Automated system for measuring the radial clearance of rolling bearings

Research output: Contributions to collected editions/worksArticle in conference proceedingsResearchpeer-review

Standard

Automated system for measuring the radial clearance of rolling bearings. / Meier, Nicolas; Papadoudis, Jan; Georgiadis, Anthimos.
Sensoren und Messsysteme 2018: Beiträge der 19. ITG/GMA-Fachtagung 26. – 27. Juni 2018 in Nürnberg. VDE Verlag GmbH, 2018. p. 410-413 (Sensoren und Messsysteme - 19. ITG/GMA-Fachtagung).

Research output: Contributions to collected editions/worksArticle in conference proceedingsResearchpeer-review

Harvard

Meier, N, Papadoudis, J & Georgiadis, A 2018, Automated system for measuring the radial clearance of rolling bearings. in Sensoren und Messsysteme 2018: Beiträge der 19. ITG/GMA-Fachtagung 26. – 27. Juni 2018 in Nürnberg. Sensoren und Messsysteme - 19. ITG/GMA-Fachtagung, VDE Verlag GmbH, pp. 410-413, 19th ITG/GMA Conference on Sensors and Measuring Systems 2018, Nurnberg, Germany, 26.06.18.

APA

Meier, N., Papadoudis, J., & Georgiadis, A. (2018). Automated system for measuring the radial clearance of rolling bearings. In Sensoren und Messsysteme 2018: Beiträge der 19. ITG/GMA-Fachtagung 26. – 27. Juni 2018 in Nürnberg (pp. 410-413). (Sensoren und Messsysteme - 19. ITG/GMA-Fachtagung). VDE Verlag GmbH.

Vancouver

Meier N, Papadoudis J, Georgiadis A. Automated system for measuring the radial clearance of rolling bearings. In Sensoren und Messsysteme 2018: Beiträge der 19. ITG/GMA-Fachtagung 26. – 27. Juni 2018 in Nürnberg. VDE Verlag GmbH. 2018. p. 410-413. (Sensoren und Messsysteme - 19. ITG/GMA-Fachtagung).

Bibtex

@inbook{82461e99468a41c596d4a28a87e4bbe2,
title = "Automated system for measuring the radial clearance of rolling bearings",
abstract = "Most of the bearing positions are designed with rolling bearings. Usually rolling bearings are manufactured with a cer-tain {"}bearing clearance{"}. Bearing clearance is defined as the total distance through which one bearing ring can be moved relative to the other in the radial direction (radial clearance) or in the axial direction (axial clearance). The radial clearance of a bearing is of considerable importance if reliable operation expected. Correctly installed rolling bearings increase the lifetime and cause less energy loss. In case of radial rolling bearings with a tapered bore, which are fas-tened on the shaft with an adapter sleeve, the radial clearance is reduced during the process of mounting. There are known measuring devices, that allow to check the radial clearance fully automatically in the uninstalled state. Methods for checking the radial clearance in the installed state are known as well. The simplest method is the use of feeler gauges. Even simple measuring devices are known where the bearing is turned by hand and the radial clearance is read manually via a dial gauge. The measurements of these methods are sometimes subject to large fluctuations because each assembly operator is not performing the task exactly the same-human variation. The intent of this work is to develop a method for measuring radial clearance during the assembly process. The meas-urement result should be reproducible and not influenced by the assembly operator's natural variation while performing the task. For this reason, a measuring device was developed. The radial clearance can now be measured before, during and immediately after the process of mounting bearings with tapered bore which are fastened on the shaft with an adapter sleeve. The measurement is performed automatically and the measured data is directly logged-specifically for each individual bearing. By developing an intelligent algorithm that adapts to different bearing configurations, the metrological determination of the test load became unnecessary. The trend of the test force was abstracted by a mechanical model and the characteris-tic curve correlated with the bearing clearance. Thus, the sensor technology originally required for this could be re-placed by an intelligent software system. The system that was developed can be incorporated into the quality control system of a rolling bearing manufacturer. It should also be used as a standardized method for checking the radial clearance of bearings after the assembly process. ",
keywords = "Engineering, Messtechnik, Industrie 4.0, Lagerluft",
author = "Nicolas Meier and Jan Papadoudis and Anthimos Georgiadis",
note = "2018, 606 Seiten, Slimlinebox, CD-Rom; 19th ITG/GMA Conference on Sensors and Measuring Systems 2018 ; Conference date: 26-06-2018 Through 27-06-2018",
year = "2018",
language = "English",
isbn = "978-3-8007-4683-5",
series = "Sensoren und Messsysteme - 19. ITG/GMA-Fachtagung",
publisher = "VDE Verlag GmbH",
pages = "410--413",
booktitle = "Sensoren und Messsysteme 2018",
address = "Germany",

}

RIS

TY - CHAP

T1 - Automated system for measuring the radial clearance of rolling bearings

AU - Meier, Nicolas

AU - Papadoudis, Jan

AU - Georgiadis, Anthimos

N1 - Conference code: 19

PY - 2018

Y1 - 2018

N2 - Most of the bearing positions are designed with rolling bearings. Usually rolling bearings are manufactured with a cer-tain "bearing clearance". Bearing clearance is defined as the total distance through which one bearing ring can be moved relative to the other in the radial direction (radial clearance) or in the axial direction (axial clearance). The radial clearance of a bearing is of considerable importance if reliable operation expected. Correctly installed rolling bearings increase the lifetime and cause less energy loss. In case of radial rolling bearings with a tapered bore, which are fas-tened on the shaft with an adapter sleeve, the radial clearance is reduced during the process of mounting. There are known measuring devices, that allow to check the radial clearance fully automatically in the uninstalled state. Methods for checking the radial clearance in the installed state are known as well. The simplest method is the use of feeler gauges. Even simple measuring devices are known where the bearing is turned by hand and the radial clearance is read manually via a dial gauge. The measurements of these methods are sometimes subject to large fluctuations because each assembly operator is not performing the task exactly the same-human variation. The intent of this work is to develop a method for measuring radial clearance during the assembly process. The meas-urement result should be reproducible and not influenced by the assembly operator's natural variation while performing the task. For this reason, a measuring device was developed. The radial clearance can now be measured before, during and immediately after the process of mounting bearings with tapered bore which are fastened on the shaft with an adapter sleeve. The measurement is performed automatically and the measured data is directly logged-specifically for each individual bearing. By developing an intelligent algorithm that adapts to different bearing configurations, the metrological determination of the test load became unnecessary. The trend of the test force was abstracted by a mechanical model and the characteris-tic curve correlated with the bearing clearance. Thus, the sensor technology originally required for this could be re-placed by an intelligent software system. The system that was developed can be incorporated into the quality control system of a rolling bearing manufacturer. It should also be used as a standardized method for checking the radial clearance of bearings after the assembly process.

AB - Most of the bearing positions are designed with rolling bearings. Usually rolling bearings are manufactured with a cer-tain "bearing clearance". Bearing clearance is defined as the total distance through which one bearing ring can be moved relative to the other in the radial direction (radial clearance) or in the axial direction (axial clearance). The radial clearance of a bearing is of considerable importance if reliable operation expected. Correctly installed rolling bearings increase the lifetime and cause less energy loss. In case of radial rolling bearings with a tapered bore, which are fas-tened on the shaft with an adapter sleeve, the radial clearance is reduced during the process of mounting. There are known measuring devices, that allow to check the radial clearance fully automatically in the uninstalled state. Methods for checking the radial clearance in the installed state are known as well. The simplest method is the use of feeler gauges. Even simple measuring devices are known where the bearing is turned by hand and the radial clearance is read manually via a dial gauge. The measurements of these methods are sometimes subject to large fluctuations because each assembly operator is not performing the task exactly the same-human variation. The intent of this work is to develop a method for measuring radial clearance during the assembly process. The meas-urement result should be reproducible and not influenced by the assembly operator's natural variation while performing the task. For this reason, a measuring device was developed. The radial clearance can now be measured before, during and immediately after the process of mounting bearings with tapered bore which are fastened on the shaft with an adapter sleeve. The measurement is performed automatically and the measured data is directly logged-specifically for each individual bearing. By developing an intelligent algorithm that adapts to different bearing configurations, the metrological determination of the test load became unnecessary. The trend of the test force was abstracted by a mechanical model and the characteris-tic curve correlated with the bearing clearance. Thus, the sensor technology originally required for this could be re-placed by an intelligent software system. The system that was developed can be incorporated into the quality control system of a rolling bearing manufacturer. It should also be used as a standardized method for checking the radial clearance of bearings after the assembly process.

KW - Engineering

KW - Messtechnik

KW - Industrie 4.0

KW - Lagerluft

UR - http://www.scopus.com/inward/record.url?scp=85073193876&partnerID=8YFLogxK

M3 - Article in conference proceedings

AN - SCOPUS:85073193876

SN - 978-3-8007-4683-5

T3 - Sensoren und Messsysteme - 19. ITG/GMA-Fachtagung

SP - 410

EP - 413

BT - Sensoren und Messsysteme 2018

PB - VDE Verlag GmbH

T2 - 19th ITG/GMA Conference on Sensors and Measuring Systems 2018

Y2 - 26 June 2018 through 27 June 2018

ER -