Estimation of volumetric accuracy based on linear error motion in machining centers

ISO230-1, an international standard of test code for machine tools, has been revised for the first time in 16 years. A volumetric accuracy for three linear axes was defined as a term of multi-axes motion in the revision of ISO 230-1. As a matter of course, the volumetric accuracy is closely connecte...
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Autor*in:	Akinori SAITO [verfasserIn] Hayato AKAIKE [verfasserIn]

Format:	E-Artikel
Sprache:	Japanisch

Erschienen:	2019

Schlagwörter:	volumetric accuracy positioning deviation angulaer deviation linear axis error motion machining center laser interferometer

Übergeordnetes Werk:	In: Nihon Kikai Gakkai ronbunshu - The Japan Society of Mechanical Engineers, 2022, 85(2019), 880, Seite 19-00222-19-00222
Übergeordnetes Werk:	volume:85 ; year:2019 ; number:880 ; pages:19-00222-19-00222

Links:	Link aufrufen Link aufrufen Link aufrufen Journal toc

DOI / URN:	10.1299/transjsme.19-00222

Katalog-ID:	DOAJ026008238

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language	Japanese
source	In Nihon Kikai Gakkai ronbunshu 85(2019), 880, Seite 19-00222-19-00222 volume:85 year:2019 number:880 pages:19-00222-19-00222
sourceStr	In Nihon Kikai Gakkai ronbunshu 85(2019), 880, Seite 19-00222-19-00222 volume:85 year:2019 number:880 pages:19-00222-19-00222
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institution	findex.gbv.de
topic_facet	volumetric accuracy positioning deviation angulaer deviation linear axis error motion machining center laser interferometer Mechanical engineering and machinery Engineering machinery, tools, and implements
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callnumber-first	T - Technology
author	Akinori SAITO
spellingShingle	Akinori SAITO misc TJ1-1570 misc TA213-215 misc volumetric accuracy misc positioning deviation misc angulaer deviation misc linear axis misc error motion misc machining center misc laser interferometer misc Mechanical engineering and machinery misc Engineering machinery, tools, and implements Estimation of volumetric accuracy based on linear error motion in machining centers
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topic_title	TJ1-1570 TA213-215 Estimation of volumetric accuracy based on linear error motion in machining centers volumetric accuracy positioning deviation angulaer deviation linear axis error motion machining center laser interferometer
topic	misc TJ1-1570 misc TA213-215 misc volumetric accuracy misc positioning deviation misc angulaer deviation misc linear axis misc error motion misc machining center misc laser interferometer misc Mechanical engineering and machinery misc Engineering machinery, tools, and implements
topic_unstemmed	misc TJ1-1570 misc TA213-215 misc volumetric accuracy misc positioning deviation misc angulaer deviation misc linear axis misc error motion misc machining center misc laser interferometer misc Mechanical engineering and machinery misc Engineering machinery, tools, and implements
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title	Estimation of volumetric accuracy based on linear error motion in machining centers
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title_full	Estimation of volumetric accuracy based on linear error motion in machining centers
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title_sort	estimation of volumetric accuracy based on linear error motion in machining centers
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title_auth	Estimation of volumetric accuracy based on linear error motion in machining centers
abstract	ISO230-1, an international standard of test code for machine tools, has been revised for the first time in 16 years. A volumetric accuracy for three linear axes was defined as a term of multi-axes motion in the revision of ISO 230-1. As a matter of course, the volumetric accuracy is closely connected with the linear axis error motions in three axis machining centers. The error motions of linear axes have been checked in compliance with ISO 10791-1 and -4 for a long time. However, the relationship between the measured error motions of linear axis and volumetric accuracy has not become clear. In this paper, the positional deviations of lattice points within the entire working volume of machining centers were measured via laser interferometer. Positional deviations were estimated by using a mathematical model in consideration of measurement coordinate systems and the tested linear error motions. As the results, the estimated positional deviations of the volumetric accuracy corresponded reasonably well with the measured deviations in a small machining center.
abstractGer	ISO230-1, an international standard of test code for machine tools, has been revised for the first time in 16 years. A volumetric accuracy for three linear axes was defined as a term of multi-axes motion in the revision of ISO 230-1. As a matter of course, the volumetric accuracy is closely connected with the linear axis error motions in three axis machining centers. The error motions of linear axes have been checked in compliance with ISO 10791-1 and -4 for a long time. However, the relationship between the measured error motions of linear axis and volumetric accuracy has not become clear. In this paper, the positional deviations of lattice points within the entire working volume of machining centers were measured via laser interferometer. Positional deviations were estimated by using a mathematical model in consideration of measurement coordinate systems and the tested linear error motions. As the results, the estimated positional deviations of the volumetric accuracy corresponded reasonably well with the measured deviations in a small machining center.
abstract_unstemmed	ISO230-1, an international standard of test code for machine tools, has been revised for the first time in 16 years. A volumetric accuracy for three linear axes was defined as a term of multi-axes motion in the revision of ISO 230-1. As a matter of course, the volumetric accuracy is closely connected with the linear axis error motions in three axis machining centers. The error motions of linear axes have been checked in compliance with ISO 10791-1 and -4 for a long time. However, the relationship between the measured error motions of linear axis and volumetric accuracy has not become clear. In this paper, the positional deviations of lattice points within the entire working volume of machining centers were measured via laser interferometer. Positional deviations were estimated by using a mathematical model in consideration of measurement coordinate systems and the tested linear error motions. As the results, the estimated positional deviations of the volumetric accuracy corresponded reasonably well with the measured deviations in a small machining center.
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title_short	Estimation of volumetric accuracy based on linear error motion in machining centers
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Estimation of volumetric accuracy based on linear error motion in machining centers

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