Improving the Non-Destructive Testing Process of the Outer Bearing Ring
SIWIEC Dominika, DWORNICKA Renata and PACANA Andrzejdownload PDF
Abstract. The aim was to identify the unconformities in the product with the magnetic-powder method and extension of the analysis process about selected quality management techniques in order to identify the root of unconformities. The product subject to magnetic-powder testing was the outer ring of the four-point ball bearing. On the product, the cracks were identified, so in order to point to the root of unconformities, the techniques like Ishikawa diagram and the 5Why method were implemented. Analyses showed that the source of the cracks on the outer bearing ring was defective material from the supplier. The proposed process of using quality management techniques together with non-destructive testing can be used in any enterprise to detect the unconformities of the products and the reasons for their creation.
Mechanical Engineering, Bearing Housing, Non-Destructive Test, Quality Management
Published online 7/20/2022, 7 pages
Copyright © 2022 by the author(s)
Published under license by Materials Research Forum LLC., Millersville PA, USA
Citation: SIWIEC Dominika, DWORNICKA Renata and PACANA Andrzej, Improving the Non-Destructive Testing Process of the Outer Bearing Ring, Materials Research Proceedings, Vol. 24, pp 174-180, 2022
The article was published as article 26 of the book Terotechnology XII
Content from this work may be used under the terms of the Creative Commons Attribution 3.0 licence. Any further distribution of this work must maintain attribution to the author(s) and the title of the work, journal citation and DOI.
 M. Zielińska, M. Rucka. Non-destructive assessment of masonry pillars using ultrasonic tomography. Materials 11 (2018) art. 2543. https://doi.org/10.3390/ma11122543
 A. Pacana, D. Siwiec, L. Bednárová. Analysis of the incompatibility of the product with fluorescent method. Metalurgija 58 (2019) 337-340.
 A. Pacana, A. Radon-Cholewa, J. Pacana J. The study of stickiness of packaging film by Shainin method. Przemysl Chemiczny 94 (2015) 1334-1336.
 W. Swiderski. Non-destructive testing of light armours of CFRP after ballistic impacts by IR thermography methods. Composite Structures 224 (2019) art. 111086.
 C. Guo, C. Xu, J. Hao, D. Xiao, W. Yang. Ultrasonic Non-Destructive Testing System of Semi-Enclosed Workpiece with Dual-Robot Testing System. Sensors 19 (2019) art. 3359. https://doi.org/10.3390/s19153359
 I. Kryukov, S. Boehm. Prospects and limitations of eddy current shearography for non-destructive testing of adhesively bonded structural joints. Journal of Adhesion 95 (2019) 874-886.
 R. Mulaveesala, V. Arora, A. Rani. Coded thermal wave imaging technique for infrared non-destructive testing and evaluation. Nondestructive Testing and Evaluation 34 (2019) 243-253.
 A. Imperiale, N. Leymarie, T. Fortuna. Coupling Strategies Between Asymptotic and Numerical Models with Application to Ultrasonic Non-Destructive Testing of Surface Flaws. Journal Of Theoretical And Computational Acoustics 27 (2019) art. 1850052. https://doi.org/10.1142/S2591728518500524
 K. Trieb, J. Glinz, M. Reiter. Non-Destructive Testing of Ceramic Knee Implants Using Micro-Computed Tomography. Journal of Arthroplasty 34 (2019) 2111-2117.
 M. Sofi, Y. Oktavianus, E. Lumantarna. Condition assessment of concrete by hybrid non-destructive tests. Journal of Civil Structural Health Monitoring 9 (2019) 339-351.
 E. Jasiuniene, L. Mazeika, V. Samaitis. Ultrasonic non-destructive testing of complex titanium/carbon fibre composite joints. Ultrasonics 95 (2019) 13-21.
 H. Rathod, R. Gupta. Sub-surface simulated damage detection using Non-Destructive Testing Techniques in reinforced-concrete slabs. Construction and Building Materials 215 (2019) 754-764.
 A.N. Hoshyar, M. Rashidi, R. Liyanapathirana. Algorithm Development for the Non-Destructive Testing of Structural Damage. Applied Sciences 9 (2019) art. 2810. https://doi.org/10.3390/app9142810