Litcius/Paper detail

Investigation of mechanical properties and performance of automotive brake pads

Mahmoud A. Essam, Noha M. Abdeltawab, Ahmed Y. Shash, Mostafa M. El-Sayed

2025Scientific Reports8 citationsDOIOpen Access PDF

Abstract

This study evaluates the performance of three powder metallurgy-based brake pad formulations (BP1, BP2, and BP3) by examining mass loss, hardness, braking force, coefficient of friction (COF), noise, and vibration under 5 and 8 bar pressures. BP1 exhibited the highest braking force (640.99 N) and COF (0.3873) at 8 bars, with improvements of 7.7-13.6% and 4.4-6.8% over BP2 and BP3, respectively. However, this came with the highest mass loss (1.2 g/h), noise (17.5 dB), and vibration (0.743 m/s²), attributed to three-body abrasive wear from SiC and ZrO₂ particles.BP3 demonstrated the lowest mass loss (1.07 g/h, ~ 20% lower than BP1), noise (14.8 dB), and vibration (0.571 m/s²), making it suitable for quiet, long-life applications. BP2 showed balanced behavior across all parameters. Hardness values were 46 HRC (BP1), 38 HRC (BP2), and 44 HRC (BP3), aligning with observed braking forces and structural compactness.

Topics & Concepts

Brake padBrakeVibrationNoise (video)Materials scienceAbrasiveCoefficient of frictionComposite materialAutomotive industryPowertrainAutomotive engineeringMetallurgyPhysicsComputer scienceEngineeringAcousticsThermodynamicsTorqueArtificial intelligenceImage (mathematics)Brake Systems and Friction AnalysisTribology and Wear AnalysisPowder Metallurgy Techniques and Materials