Measurement of tool temperature in burnishing using diamond tip

This paper proposes a method for measuring the tool temperature during burnishing by using a diamond tip. The proposed method was used to examine the influence of tool wear behavior and burnishing conditions on the tool temperature. The experiment focused on the inner circumferential surface of a cy...

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Autores principales: Masato OKADA, Masayoshi SHINYA, Hidetake TANAKA, Naoki ASAKAWA, Masaaki OTSU
Formato: article
Lenguaje:EN
Publicado: The Japan Society of Mechanical Engineers 2016
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Acceso en línea:https://doaj.org/article/14e1ba310c044a779c5b8b222b270d01
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spelling oai:doaj.org-article:14e1ba310c044a779c5b8b222b270d012021-11-26T06:40:17ZMeasurement of tool temperature in burnishing using diamond tip2187-974510.1299/mej.15-00569https://doaj.org/article/14e1ba310c044a779c5b8b222b270d012016-04-01T00:00:00Zhttps://www.jstage.jst.go.jp/article/mej/3/2/3_15-00569/_pdf/-char/enhttps://doaj.org/toc/2187-9745This paper proposes a method for measuring the tool temperature during burnishing by using a diamond tip. The proposed method was used to examine the influence of tool wear behavior and burnishing conditions on the tool temperature. The experiment focused on the inner circumferential surface of a cylindrical geometric workpiece rotated by the main spindle of a lathe. The tool temperature was measured by using a two-color pyrometer with an optical fiber as a noncontact thermometer. An optical fiber was embedded in the workpiece in the radial direction, and it was rotated with the workpiece. The optical fiber accepted the infrared rays that radiated from the burnishing point of the diamond tip. Another optical fiber that was fixed on the outside of the lathe guided the accepted infrared rays to the two-color pyrometer. The accelerometer was fixed on the tool shank to detect the position of the burnishing point. The output pulses from the two-color pyrometer and accelerometer were stably observed during each rotation of the workpiece. The influence of the tool wear behavior on the tool temperature was observed. The tool temperature increased when the profile of the wear region of the diamond tip became rough. In contrast, the tool temperature decreased during the initial stage of burnishing. The circumferential speed of the target surface (burnishing speed) and the indentation force of the diamond tip on the target surface influenced the tool temperature.Masato OKADAMasayoshi SHINYAHidetake TANAKANaoki ASAKAWAMasaaki OTSUThe Japan Society of Mechanical Engineersarticlesurface finishingburnishingdiamond tiptool temperaturetwo-color pyrometerMechanical engineering and machineryTJ1-1570ENMechanical Engineering Journal, Vol 3, Iss 2, Pp 15-00569-15-00569 (2016)
institution DOAJ
collection DOAJ
language EN
topic surface finishing
burnishing
diamond tip
tool temperature
two-color pyrometer
Mechanical engineering and machinery
TJ1-1570
spellingShingle surface finishing
burnishing
diamond tip
tool temperature
two-color pyrometer
Mechanical engineering and machinery
TJ1-1570
Masato OKADA
Masayoshi SHINYA
Hidetake TANAKA
Naoki ASAKAWA
Masaaki OTSU
Measurement of tool temperature in burnishing using diamond tip
description This paper proposes a method for measuring the tool temperature during burnishing by using a diamond tip. The proposed method was used to examine the influence of tool wear behavior and burnishing conditions on the tool temperature. The experiment focused on the inner circumferential surface of a cylindrical geometric workpiece rotated by the main spindle of a lathe. The tool temperature was measured by using a two-color pyrometer with an optical fiber as a noncontact thermometer. An optical fiber was embedded in the workpiece in the radial direction, and it was rotated with the workpiece. The optical fiber accepted the infrared rays that radiated from the burnishing point of the diamond tip. Another optical fiber that was fixed on the outside of the lathe guided the accepted infrared rays to the two-color pyrometer. The accelerometer was fixed on the tool shank to detect the position of the burnishing point. The output pulses from the two-color pyrometer and accelerometer were stably observed during each rotation of the workpiece. The influence of the tool wear behavior on the tool temperature was observed. The tool temperature increased when the profile of the wear region of the diamond tip became rough. In contrast, the tool temperature decreased during the initial stage of burnishing. The circumferential speed of the target surface (burnishing speed) and the indentation force of the diamond tip on the target surface influenced the tool temperature.
format article
author Masato OKADA
Masayoshi SHINYA
Hidetake TANAKA
Naoki ASAKAWA
Masaaki OTSU
author_facet Masato OKADA
Masayoshi SHINYA
Hidetake TANAKA
Naoki ASAKAWA
Masaaki OTSU
author_sort Masato OKADA
title Measurement of tool temperature in burnishing using diamond tip
title_short Measurement of tool temperature in burnishing using diamond tip
title_full Measurement of tool temperature in burnishing using diamond tip
title_fullStr Measurement of tool temperature in burnishing using diamond tip
title_full_unstemmed Measurement of tool temperature in burnishing using diamond tip
title_sort measurement of tool temperature in burnishing using diamond tip
publisher The Japan Society of Mechanical Engineers
publishDate 2016
url https://doaj.org/article/14e1ba310c044a779c5b8b222b270d01
work_keys_str_mv AT masatookada measurementoftooltemperatureinburnishingusingdiamondtip
AT masayoshishinya measurementoftooltemperatureinburnishingusingdiamondtip
AT hidetaketanaka measurementoftooltemperatureinburnishingusingdiamondtip
AT naokiasakawa measurementoftooltemperatureinburnishingusingdiamondtip
AT masaakiotsu measurementoftooltemperatureinburnishingusingdiamondtip
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