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Abstract

High-speed electric vehicle (EV) motor shafts require superior surface integrity to ensure efficiency, durability, and noise–vibration–harshness (NVH) performance. Conventional finishing methods such as grinding and superfinishing provide micrometric smoothness but often fail to deliver the nanometric precision demanded by modern EV drivetrains. This study explores magnetorheological (MR) nano-finishing as a transformative technique for enhancing the performance of 42CrMo4 alloy steel shafts commonly used in EV motors. Experimental investigations were carried out on heat-treated shafts (52–56HRC) using a custom MR finishing setup under systematically varied process parameters. Statistical analysis (analysis of variance) identified the most significant factors influencing surface roughness and subsurface properties. Results revealed a reduction in surface roughness from 0.18–0.22 to 0.013–0.020 µm, representing ∼90% improvement. Residual stress analysis showed a shift from tensile (+150 MPa) to compressive (−160 to −230 MPa) states, alongside a 6% to 8% increase in near-surface hardness. Tribological tests confirmed ∼30% lower friction and ∼35% to 42% reduced wear, while fatigue life improved by ∼39%. NVH evaluations further demonstrated a reduction of ∼5 dB(A) in noise and ∼20% lower vibration amplitudes. The findings establish MR nano-finishing as a scalable and sustainable process that simultaneously improves surface quality, subsurface integrity, and functional performance. Its adoption could significantly advance EV drivetrain reliability, efficiency, and passenger comfort.

Keywords

Magnetorheological finishing electric vehicle motor shafts surface integrity noise vibration harshness tribological performance

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References

Günther

Muhammedi

Werner

, et al. Investigations into increasing the fatigue strength of shafts by deep rolling. Forsch Ingenieurwes 2024; 88: 19.

Horn

Ritchie

. Mechanism of tempered martensite embrittlement in low alloy steels. Metall Trans A 1978; 9A: 1039–1053.

Alajmi

Almeshal

. Prediction and optimization of surface roughness in a turning process using the ANFIS-QPSO method. Materials (Basel) 2020; 13: 2986.

Wan

Zou

, et al. Experimental study on cutting force in ultrasonic vibration-assisted turning of 304 austenitic stainless steel. Proc Inst Mech Eng B J Eng Manuf 2020; 235: 494–513.

Dutta

Kumar

Narala

. Investigations on machining characteristics and chip morphology in turning Al-Mn (AM) alloy using finite element simulation. Proc Inst Mech Eng B J Eng Manuf 2021; 235: 1608–1617.

Grzesik

Bartoszuk

Nieslony

. Finite element modeling of temperature distribution in the cutting zone in turning processes with differently coated tools. J Mater Process Technol 2005; 164: 1204–1211.

Twardowski

Wiciak-Pikuła

. Prediction of tool wear using artificial neural networks during turning of hardened steel. Materials (Basel) 2019; 12: 3091.

Liu

Wan

Zhang

, et al. Chip formation mechanism of Inconel 718: a review of models and approaches. Chin J Mech Eng 2021; 34: 34.

Duan

Doul

Cai

, et al. Finite element simulation and experiment of chip formation process during high speed machining of AISI 1045 hardened steel. Int J Recent Trends Eng 2009; 1: 46–50.

10.

Tan

Xie

Chen

, et al. Structure optimization of conical spool and flow force compensation in a diverged flow cartridge proportional valve. Flow Meas Instrum 2019; 66: 170–181.

11.

Amirante

Andrea

Tamburrano

. The importance of a full 3D fluid dynamic analysis to evaluate the flow forces in a hydraulic directional proportional valve. Eng Comput 2014; 31: 898–922.

12.

Horvath

Feszty

. Surface waviness of EV gears and NVH effects—A comprehensive review. World Electr Veh J 2025; 16: 40.

13.

Zhmud

Najjari

Brodmann

. The effects of the lubricant properties and surface finish characteristics on the tribology of high-speed gears for EV transmissions. Lubricants 2024; 12: 112.

14.

Ghanbarzadeh

. Electric vehicle tribology: highlighting challenges and opportunities in the automotive industry. J Tribol 2025; 148: 1–90.

15.

Tung

. Powertrain tribology development trends and impact of surface engineering on friction and wear control. Surf Eng Found Concepts Tech Appl 2025. doi: https://doi.org/10.5772/intechopen.1007649

16.

Singh

. Improved magnetorheological finishing process with rectangular core tip for external cylindrical surfaces. Mater Manuf Process 2019; 34: 1049–1061.

17.

Singh

. Performance investigation of magnetorheological finishing of rolls in cold rolling process. J Manuf Process 2019; 41: 315–329.

18.

Singh

. Magnetorheological finishing of micro-punches for enhanced performance of micro-extrusion process. Mater Manuf Process 2019; 34: 1646–1657.

19.

Pandey

. Use of chemical oxidizers with alumina slurry in double disk magnetic abrasive finishing for improving surface finish of Si (100). J Manuf Process 2018; 32: 138–150.

20.

Singh

. Theoretical investigations into magnetorheological finishing of external cylindrical surfaces for improved performance. Proc Inst Mech Eng C J Process Mech Eng 2021; 234(24): 4872–4892.

21.

Singh

. Precision Surface Finishing of Additively Manufactured ABS Punches via Magnetorheological Finishing. JOM 2025. DOI: 10.1007/s11837-025-07937-4

22.

Wang

Gordaninejad

. Study of magnetorheological fluids at high shear rate. Rheol Acta 2006; 45: 899–908.

23.

Kordonski

Jacobs

. Magnetorheological finishing. Int J Mod Phys B 1996; 10: 2857–2865.

24.

Vahdati

Rasouli

. Study of magnetic abrasive finishing of free form surface. Trans Inst Met Finish 2016; 94: 294–302.

25.

Singh

. Influence of magnetorheological finishing on roller surface properties and thread rolling efficiency. Proc Inst Mech Eng Part E: J Process Mech Eng 2025. DOI: 10.1177/095440892513228

26.

Singh

Jayant

. Optimization of turning parameters of titanium chrome-moly (Ti-Cr-Mo) alloy using Taguchi method. Indian J Eng Mater Sci 2019; 27: 776–782.

27.

Park

Fang

Choi

. Magnetorheology: materials and application. Soft Matter 2010; 6: 5246–5253.

28.

Kubík

Válek

Žáček

, et al. Transient response of magnetorheological fluid on rapid change of magnetic field in shear mode. Sci Rep 2022; 12: 10612.

29.

Kikuchi

Noma

Akaiwa

, et al. Response time of magnetorheological fluid-based haptic device. J Intell Mater Syst Struct 2016; 27: 859–865.

30.

Trübswetter

Götz

Kohn

, et al. Effects of different hard finishing processes on gear excitation. Machines 2021; 9: 169.

31.

Horváth

. Data-driven predictive modeling for investigating the impact of gear manufacturing parameters on noise levels in electric vehicle drivetrains. World Electric Vehicle J 2025; 16: 426.

32.

Yousuf

Spikes

, et al. The influence of lubricant formulation on surface damage under electrified rolling-sliding contact with relevance to electric vehicle drivetrain applications. Tribol Lett 2025; 73: 126.

33.

Janik

Saha

Jackson

, et al. Rheological and electro-pitting performance of electric vehicle motor greases with various nanoparticle greases. J Tribol 2025; 147: 051110.

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Advancing electric vehicle drivetrain reliability through magnetorheological finishing of 42CrMo4 motor shaft

Abstract

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