 1549–1554.

29.

Wang

Felicelli

. Process modeling in laser deposition of multilayer SS410 steel. ASME J Manuf Sci Eng. 2007; 129: 1028–1034.

30.

Sabetghadam

Hanzaki

Araee

. Diffusion bonding of 410 stainless steel to copper using a nickel interlayer. Mater Charact 2010; 61(6): 626–634.

31.

Lei

Sun

Tang

, et al. Numerical simulation of temperature distribution and TiC growth kinetics for high power laser clad TiC/NiCrBSiC composite coatings. Opt Laser Technol 2012; 44: 1141–1147.

32.

Ley

Joshi

Zhang

, et al. Laser coating of a CrMoTaWZr complex concentrated alloy onto a H13 tool steel die head. Surf Coat Technol 2018; 348: 150–158.

33.

Toyserkani

Khajepour

Corbin

. 3-D Finite element modeling of LC by powder injection: effects of laser pulse shaping on the process. Opt Lasers Eng 2004; 41: 849–867.

34.

Vora

Santhanakrishnan

Harimkar

, et al. One-dimensional multipulse laser machining of structural alumina: evolution of surface topography. Int J Adv Manufact Technol 2013; 68: 69–83.

35.

Chen

Luo

, et al. Effect of laser scanning speed on the microstructure and mechanical properties of laser-powder-bed-fused K418 nickel-based alloy. Materials (Basel) 2022; 15: 3045.

36.

Raj

Maity

Das

. Characterisation of laser-cladded 410 stainless steel for in situ repair of turbine blade. Surf Eng 2024; 40: 515–526.

37.

Ming

Zhang

Wang

, et al. Microstructure of a domestically fabricated dissimilar metal weld joint (SA508-52M-309L-CF8A) in nuclear power plant. Mater Charact 2019; 148: 100–115.

38.

Chai

Zhang

Zhong

, et al. Effect of scan speed on grain and microstructural morphology for laser additive manufacturing of 304 stainless steel. Rev Adv Mater Sci 2021; 60: 744–760.

39.

Guo

Ding

, et al. Microstructure characteristics and mechanical properties of a laser cladded Fe-based martensitic stainless steel coating. Surf Coat Technol 2021; 408: 126795.

40.

Telasang

Majumdar

Padmanabham

, et al. Effect of laser parameters on microstructure and hardness of laser clad and tempered AISI H13 tool steel. Surf Coat Technol 2014; 258: 1108–1118.

41.

Muvvala

Karmakar

Nath

. Online assessment of TiC decomposition in LC of metal matrix composite coating. Mater Des 2017; 121: 310–320.

42.

Cedillos-Barraza

Manara

Boboridis

, et al. Investigating the highest melting temperature materials: a laser melting study of the TaC-HfC system. Sci Rep 2016; 6: 37962.

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Numerical and experimental investigation of nickel-deposited 410 stainless steel using the laser cladding process

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