Comprehensive Analysis of Current Primary Measures to Mitigate Brake Wear Particle Emissions from Light-Duty Vehicles

Storch, Lukas; Hamatschek, Christopher; Hesse, David; Feist, Felix E.; Bachmann, Thomas; Eichler, Philipp; Grigoratos, Theodorοs

doi:10.3390/atmos14040712

Cited by 19 publications

(30 citation statements)

References 35 publications

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“…0.107) based on actual vehicles. These results indicate the need for vehicle-specific friction brake share coefficients, a conclusion consistent with a previous study [17]. Using electrified vehicle brakes as FFBs and a single coefficient for each group does not allow for fair brake-wear particle measurements, especially fair PN measurements.…”

Section: Pm10 Pm25 and Tpnsupporting

confidence: 75%

“…Friction brakes that share coefficients that depend on the electric vehicle type have been implemented in this method to allow third-party laboratories to perform tests based on the GTR24 procedure. Although this friction brake share coefficient was the first step of the study of brake wear particle emissions for vehicle with regenerative brake systems, the method does not represent actual regenerative braking characteristics and needs to be improved [17]. Based on environmental policy making processes in Japan [18], the Automotive Emissions Expert Committee of Japan has been discussing this issue and is in the process of developing the Future Measures to Reduce Automobile Emissions (Fifteenth Report).…”

Section: Introductionmentioning

confidence: 99%

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Investigation of Brake-Wear Particle Emissions from Regenerative-Friction Brake Coordination Systems via Dynamometer Testing

Hagino

2023

Preprint

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The goal of this study was to evaluate the feasibility of methods based on the Worldwide Harmonized Light-Duty Vehicles Test Procedure Brake Cycle to measure brake wear particle emissions for currently used electrified vehicles. Our results indicated that reducing brake friction work reduced brake wear particle emissions. Commercially available, plug-in hybrid electric vehicles reduced emissions by 85% for PM10, 78% for PM2.5, and 87% for particle numbers (PNs) compared to vehicles with internal combustion engines. Brake friction work showed a linear relationship with PM10 and PM2.5. Nanoparticle PM emissions tended to increase slightly with regenerative braking, but did not contribute significantly to the overall PM percentage. the emission events of high number concentrations of nuclei mode particles (<20 nm in diameter) in electric vehicle brake assemblies designed for regenerative braking use under high-temperature, high-load braking conditions with full-friction brakes. The nuclei mode particles amplified the PN emissions and led to a high variability. In strict regulatory certification tests, where measurement reproducibility and stability are required, it is appropriate to measure PNs under brake conditions appropriate for the actual use of electric vehicles rather than under full-friction brake conditions or to remove particle measurements smaller than 20 nm.

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Section: Pm10 Pm25 and Tpnsupporting

confidence: 75%

Section: Introductionmentioning

confidence: 99%

Investigation of Brake-Wear Particle Emissions from Regenerative-Friction Brake Coordination Systems via Dynamometer Testing

Hagino

2023

Preprint

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“…Mass loss as a wear factor was 9.31 mg/km per brake with ECE pads (Figure 1). A comparison of these results to the benchmarks of a previous interlaboratory study (ILS) [8] revealed that higher emissions were observed in that study than in this study (6.5 mg/km per brake with NAO pads and 21 mg/km per brake with ECE pads) [26,27]. NAO was developed to optimize comfort (reduction of noise and rim contamination), and this study (Figure 1) as well as previous studies have shown higher emissions with ECE than with NAO [26].…”

Section: Brake Pad and Disc Wearsupporting

confidence: 47%

Iron Oxide and Hydroxide Speciation in Emissions of Brake Wear Particles from Different Friction Materials Using an X-ray Absorption Fine Structure

Hagino,

Iwata,

Okuda

2023

Atmosphere

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Iron (Fe), the main component of non-exhaust particulates, is known to have variable health effects that depend on the chemical species of iron. This study characterized the possible contribution of iron oxides and hydroxides to airborne brake wear particles under realistic vehicle driving and braking conditions with different brake pad friction materials. We found significant differences in wear factors and PM10 and PM2.5 emissions between non-asbestos organic (NAO) and European performance (ECE) brake pads. Iron was the dominant contributor to PM10 and PM2.5 brake wear particles for both NAO and ECE. The iron concentration ratio in the particle mass (PM) was comparable to the disc-to-pads ratio measured by wear mass. The fact that magnetite, which is of interest with respect to health effects, was less abundant in NAO than in ECE suggested that tribo-oxidations occurred in NAO. Metallic iron is generated not only from abrasive wear but also from tribo-chemical reduction with magnetite as the starting material. We found that there were differences in PM emissions between brake friction materials, and that the phase transformations of iron differed between friction materials. These differences were apparent in the distribution of iron oxides and hydroxides. Heat, tribo-oxidation, and tribo-reduction are intricately involved in these reactions.

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“…Similarly, Storch et al 21 reported that wear particles from drum brakes initially accumulated in the drum but began escaping from the drum once saturation of the accumulation was reached. This resulted in a steady state level of emissions after an initial phase.…”

Section: Discussionmentioning

confidence: 93%

Ultrafine particle emissions from dry clutches: number concentration, size distribution and chemical composition

Hjelm,

Lyu,

Mancini

et al. 2024

Environ. Sci.: Atmos.

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Comprehensive Analysis of Current Primary Measures to Mitigate Brake Wear Particle Emissions from Light-Duty Vehicles

Cited by 19 publications

References 35 publications

Investigation of Brake-Wear Particle Emissions from Regenerative-Friction Brake Coordination Systems via Dynamometer Testing

Investigation of Brake-Wear Particle Emissions from Regenerative-Friction Brake Coordination Systems via Dynamometer Testing

Iron Oxide and Hydroxide Speciation in Emissions of Brake Wear Particles from Different Friction Materials Using an X-ray Absorption Fine Structure

Ultrafine particle emissions from dry clutches: number concentration, size distribution and chemical composition

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