Manufacture material characteristic analysis of original and alternative auto parts. Case Study: Brake Disc

Jaime Antamba; Vladimir Azanza; Gorky Reyes; Álvaro Remache; Soraya Ruiz

doi:10.29019/enfoqueute.v11n3.631

Authors

Jaime Antamba Universidad Internacional del Ecuador https://orcid.org/0000-0001-9666-9873
Vladimir Azanza Universidad Internacional del Ecuador https://orcid.org/0000-0001-5582-2077
Gorky Reyes Universidad Internacional del Ecuador https://orcid.org/0000-0002-7133-9509
Álvaro Remache Universidad Internacional del Ecuador https://orcid.org/0000-0003-3947-5057
Soraya Ruiz Universidad Internacional del Ecuador https://orcid.org/0000-0002-7603-5846

DOI:

https://doi.org/10.29019/enfoqueute.v11n3.631

Keywords:

SAE J341, auto parts, carbon equivalent, perlitic matrix

Abstract

All powered vehicles have a braking system adopted according to the type of vehicle and work for which they are designed. In Ecuador, there is a great variety of auto parts that are proposed as alternative replacement, varying in cost and quality. This research aims to quantitatively analyze the characteristics of the brake disc material between original and alternate auto parts. This research analyzes three brake disc samples (A, B, C) from different manufacturing sources, using the ASTM E415-08 spectrometry test and the metallography test under the ASTM A247-16A standard. The spectrometry detects 15 elements in each sample, the carbon equivalent of sample A is 18% and 20% higher in relation to sample B and C, which significantly influences the microstructure. The metallographic tests indicate a pearlitic matrix in each sample, however, there is a different distribution and size of the graphite flakes. According to the SAE J431 standard, each auto part meets the material conditions for the brake disc function.

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References

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JCR(JCI)	Q4(0.13)
REDIB Journals Ranking	Q2(16.594)
Google Scholar Citations	3405
Google Scholar h-index	25
Google Scholar i10-index	103
OAJI Impact Factor	0.351
MIAR ICDS	7.5
Index Copernicus Value	94.81
Dimensions	351(0.93)

	2022	2021
Submissions Received	92	65
Submissions Accepted	29	22
Submissions Declined	53	41
Submissions Published	24	24
Days to Accept (x̄)	104	131
Days to Reject (x̄)	35	34
Acceptance Rate	24%	35%
Rejection Rate	76%	65%

Manufacture material characteristic analysis of original and alternative auto parts. Case Study: Brake Disc

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