iTeh StandardsiTeh Standards
EURUSD
Your shopping cart is empty.
ISO

ISO 230-10:2022

(Main)

Test code for machine tools — Part 10: Determination of the measuring performance of probing systems of numerically controlled machine tools

Test code for machine tools — Part 10: Determination of the measuring performance of probing systems of numerically controlled machine tools

This document specifies test procedures to evaluate the measuring performance of probing systems integrated with a numerically controlled machine tool. Test procedures for touch trigger probing systems and scanning probing systems operating in discrete-point measurement mode are specified in 7.1. Test procedures are specified for scanning probing systems in 7.2, for bore gauge systems in 7.3, for contacting tool measuring systems in 8.1, and for non-contacting tool measuring systems using the laser light barrier principle in 8.2. The evaluation of the performance of the machine tool, used as a coordinate measuring machine (CMM), is outside the scope of this document. Such performance evaluation involves traceability issues, is strongly influenced by machine tool geometric accuracy and can, in addition to the machine tool probing system tests specified in this document, be evaluated according to ISO 10360-2 and ISO 10360-5. Descriptions of test procedures in this document are referred to machining centres. However, tests apply in principle to most NC machine tools.

Code d'essai des machines-outils — Partie 10: Détermination des performances de mesure des systèmes de palpage des machines-outils à commande numérique

Le présent document spécifie les modes opératoires d'essai pour évaluer les performances de mesure des systèmes de palpage intégrés avec une machine-outil à commande numérique. Les modes opératoires d'essai pour les systèmes de palpage à détente et les systèmes de palpage de scanning opérant en mode de mesurage de points discrets sont spécifiés en 7.1. Les modes opératoires d'essai sont spécifiés pour les systèmes de palpage de scanning en 7.2, pour les systèmes de comparateur d'alésage en 7.3, pour les systèmes de mesure d'outil à contact en 8.1, et pour les systèmes de mesure d'outil sans contact utilisant le principe de barrière optique laser en 8.2. L'évaluation des performances de la machine-outil utilisée comme machine à mesurer tridimensionnelle (MMT) ne fait pas partie du domaine d'application du présent document. L'évaluation de telles performances implique des problèmes de traçabilité, est fortement influencée par l'exactitude géométrique de la machine-outil et peuvent, en plus d'être soumises aux essais du système de palpage de la machine-outil spécifiés dans le présent document, être évaluées conformément à l’ISO 10360-2 et l’ISO 10360-5. Les modes opératoires d'essai décrits dans le présent document se réfèrent aux centres d’usinage. Toutefois, les essais s’appliquent en principe à la plupart des machines-outils CN.

General Information

Status
Published
Publication Date
23-Mar-2022
ICS
25.080.01 - Machine tools in general
Technical Committee
ISO/TC 39/SC 2 - Test conditions for metal cutting machine tools
Drafting Committee
ISO/TC 39/SC 2 - Test conditions for metal cutting machine tools
Current Stage
6060 - International Standard published
Start Date
24-Mar-2022
Due Date
02-Jul-2022
Completion Date
24-Mar-2022
Ref Project

Relations

Revises
ISO 230-10:2016 - Test code for machine tools — Part 10: Determination of the measuring performance of probing systems of numerically controlled machine tools
Effective Date
23-Apr-2020

Buy Standard

ISO 230-10:2022 - Test code for machine tools — Part 10: Determination of the measuring performance of probing systems of numerically controlled machine tools Released:3/24/2022ISO 230-10:2022 - Test code for machine tools — Part 10: Determination of the measuring performance of probing systems of numerically controlled machine tools Released:3/24/2022
PreviousNext
Standard
ISO 230-10:2022 - Test code for machine tools — Part 10: Determination of the measuring performance of probing systems of numerically controlled machine tools Released:3/24/2022
English language
68 pages
sale 15% off
Preview
sale 15% off
Preview
ISO 230-10:2022 - Test code for machine tools — Part 10: Determination of the measuring performance of probing systems of numerically controlled machine tools Released:3/24/2022ISO 230-10:2022 - Test code for machine tools — Part 10: Determination of the measuring performance of probing systems of numerically controlled machine tools Released:3/24/2022
PreviousNext
Standard
ISO 230-10:2022 - Test code for machine tools — Part 10: Determination of the measuring performance of probing systems of numerically controlled machine tools Released:3/24/2022
French language
77 pages
sale 15% off
Preview
sale 15% off
Preview
ISO/PRF 230-10 - Test code for machine toolsISO/PRF 230-10 - Test code for machine tools
PreviousNext
Draft
ISO/PRF 230-10 - Test code for machine tools
English language
67 pages
sale 15% off
Preview
sale 15% off
Preview

Standards Content (Sample)

INTERNATIONAL ISO
STANDARD 230-10
Third edition
2022-03
Test code for machine tools —
Part 10:
Determination of the measuring
performance of probing systems of
numerically controlled machine tools
Code d'essai des machines-outils —
Partie 10: Détermination des performances de mesure des systèmes de
palpage des machines-outils à commande numérique
Reference number
ISO 230-10:2022(E)
© ISO 2022

---------------------- Page: 1 ----------------------
ISO 230-10:2022(E)
COPYRIGHT PROTECTED DOCUMENT
© ISO 2022
All rights reserved. Unless otherwise specified, or required in the context of its implementation, no part of this publication may
be reproduced or utilized otherwise in any form or by any means, electronic or mechanical, including photocopying, or posting on
the internet or an intranet, without prior written permission. Permission can be requested from either ISO at the address below
or ISO’s member body in the country of the requester.
ISO copyright office
CP 401 • Ch. de Blandonnet 8
CH-1214 Vernier, Geneva
Phone: +41 22 749 01 11
Email: copyright@iso.org
Website: www.iso.org
Published in Switzerland
ii
  © ISO 2022 – All rights reserved

---------------------- Page: 2 ----------------------
ISO 230-10:2022(E)
Contents Page
Foreword .v
Introduction . vi
1 Scope . 1
2 Normative references . 1
3 Terms and definitions . 1
3.1 General terms . 2
3.2 Terms relating to the probing system . 2
3.3 Terms relating to probing performance . 7
3.4 Terms relating to scanning probes . 8
4 Symbols . 9
5 Preliminary remarks .12
5.1 Influences on the measurement performance of the probing system .12
5.2 Measurement units .12
5.3 Reference to ISO 230-1 . 13
5.4 Recommended instrumentation and test equipment .13
5.5 Machine conditions prior to testing . 13
5.6 Testing sequence . 13
5.7 Tests to be performed .13
5.8 Sources of test uncertainty .13
5.9 Reporting of test results . 14
6 Thermal influences .15
6.1 General . 15
6.2 Environmental temperature variation error (ETVE) test. 15
6.3 Other thermal distortion tests . 15
7 Probing of workpiece .16
7.1 Touch trigger probes . 16
7.1.1 General . 16
7.1.2 Probing repeatability . 17
7.1.3 Stylus tip offset test . 18
7.1.4 Probing-tool location repeatability test . 19
7.1.5 2D probing error test . 20
7.1.6 3D probing error test . 21
7.1.7 Workpiece position and orientation tests . 23
7.1.8 Combined workpiece machining and location test .29
7.1.9 Time delay variation tests .30
7.1.10 Feature size measurement performance tests . 35
7.2 Scanning probes . 37
7.2.1 General . 37
7.2.2 Filtering parameters . 37
7.2.3 Scanning 2D performance test . 37
7.2.4 Scanning 3D performance test.39
7.3 Bore gauge . 42
7.3.1 General . 42
7.3.2 Characteristics of bore gauge systems . 42
7.3.3 Preliminary remarks . 45
7.3.4 Determination of measurement repeatability of the system .46
8 Probing of tools .46
8.1 Touch trigger probes .46
8.1.1 General .46
8.1.2 Tool-setting system qualification . 47
8.1.3 Tool-setting repeatability . 47
iii
© ISO 2022 – All rights reserved

---------------------- Page: 3 ----------------------
ISO 230-10:2022(E)
8.2 Non-contacting laser light barrier tool measuring system .50
8.2.1 General .50
8.2.2 Typical functions of a laser light barrier system . 51
8.2.3 Differences between laser light barrier systems and contacting tool
measuring systems . 51
8.2.4 Laser light barrier tool measuring system . 51
8.2.5 Factors influencing the uncertainty of tool dimensional measurement .54
8.2.6 Preliminary remarks .54
8.2.7 Verification of detection tasks .54
8.2.8 Verification of measurement tasks . 59
8.2.9 Reports of test results .66
Bibliography .68
iv
  © ISO 2022 – All rights reserved

---------------------- Page: 4 ----------------------
ISO 230-10:2022(E)
Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards
bodies (ISO member bodies). The work of preparing International Standards is normally carried out
through ISO technical committees. Each member body interested in a subject for which a technical
committee has been established has the right to be represented on that committee. International
organizations, governmental and non-governmental, in liaison with ISO, also take part in the work.
ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of
electrotechnical standardization.
The procedures used to develop this document and those intended for its further maintenance are
described in the ISO/IEC Directives, Part 1. In particular, the different approval criteria needed for the
different types of ISO documents should be noted. This document was drafted in accordance with the
editorial rules of the ISO/IEC Directives, Part 2 (see www.iso.org/directives).
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. ISO shall not be held responsible for identifying any or all such patent rights. Details of
any patent rights identified during the development of the document will be in the Introduction and/or
on the ISO list of patent declarations received (see www.iso.org/patents).
Any trade name used in this document is information given for the convenience of users and does not
constitute an endorsement.
For an explanation of the voluntary nature of standards, the meaning of ISO specific terms and
expressions related to conformity assessment, as well as information about ISO's adherence to
the World Trade Organization (WTO) principles in the Technical Barriers to Trade (TBT) see
www.iso.org/iso/foreword.html.
This document was prepared by Technical Committee ISO/TC 39, Machine tools, Subcommittee SC 2,
Test conditions for metal cutting machine tools.
This third edition cancels and replaces the second edition (ISO 230-10:2016), which has been technically
revised.
The main changes compared to the previous edition are as follows:
— The document scope has been revised to include specification in 7.2, 7.3 and 8.2;
— a definition for laser light barrier principle is added in 3.2.12;
— Figures 1, 4, 6 and 7 have been revised;
— Symbols of variables in Formulae (3) and (4) have been changed to be consistent with symbols in
8.2.8.4.1;
— a new subclause 7.3 on "Determination of the performance of bore gauge systems" has been added.
— a new subclause 8.2 on "Non-contacting laser light barrier tool measuring systems" has been added.
A list of all parts in the ISO 230 series can be found on the ISO website.
Any feedback or questions on this document should be directed to the user’s national standards body. A
complete listing of these bodies can be found at www.iso.org/members.html.
v
© ISO 2022 – All rights reserved

---------------------- Page: 5 ----------------------
ISO 230-10:2022(E)
Introduction
The purpose of ISO 230 (all parts) is to standardize methods of testing the accuracy of machine tools,
excluding portable power tools.
This document specifies test procedures to evaluate the measuring performance of contacting and non-
contacting probing systems integrated with CNC machine tools. The test procedures are not intended to
distinguish between the various causes of errors. They intend to demonstrate the combined influence
of the environment, machine tool, probing system and probing software on the measuring performance.
The results of these tests do not reflect on the performance of the machine tool in a metal cutting mode.
When the tests are required for acceptance purposes, it is up to the user to choose the tests that are of
interest, in agreement with the manufacturer/supplier.
The results of these tests do not reflect on the performance of the machine tool used as a coordinate
measuring machine (CMM). Such performance involves traceability issues and it is intended that they
be evaluated based on methods of ISO 10360-2 and ISO 10360-5.
Test procedures to measure performance with touch trigger probes are given in 7.1 and 8.1, scanning
probes in 7.2, bore gauge systems in 7.3. and with non-contacting tool measuring systems applying
laser light barrier principle in 8.2.
Numerically controlled machine tools can apply probing systems in machining process applications,
such as
— identification that the correct workpiece has been loaded before machining,
— location and/or alignment of the workpiece,
— dimensional measurement of the workpiece after machining, but while still on the machine tool,
— measurement of the position and orientation of the machine tool rotary axes,
— measurement and setting of the cutting tool (radius, length and offset of the tool), and
— detection of tool breakage.
vi
  © ISO 2022 – All rights reserved

---------------------- Page: 6 ----------------------
INTERNATIONAL STANDARD ISO 230-10:2022(E)
Test code for machine tools —
Part 10:
Determination of the measuring performance of probing
systems of numerically controlled machine tools
1 Scope
This document specifies test procedures to evaluate the measuring performance of probing systems
integrated with a numerically controlled machine tool. Test procedures for touch trigger probing
systems and scanning probing systems operating in discrete-point measurement mode are specified
in 7.1. Test procedures are specified for scanning probing systems in 7.2, for bore gauge systems in 7.3,
for contacting tool measuring systems in 8.1, and for non-contacting tool measuring systems using the
laser light barrier principle in 8.2.
The evaluation of the performance of the machine tool, used as a coordinate measuring machine (CMM),
is outside the scope of this document. Such performance evaluation involves traceability issues, is
strongly influenced by machine tool geometric accuracy and can, in addition to the machine tool probing
system tests specified in this document, be evaluated according to ISO 10360-2 and ISO 10360-5.
Descriptions of test procedures in this document are referred to machining centres. However, tests
apply in principle to most NC machine tools.
2 Normative references
The following documents are referred to in the text in such a way that some or all of their content
constitutes requirements of this document. For dated references, only the edition cited applies. For
undated references, the latest edition of the referenced document (including any amendments) applies.
ISO 230-1:2012, Test code for machine tools — Part 1: Geometric accuracy of machines operating under
no-load or quasi-static conditions
ISO 230-3:2020, Test code for machine tools — Part 3: Determination of thermal effects
3 Terms and definitions
For the purposes of this document, the following terms and definitions apply.
ISO and IEC maintain terminological databases for use in standardization at the following addresses:
— IEC Electropedia: available at https:// www .electropedia .org/
— ISO Online browsing platform: available at https:// www .iso .org/ obp
NOTE In measuring mode, machine tools are used like CMMs. Therefore, definitions for probing systems
performance tests for CMMs apply also to machine tools. However, since not all machine tool users are familiar
with the use of CMMs, this document provides definitions specifically with machine tools in mind, making sure
that they do not create any conflicts with CMM definitions.
1
© ISO 2022 – All rights reserved

---------------------- Page: 7 ----------------------
ISO 230-10:2022(E)
3.1 General terms
3.1.1
machine coordinate system
MCS
coordinate system fixed with respect to physical or calculated axes of a machine tool
[SOURCE: ISO 10360-1:2000, 2.5 — modified, reference to "machine tool" instead of "machine coordinate
system".]
3.1.2
workpiece coordinate system
WCS
coordinate system fixed with respect to a workpiece
[SOURCE: ISO 10360-1:2000, 2.4]
3.1.3
measuring volume
three-dimensional space encompassing all linear coordinates that are accessible for measurement on
the machine tool
3.2 Terms relating to the probing system
3.2.1
probe
device that senses a surface and generates the signal(s) during probing
Note 1 to entry: There are several types of probes used on machine tools and they use different technologies to
achieve the same aim.
Note 2 to entry: Probes can either be “switching” types or “proportional” types. These can be available as either
“contacting” or “non-contacting” systems.
[SOURCE: ISO 10360-1:2000, 3.1 — modified, Note 1 to entry and Note 2 to entry have been added.]
3.2.1.1
contacting probe
probe (3.2.1) that needs material contact with a surface being measured (detected) in order to function
EXAMPLE Electrical circuit breakage, strain gauge.
Note 1 to entry: The contacting feed speed applied to obtain the material contact can influence the performance
of such probes. Proper contacting feed speed is specified in the manufacturer/supplier instructions.
Note 2 to entry: For best performance, the contacting feed speed applied during measurement is the same as the
feed speed applied during probe qualification.
Note 3 to entry: Typical contacting probes that operate in the − X, + X, − Y, + Y and − Z directions, and in any
combination of such directions, are sometimes referred to as 2,5D probes. These contacting probes do not allow
for (or allow for very limited) operation in the + Z direction.
Note 4 to entry: Measurement in the + Z direction capability can be obtained by the use of stylus systems
equipped with multiple styli, as depicted in Figure 1, where stylus tip 2 (moving in the + Z direction) contacts
the workpiece surface and causes the probe to generate the signal as a consequence of the deflection in the − Z
direction.
3.2.1.2
non-contacting probe
probe (3.2.1) that needs no material contact with a surface being measured in order to function
EXAMPLE Optical and laser systems, inductive and capacitive systems.
2
  © ISO 2022 – All rights reserved

---------------------- Page: 8 ----------------------
ISO 230-10:2022(E)
Note 1 to entry: In this document, only laser light barrier systems as a non-contacting probing system is included.
3.2.1.3
switching probe
touch trigger probe
probe (3.2.1) that gives a binary signal as a result of detection of a surface
3.2.1.4
laser light barrier principle
principle utilising a laser light transmitter and an opto-electronic receiver to detect light interruption
for performing non-contacting measurement tasks
3.2.2
probing
to probe
measurement action that results in the determination of values (e.g., coordinate values, length values,
false/true values)
Note 1 to entry: Probing associated with the measurement of cutting tools does not necessarily result in the
determination of coordinate values.
Note 2 to entry: Probing associated with tool breakage detection results in the determination of a false/true
state.
[SOURCE: ISO 10360-1:2000, 2.7 — modified, definition has been partly modified by explaining “values”,
Note 1 to entry and Note 2 to entry have been added.]
3.2.2.1
1D probing
measurement allowing only for probing motion parallel to one machine coordinate system axis or to
one workpiece coordinate system axis
3.2.2.2
2D probing
measurement allowing for probing motion along a vector in a plane
Note 1 to entry: Independent qualification for stylus tip 1 and for stylus tip 2, and additional tests, are specified
in ISO 10360-5.
3
© ISO 2022 – All rights reserved

---------------------- Page: 9 ----------------------
ISO 230-10:2022(E)
Key
1 stylus tip 1 4 tool holder
2 stylus tip 2 5 probe
3 spindle 6 workpiece
Figure 1 — Probing-tool equipped with 2 styli
3.2.2.3
3D probing
measurement allowing for probing motion along any vector in space
3.2.3
probing system
system consisting of a probe (3.2.1), contacting probe (3.2.1.1) or non-contacting probe (3.2.1.2), signal
transmission system (e.g. optical, radio, wire), signal conditioning hardware, the probing hardware and
software and, where present, probe extensions, probe changing system, stylus and stylus extensions,
when used in conjunction with a suitable numerically controlled machine tool
Note 1 to entry: Some of the tests specified in this document are referred to probing systems consisting of
contacting probes equipped with a single stylus system that is parallel to the machine tool spindle axis average
line, as depicted in Figure 2. For applications using stylus systems equipped with multiple styli (see Figure 1),
and for application where measurement is performed by using multiple orientations of the spindle axis average
line with respect to the WCS, additional tests are specified in ISO 10360-5.
[SOURCE: ISO 10360-1:2000, 2.6 — modified, Note 1 to entry has been added.]
3.2.4
probing system qualification
establishment of the parameters of a probing system (based on manufacturer/supplier instructions)
necessary for subsequent measurements
Note 1 to entry: Effective stylus tip diameter (3.2.6) and location of the stylus tip centre with respect to spindle
axis average line are typical parameters established by probing system qualification.
Note 2 to entry: Suppliers’ technical literature sometimes refers to probing system qualification with the
expression “probing system calibration”; this expression is not appropriate.
[SOURCE: ISO 10360-1:2000, 3.7 — modified, Note 1 to entry and Note 2 to entry have been added.]
4
  © ISO 2022 – All rights reserved

---------------------- Page: 10 ----------------------
ISO 230-10:2022(E)
3.2.5
pre-travel
distance between the point of first material contact of the probe stylus tip with the surface being
detected and the point where the probe signal is generated
Note 1 to entry: Pre-travel is affected by probe construction, probing direction, probing speed, switching force,
stylus system length and compliance, time delay between probing signal and machine tool position transducer
read-out, etc.
Note 2 to entry: Pre-travel variation (commonly referred to as “lobing”), under specified probing conditions, is a
very important probing system characteristic.
Note 3 to entry: Some probe qualification techniques can significantly reduce the effects of probing system pre-
travel variation.
3.2.6
effective stylus tip diameter
effective stylus tip size
stylus tip dimension used by some probing software to determine feature size from the measurement
data
Note 1 to entry: The effective stylus tip diameter (size) is associated with probing system performance and is
determined by appropriate probing system qualification, rather than by simply measuring the stylus tip size.
3.2.7
stylus tip
physical element that establishes the contact with the object to measure
[SOURCE: ISO 10360-1:2000, 4.2 — modified, "workpiece" replaced with "object to measure".]
3.2.8
stylus system
system composed of a stylus and stylus extension(s) (if any)
[SOURCE: ISO 10360-1:2000, 4.4 — modified, Note 1 to entry has been added.]
Note 1 to entry: Stylus extensions can reduce stylus system stiffness and can adversely influence probing system
performance. Therefore, performance tests are carried out using the particular stylus extension(s) of interest.
3.2.9
stylus system length
distance from the centre of the stylus tip to the feature interfacing with the probe
of the stylus system (3.2.8)
Note 1 to entry: See Figure 2.
Note 2 to entry: Some probing systems (3.2.3) establish the stylus system length as the distance from the centre
of the stylus tip and others from the most protruding point of the stylus tip.
5
© ISO 2022 – All rights reserved

---------------------- Page: 11 ----------------------
ISO 230-10:2022(E)
Key
1 stylus tip (3.2.7)
2 stylus
3 stylus extension (3.2.9)
a stylus system length
Figure 2 — Stylus system length
3.2.10
probing-tool
device consisting of a probe and its stylus system (3.2.8), attached to a tool holder
Note 1 to entry: See Figure 2.
3.2.11
probing-tool length
distance from the most protruding point of the stylus tip to the machine tool spindle reference surface
or gauge line that connects to the probing-tool (3.2.10)
Note 1 to entry: See Figure 3.
Note 2 to entry: Some probing systems establish the probing-tool length as the distance from the centre of the
stylus tip to the machine tool spindle reference surface that connects to the probing-tool and others from the
most protruding point of the stylus tip to the machine tool spindle reference surface that connects to the probing-
tool.
Note 3 to entry: For solid-shank-type tool holders, the spindle reference surface is at the spindle cone gauge line.
For other tool holders (hollow shank), the spindle reference surface is the spindle face.
Note 4 to entry: Typically, the probing system is handled by the machine controller as a tool, therefore, the overall
length is considered.
Note 5 to entry: The procedure for establishing the length of the probing-tool is specified in manufacturer/
supplier instructions.
6
  © ISO 2022 – All rights reserved

---------------------- Page: 12 ---------
...

NORME ISO
INTERNATIONALE 230-10
Troisième édition
2022-03
Code d'essai des machines-outils —
Partie 10:
Détermination des performances
de mesure des systèmes de palpage
des machines-outils à commande
numérique
Test code for machine tools —
Part 10: Determination of the measuring performance of probing
systems of numerically controlled machine tools
Numéro de référence
ISO 230-10:2022(F)
© ISO 2022

---------------------- Page: 1 ----------------------
ISO 230-10:2022(F)
DOCUMENT PROTÉGÉ PAR COPYRIGHT
© ISO 2022
Tous droits réservés. Sauf prescription différente ou nécessité dans le contexte de sa mise en œuvre, aucune partie de cette
publication ne peut être reproduite ni utilisée sous quelque forme que ce soit et par aucun procédé, électronique ou mécanique,
y compris la photocopie, ou la diffusion sur l’internet ou sur un intranet, sans autorisation écrite préalable. Une autorisation peut
être demandée à l’ISO à l’adresse ci-après ou au comité membre de l’ISO dans le pays du demandeur.
ISO copyright office
Case postale 401 • Ch. de Blandonnet 8
CH-1214 Vernier, Genève
Tél.: +41 22 749 01 11
E-mail: copyright@iso.org
Web: www.iso.org
Publié en Suisse
ii
  © ISO 2022 – Tous droits réservés

---------------------- Page: 2 ----------------------
ISO 230-10:2022(F)
Sommaire Page
Avant-propos .v
Introduction . vi
1 Domaine d'application .1
2 Références normatives .1
3 Termes et définitions . 1
3.1 Termes généraux . 2
3.2 Termes liés au système de palpage . 2
3.3 Termes relatifs au performance de palpage . 7
3.4 Termes relatifs aux palpeurs de scanning . 8
4 Symboles . 9
5 Remarques préliminaires .12
5.1 Influences sur la performance de mesure du système de palpage .12
5.2 Unités de mesure .13
5.3 Référence à l'ISO 230-1 . 13
5.4 Instruments et équipements d'essai recommandés . 13
5.5 État de la machine avant essai .13
5.6 Ordre des essais . 13
5.7 Essais à réaliser . 13
5.8 Sources d'incertitude d'essai . 14
5.9 Consignation des résultats d'essai . 14
6 Influences thermiques .15
6.1 Généralités . 15
6.2 Essai d'erreur de variation de température ambiante (ETVE) .15
6.3 Autres essais de distorsion thermique . 16
7 Palpage d'une pièce .16
7.1 Palpeurs de contact à détente . 16
7.1.1 Généralités . 16
7.1.2 Répétabilité de palpage . 17
7.1.3 Essai de constante de palpage . 19
7.1.4 Essai de répétabilité de position de l'outil de palpage . 19
7.1.5 Essai d'erreur de palpage 2D . 20
7.1.6 Essai d'erreur de palpage 3D . 22
7.1.7 Essais de position et d'orientation de la pièce .23
7.1.8 Essai combiné d'usinage et de position de la pièce . 31
7.1.9 Essais de variation de la temporisation . 33
7.1.10 Essais de performance du mesurage de la taille de l'élément .39
7.2 Palpeurs de scanning . 41
7.2.1 Généralités . 41
7.2.2 Paramètres de filtrage . 42
7.2.3 Essai de performance de scanning 2D . 42
7.2.4 Essai de performance de scanning 3D .44
7.3 Comparateur d'alésage .48
7.3.1 Généralités .48
7.3.2 Caractéristiques des systèmes de comparateur d'alésage .48
7.3.3 Remarques préliminaires . 52
7.3.4 Détermination de la répétabilité de mesure du système .53
8 Palpage des outils .53
8.1 Palpeurs de contact à détente . 53
8.1.1 Généralités .53
8.1.2 Qualification du système de réglage d'outil .54
8.1.3 Répétabilité de réglage de l’outil .54
iii
© ISO 2022 – Tous droits réservés

---------------------- Page: 3 ----------------------
ISO 230-10:2022(F)
8.2 Système de mesure d'outil à barrière optique laser sans contact .58
8.2.1 Généralités .58
8.2.2 Fonction typiques du système de barrière optique laser . 59
8.2.3 Différences entre les systèmes de barrière optique laser et les systèmes de
mesure d'outil à contact . 59
8.2.4 Système de mesure d'outil à barrière optique laser . 59
8.2.5 Facteurs influençant l’incertitude de la mesure dimensionnelle de l’outil . 62
8.2.6 Remarques préliminaires .63
8.2.7 Contrôle des tâches de détection .63
8.2.8 Contrôle des tâches de mesurage .68
8.2.9 Consignation des résultats d'essai . 76
Bibliographie .77
iv
  © ISO 2022 – Tous droits réservés

---------------------- Page: 4 ----------------------
ISO 230-10:2022(F)
Avant-propos
L'ISO (Organisation internationale de normalisation) est une fédération mondiale d'organismes
nationaux de normalisation (comités membres de l'ISO). L'élaboration des Normes internationales est
en général confiée aux comités techniques de l'ISO. Chaque comité membre intéressé par une étude
a le droit de faire partie du comité technique créé à cet effet. Les organisations internationales,
gouvernementales et non gouvernementales, en liaison avec l'ISO participent également aux travaux.
L'ISO collabore étroitement avec la Commission électrotechnique internationale (IEC) en ce qui
concerne la normalisation électrotechnique.
Les procédures utilisées pour élaborer le présent document et celles destinées à sa mise à jour sont
décrites dans les Directives ISO/IEC, Partie 1. Il convient, en particulier de prendre note des différents
critères d'approbation requis pour les différents types de documents ISO. Le présent document
a été rédigé conformément aux règles de rédaction données dans les Directives ISO/IEC, Partie 2
(voir www.iso.org/directives).
L'attention est attirée sur le fait que certains des éléments du présent document peuvent faire l'objet de
droits de propriété intellectuelle ou de droits analogues. L'ISO ne saurait être tenue pour responsable
de ne pas avoir identifié de tels droits de propriété et averti de leur existence. Les détails concernant
les références aux droits de propriété intellectuelle ou autres droits analogues identifiés lors de
l'élaboration du document sont indiqués dans l'Introduction et/ou dans la liste des déclarations de
brevets reçues par l'ISO (voir www.iso.org/brevets).
Les appellations commerciales éventuellement mentionnées dans le présent document sont données
pour information, par souci de commodité, à l’intention des utilisateurs et ne sauraient constituer un
engagement.
Pour une explication de la nature volontaire des normes, la signification des termes et expressions
spécifiques de l'ISO liés à l'évaluation de la conformité, ou pour toute information au sujet de l'adhésion
de l'ISO aux principes de l’Organisation mondiale du commerce (OMC) concernant les obstacles
techniques au commerce (OTC), voir le lien suivant: www.iso.org/iso/fr/avant-propos.html.
Le présent document a été élaboré par le comité technique ISO/TC 39, Machines-outils, sous-comité SC 2,
Conditions de réception des machines travaillant par enlèvement de métal.
Cette troisième édition annule et remplace la deuxième édition (ISO 230-10:2016), qui a fait l'objet d'une
révision technique.
Les principales modifications par rapport à l'édition précédente sont les suivantes:
— le domaine d’application du document a été révisé afin d'inclure une spécification en 7.2, 7.3 et 8.2;
— une définition du principe de barrière optique laser est ajoutée en 3.2.12;
— les Figures 1, 4, 6 et7 ont été révisées;
— les symboles des variables dans les Formules (3) et (4) ont été changés afin de correspondre aux
symboles en 8.2.8.4.1;
— un nouveau paragraphe 7.3 sur la «Détermination de la performance des systèmes de comparateur
d'alésage» a été ajouté;
— un nouveau paragraphe 8.2 sur les «Systèmes de mesure d'outil à barrière optique laser sans
contact» a été ajouté.
Une liste de toutes les parties de la série ISO 230 se trouve sur le site Web de l’ISO.
Il convient que l’utilisateur adresse tout retour d’information ou toute question concernant le présent
document à l’organisme national de normalisation de son pays. Une liste exhaustive desdits organismes
se trouve à l’adresse www.iso.org/fr/members.html.
v
© ISO 2022 – Tous droits réservés

---------------------- Page: 5 ----------------------
ISO 230-10:2022(F)
Introduction
L'objet de l'ISO 230 (toutes les parties) est de normaliser des méthodes d'essai pour la vérification de
l'exactitude des machines-outils, à l'exception des machines-outils électriques portatives.
Le présent document spécifie les modes opératoires d'essai pour évaluer les performances de mesure
des systèmes de palpage à contact ou sans contact intégrés à des machines-outils à commande
numérique (CN). Les modes opératoires d'essai ne sont pas destinés à différencier les différentes causes
d'erreurs. Elles visent à démontrer l'influence combinée de l'environnement, de la machine-outil, du
système de palpage et du logiciel de palpage sur les performances de mesure.
Les résultats de ces essais n'ont aucune incidence sur les performances de la machine-outil en mode
enlèvement de métal. Lorsque des essais de réception sont spécifiés, il incombe à l'utilisateur de choisir
les essais pertinents, en concertation avec le fabricant/le fournisseur.
Les résultats de ces essais ne reflètent pas les performances de la machine-outil utilisée comme machine
à mesurer tridimensionnelle (MMT). Ces performances impliquent des problèmes de traçabilité et il est
prévu de les évaluer selon les méthodes de l'ISO 10360-2 et de l'ISO 10360-5.
Les modes opératoires d'essai pour mesurer la performance avec des palpeurs à détente sont donnés
en 7.1 et 8.1, des palpeurs de scanning en 7.2, des systèmes de comparateur d'alésage en 7.3, et avec des
systèmes de mesure d’outil sans contact appliquant le principe de barrière optique laser en 8.2.
Les machines-outils à commande numérique peuvent utiliser des systèmes de palpage dans des
applications d'usinage telles que
— l'identification permettant de vérifier que la bonne pièce a été chargée avant l'usinage,
— la position et/ou l'alignement de la pièce,
— le mesurage dimensionnel de la pièce après usinage, la pièce étant encore sur la machine-outil,
— le mesurage de la position et de l'orientation des axes rotatifs de la machine-outil,
— le mesurage et le réglage de l'outil coupant (rayon, longueur et décalage de l'outil), et
— la détection des bris d'outil.
vi
  © ISO 2022 – Tous droits réservés

---------------------- Page: 6 ----------------------
NORME INTERNATIONALE ISO 230-10:2022(F)
Code d'essai des machines-outils —
Partie 10:
Détermination des performances de mesure des systèmes
de palpage des machines-outils à commande numérique
1 Domaine d'application
Le présent document spécifie les modes opératoires d'essai pour évaluer les performances de mesure des
systèmes de palpage intégrés avec une machine-outil à commande numérique. Les modes opératoires
d'essai pour les systèmes de palpage à détente et les systèmes de palpage de scanning opérant en mode
de mesurage de points discrets sont spécifiés en 7.1. Les modes opératoires d'essai sont spécifiés pour
les systèmes de palpage de scanning en 7.2, pour les systèmes de comparateur d'alésage en 7.3, pour
les systèmes de mesure d'outil à contact en 8.1, et pour les systèmes de mesure d'outil sans contact
utilisant le principe de barrière optique laser en 8.2.
L'évaluation des performances de la machine-outil utilisée comme machine à mesurer tridimensionnelle
(MMT) ne fait pas partie du domaine d'application du présent document. L'évaluation de telles
performances implique des problèmes de traçabilité, est fortement influencée par l'exactitude
géométrique de la machine-outil et peuvent, en plus d'être soumises aux essais du système de palpage
de la machine-outil spécifiés dans le présent document, être évaluées conformément à l’ISO 10360-2 et
l’ISO 10360-5.
Les modes opératoires d'essai décrits dans le présent document se réfèrent aux centres d’usinage.
Toutefois, les essais s’appliquent en principe à la plupart des machines-outils CN.
2 Références normatives
Les documents suivants, en tout ou partie, sont référencés de manière normative dans le présent
document et sont indispensables à son application. Pour les références datées, seule l'édition citée
s'applique. Pour les références non datées, la dernière édition du document de référence s'applique (y
compris les éventuels amendements).
ISO 230-1, Code d'essai des machines-outils — Partie 1: Exactitude géométrique des machines fonctionnant
à vide ou dans des conditions quasi-statiques
ISO 230-3:2020, Code d'essai des machines-outils — Partie 3: Évaluation des effets thermiques
3 Termes et définitions
Pour les besoins du présent document, les termes et définitions suivants s'appliquent.
L’ISO et l’IEC tiennent à jour des bases de données terminologiques destinées à être utilisées en
normalisation, consultables aux adresses suivantes:
— IEC Electropedia: disponible à l’adresse https:// www .electropedia .org/
— ISO Online browsing platform: disponible à l’adresse https:// www .iso .org/ obp
1
© ISO 2022 – Tous droits réservés

---------------------- Page: 7 ----------------------
ISO 230-10:2022(F)
NOTE En mode mesurage, les machines-outils sont utilisées comme des MMT. Les définitions relatives aux
essais des performances des systèmes de palpage pour les MMT s'appliquent donc également aux machines-
outils. Tous les utilisateurs de machines-outils ne sont toutefois pas familiarisés avec l'utilisation des MMT, c'est
pourquoi le présent document donne des définitions spécifiques aux machines-outils, afin de s’assurer d’éviter
tout risque de contradiction avec les définitions relatives aux MMT.
3.1 Termes généraux
3.1.1
repère machine
RM
système de coordonnées lié aux axes, physiques ou calculés, d'une machine-outil
[SOURCE: ISO 10360-1:2000, 2.5 — modifiée, référence à «machine-outil» à la place de «repère
machine».]
3.1.2
repère pièce
RP
système de coordonnées lié à la pièce
[SOURCE: ISO 10360-1:2000, 2.4]
3.1.3
volume de mesure
espace tridimensionnel englobant l'ensemble des coordonnées linéaires accessibles au mesurage sur la
machine-outil
3.2 Termes liés au système de palpage
3.2.1
palpeur
dispositif qui détecte une surface et génère un (des) signal (signaux) pendant le palpage
Note 1 à l'article: Il existe plusieurs types de palpeurs utilisés sur les machines-outils et employant différentes
technologies pour atteindre le même but.
Note 2 à l'article: Les palpeurs peuvent être de type «à déclenchement» ou «proportionnel». Ils peuvent être
disponibles sous la forme de systèmes «à contact» ou «sans contact».
[SOURCE: ISO 10360-1:2000, 3.1 — modifiée, la Note 1 à l’article et la Note 2 à l’article ont été ajoutées.]
3.2.1.1
palpeur à contact
palpeur (3.2.1) qui nécessite un contact matériel avec une surface à mesurer (à détecter) pour
fonctionner
EXEMPLE Disjoncteur électrique, jauge de contrainte.
Note 1 à l'article: La vitesse d'avance de contact appliquée pour obtenir le contact matériel peut influencer les
performances de ces palpeurs. La vitesse d'avance de contact appropriée est spécifiée dans les instructions du
fabricant/fournisseur.
Note 2 à l'article: Pour obtenir des performances optimales, la vitesse d'avance de contact appliquée pendant le
mesurage est identique à la vitesse appliquée pendant la qualification du palpeur.
Note 3 à l'article: Les palpeurs à contact types fonctionnant dans les directions − X, + X, − Y, + Y et − Z, et dans
n'importe quelle combinaison de ces directions, sont parfois appelés palpeurs 2,5D. Ces palpeurs à contact ne
permettent pas une déviation (ou permettent une déviation très limitée) dans la direction + Z.
2
  © ISO 2022 – Tous droits réservés

---------------------- Page: 8 ----------------------
ISO 230-10:2022(F)
Note 4 à l'article: La fonctionnalité de mesurage dans la direction + Z peut être obtenue en utilisant les systèmes
de stylet équipés de stylets multiples comme illustré à la Figure 1, dans lesquels la touche de stylet 2 (se déplaçant
dans la direction + Z) sera en contact avec la surface de la pièce et incitera le palpeur à émettre le signal en
conséquence de la déviation dans la direction − Z.
3.2.1.2
palpeur sans contact
palpeur (3.2.1) qui ne nécessite pas un contact matériel avec une surface à mesurer pour fonctionner
EXEMPLE Systèmes optiques et laser, systèmes inductifs et capacitifs.
Note 1 à l'article: Dans le présent document seul les systèmes de barrière optique laser en tant que système de
palpage sans contact sont inclus.
3.2.1.3
palpeur à déclenchement
palpeur de contact à détente
palpeur (3.2.1) émettant un signal binaire au contact d'une surface à mesurer (à détecter)
3.2.1.4
principe de barrière optique laser
principe utilisant un émetteur de lumière laser et un récepteur optoélectronique pour détecter une
interruption de lumière afin d’effectuer des tâches de mesurage sans contact
3.2.2
palpage
palper
action de mesurage consistant à déterminer des valeurs (par exemple, valeurs de coordonnées, valeurs
de longueurs, valeurs fausses/vraies)
Note 1 à l'article: Le palpage associé au mesurage des outils coupants ne permettra pas nécessairement de
déterminer des valeurs de coordonnées.
Note 2 à l'article: Le palpage associé à la détection de bris d'outil permettra de déterminer un état faux/vrai.
[SOURCE: ISO 10360-1:2000, 2.7 — modifiée, la définition a été partiellement modifiée en explicitant
«valeurs», la Note 1 à l’article et la Note 2 à l’article ont été ajoutées.]
3.2.2.1
palpage 1D
mesurage permettant uniquement un mouvement de palpage parallèle à un axe d’un repère machine ou
à un axe d’un repère pièce
3.3.2.2
palpage 2D
mesurage permettant un mouvement de palpage le long d'un vecteur dans un plan
Note 1 à l'article: Une qualification indépendante pour la touche de stylet 1 et la touche de stylet 2, ainsi que des
essais supplémentaires sont spécifiés dans l'ISO 10360-5.
3
© ISO 2022 – Tous droits réservés

---------------------- Page: 9 ----------------------
ISO 230-10:2022(F)
Légende
1 touche de stylet 1 4 porte-outil
2 touche de stylet 2 5 palpeur
3 broche 6 pièce
Figure 1 — Outil de palpage équipé de deux stylets
3.2.2.3
palpage 3D
mesurage permettant un mouvement de palpage le long de tout vecteur dans l'espace
3.2.3
système de palpage
système constitué d'un palpeur (3.2.1), d’un palpeur à contact (3.2.1.1) ou d’un palpeur sans contact
(3.2.1.2) d'un système de transmission de signal (par exemple, optique, radio, filaire), d'un matériel de
traitement du signal, du matériel et du logiciel de palpage et, selon le cas, de rallonges de palpeur, d'un
système de changement de palpeur, d'un stylet et de rallonges de stylet, en cas d'utilisation conjointe
avec une machine-outil à commande numérique appropriée
Note 1 à l'article: Certains des essais spécifiés dans le présent document concernent les systèmes de palpage
constitués de palpeurs à contact équipés d'un système de stylet simple parallèle à la ligne moyenne d'axe de
broche de la machine-outil, comme illustré dans la Figure 2. Pour les applications utilisant des systèmes équipés
de stylets multiples (voir Figure 1) et pour les applications dans lesquelles le mesurage est effectué en utilisant
plusieurs orientations de la ligne moyenne d'axe de broche par rapport au RP, des essais supplémentaires sont
spécifiés dans l'ISO 10360-5.
[SOURCE: ISO 10360-1:2000, 2.6 — modifiée, la Note 1 à l’article a été ajoutée.]
3.2.4
qualification du système de palpage
établissement des paramètres d’un système de palpage (d’après les instructions du fabricant/
fournisseur) nécessaires pour les mesurages à venir
Note 1 à l'article: Le diamètre effectif de la touche de stylet (3.2.6) et la position du centre de la touche de stylet
par rapport à la ligne moyenne d'axe de la broche des paramètres types établis par la qualification du système de
palpage.
Note 2 à l'article: La documentation technique des fournisseurs utilise parfois l'expression «étalonnage du
système de palpage» pour désigner la qualification du système de palpage; cette expression n'est pas appropriée.
[SOURCE: ISO 10360-1:2000, 3.7 — modifiée, la Note 1 à l’article et la Note 2 à l’article ont été ajoutées.]
4
  © ISO 2022 – Tous droits réservés

---------------------- Page: 10 ----------------------
ISO 230-10:2022(F)
3.2.5
pré-course
distance entre le point du premier contact matériel de la touche de stylet du palpeur dont la surface est
détectée et le point d'émission du signal du palpeur
Note 1 à l'article: La pré-course est affectée par la construction du palpeur, la direction de palpage, la vitesse de
palpage, la force de déclenchement, la longueur et la conformité du système de stylet, la temporisation entre le
signal de palpage et la lecture des transducteurs de position de la machine-outil, etc.
Note 2 à l'article: Dans les conditions de palpage spécifiées, la variation de pré-course (couramment appelée
«frange») est une caractéristique très importante du système de palpage.
Note 3 à l'article: Certaines techniques de qualification du palpeur peuvent nettement réduire les effets de
variation de pré-course du système de palpage.
3.2.6
diamètre effectif de la touche de stylet
taille effective de la touche de stylet
dimension utilisée par certains logiciels de palpage pour déterminer la taille de l'élément mesuré à
partir de données de mesure
Note 1 à l'article: Le diamètre effectif (taille) de la touche de stylet est associé aux performances du système
de palpage et est déterminé par une qualification appropriée au système de palpage, plutôt qu'en mesurant
simplement la taille de la touche de stylet.
3.2.7
touche de stylet
élément physique qui établit le contact avec l'objet à mesurer
[SOURCE: ISO 10360-1:2000, 4.2 — modifiée, «pièce» remplacé par «objet à mesure».]
3.2.8
système de stylet
système composé d'un stylet et de rallonge(s) de stylet (selon le cas)
[SOURCE: ISO 10360-1:2000, 4.4 — modifiée, la Note 1 à l’article a été ajoutée.]
Note 1 à l'article: Les rallonges de stylet peuvent réduire la rigidité du syst
...

INTERNATIONAL ISO
STANDARD 230-10
Third edition
Test code for machine tools —
Part 10:
Determination of the measuring
performance of probing systems of
numerically controlled machine tools
Code d'essai des machines-outils —
Partie 10: Détermination des performances de mesure des systèmes de
palpage des machines-outils à commande numérique
PROOF/ÉPREUVE
Reference number
ISO 230-10:2021(E)
© ISO 2021

---------------------- Page: 1 ----------------------
ISO 230-10:2021(E)
COPYRIGHT PROTECTED DOCUMENT
© ISO 2021
All rights reserved. Unless otherwise specified, or required in the context of its implementation, no part of this publication may
be reproduced or utilized otherwise in any form or by any means, electronic or mechanical, including photocopying, or posting on
the internet or an intranet, without prior written permission. Permission can be requested from either ISO at the address below
or ISO’s member body in the country of the requester.
ISO copyright office
CP 401 • Ch. de Blandonnet 8
CH-1214 Vernier, Geneva
Phone: +41 22 749 01 11
Email: copyright@iso.org
Website: www.iso.org
Published in Switzerland
ii
PROOF/ÉPREUVE © ISO 2021 – All rights reserved

---------------------- Page: 2 ----------------------
ISO 230-10:2021(E)
Contents Page
Foreword .v
Introduction . vi
1 Scope . 1
2 Normative references . 1
3 Terms and definitions . 1
3.1 General terms . 2
3.2 Terms relating to the probing system . 2
3.3 Terms relating to probing performance . 7
3.4 Terms relating to scanning probes . 8
4 Symbols . 8
5 Preliminary remarks .11
5.1 Influences on the measurement performance of the probing system . 11
5.2 Measurement units .12
5.3 Reference to ISO 230-1 . 12
5.4 Recommended instrumentation and test equipment .12
5.5 Machine conditions prior to testing .12
5.6 Testing sequence .12
5.7 Tests to be performed .12
5.8 Sources of test uncertainty .13
5.9 Reporting of test results . 14
6 Thermal influences .14
6.1 General . 14
6.2 Environmental temperature variation error (ETVE) test. 14
6.3 Other thermal distortion tests . 15
7 Probing of workpiece .15
7.1 Touch trigger probes . 15
7.1.1 General .15
7.1.2 Probing repeatability . 16
7.1.3 Stylus tip offset test . 17
7.1.4 Probing-tool location repeatability test . 18
7.1.5 2D probing error test . 19
7.1.6 3D probing error test .20
7.1.7 Workpiece position and orientation tests . 22
7.1.8 Combined workpiece machining and location test .28
7.1.9 Time delay variation tests .29
7.1.10 Feature size measurement performance tests .34
7.2 Scanning probes . 36
7.2.1 General .36
7.2.2 Filtering parameters .36
7.2.3 Scanning 2D performance test .36
7.2.4 Scanning 3D performance test.38
7.3 Bore gauge . 41
7.3.1 General . 41
7.3.2 Characteristics of bore gauge systems . 41
7.3.3 Preliminary remarks .44
7.3.4 Determination of measurement repeatability of the system . 45
8 Probing of tools .45
8.1 Touch trigger probes . 45
8.1.1 General . 45
8.1.2 Tool-setting system qualification .46
8.1.3 Tool-setting repeatability .46
iii
© ISO 2021 – All rights reserved PROOF/ÉPREUVE

---------------------- Page: 3 ----------------------
ISO 230-10:2021(E)
8.2 Non-contacting laser light barrier tool measuring system .49
8.2.1 General .49
8.2.2 Typical functions of a laser light barrier system .50
8.2.3 Differences between laser light barrier systems and contacting tool
measuring systems .50
8.2.4 Laser light barrier tool measuring system .50
8.2.5 Factors influencing the uncertainty of tool dimensional measurement .53
8.2.6 Preliminary remarks .53
8.2.7 Verification of detection tasks . 53
8.2.8 Verification of measurement tasks .58
8.2.9 Reports of test results .65
Bibliography .67
iv
PROOF/ÉPREUVE © ISO 2021 – All rights reserved

---------------------- Page: 4 ----------------------
ISO 230-10:2021(E)
Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards
bodies (ISO member bodies). The work of preparing International Standards is normally carried out
through ISO technical committees. Each member body interested in a subject for which a technical
committee has been established has the right to be represented on that committee. International
organizations, governmental and non-governmental, in liaison with ISO, also take part in the work.
ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of
electrotechnical standardization.
The procedures used to develop this document and those intended for its further maintenance are
described in the ISO/IEC Directives, Part 1. In particular, the different approval criteria needed for the
different types of ISO documents should be noted. This document was drafted in accordance with the
editorial rules of the ISO/IEC Directives, Part 2 (see www.iso.org/directives).
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. ISO shall not be held responsible for identifying any or all such patent rights. Details of
any patent rights identified during the development of the document will be in the Introduction and/or
on the ISO list of patent declarations received (see www.iso.org/patents).
Any trade name used in this document is information given for the convenience of users and does not
constitute an endorsement.
For an explanation of the voluntary nature of standards, the meaning of ISO specific terms and
expressions related to conformity assessment, as well as information about ISO's adherence to
the World Trade Organization (WTO) principles in the Technical Barriers to Trade (TBT) see
www.iso.org/iso/foreword.html.
This document was prepared by Technical Committee ISO/TC 39, Machine tools, Subcommittee SC 2,
Test conditions for metal cutting machine tools.
This third edition cancels and replaces the second edition (ISO 230-10:2016), which has been technically
revised.
The main changes compared to the previous edition are as follows:
— The document scope has been revised to include specification in 7.2, 7.3 and 8.2;
— a definition for laser light barrier principle is added in 3.2.12;
— Figures 1, 4, 6 and 7 have been revised;
— Symbols of variables in Formulae (3) and (4) have been changed to be consistent with symbols in
8.2.8.4.1;
— a new subclause 7.3 on "Determination of the performance of bore gauge systems" has been added.
— a new subclause 8.2 on "Non-contacting laser light barrier tool measuring systems" has been added.
A list of all parts in the ISO 230 series can be found on the ISO website.
Any feedback or questions on this document should be directed to the user’s national standards body. A
complete listing of these bodies can be found at www.iso.org/members.html.
v
© ISO 2021 – All rights reserved PROOF/ÉPREUVE

---------------------- Page: 5 ----------------------
ISO 230-10:2021(E)
Introduction
The purpose of ISO 230 (all parts) is to standardize methods of testing the accuracy of machine tools,
excluding portable power tools.
This document specifies test procedures to evaluate the measuring performance of contacting and non-
contacting probing systems integrated with CNC machine tools. The test procedures are not intended to
distinguish between the various causes of errors. They intend to demonstrate the combined influence
of the environment, machine tool, probing system and probing software on the measuring performance.
The results of these tests do not reflect on the performance of the machine tool in a metal cutting mode.
When the tests are required for acceptance purposes, it is up to the user to choose the tests that are of
interest, in agreement with the manufacturer/supplier.
The results of these tests do not reflect on the performance of the machine tool used as a coordinate
measuring machine (CMM). Such performance involves traceability issues and it is intended that they
be evaluated based on methods of ISO 10360-2 and ISO 10360-5.
Test procedures to measure performance with touch trigger probes are given in 7.1 and 8.1, scanning
probes in 7.2, bore gauge systems in 7.3. and with non-contacting tool measuring systems applying
laser light barrier principle in 8.2.
Numerically controlled machine tools can apply probing systems in machining process applications,
such as
— identification that the correct workpiece has been loaded before machining,
— location and/or alignment of the workpiece,
— dimensional measurement of the workpiece after machining, but while still on the machine tool,
— measurement of the position and orientation of the machine tool rotary axes,
— measurement and setting of the cutting tool (radius, length and offset of the tool), and
— detection of tool breakage.
vi
PROOF/ÉPREUVE © ISO 2021 – All rights reserved

---------------------- Page: 6 ----------------------
INTERNATIONAL STANDARD ISO 230-10:2021(E)
Test code for machine tools —
Part 10:
Determination of the measuring performance of probing
systems of numerically controlled machine tools
1 Scope
This document specifies test procedures to evaluate the measuring performance of probing systems
integrated with a numerically controlled machine tool. Test procedures for touch trigger probing
systems and scanning probing systems operating in discrete-point measurement mode are specified
in 7.1. Test procedures are specified for scanning probing systems in 7.2, for bore gauge systems in 7.3,
for contacting tool measuring systems in 8.1, and for non-contacting tool measuring systems using the
laser light barrier principle in 8.2.
The evaluation of the performance of the machine tool, used as a coordinate measuring machine (CMM),
is outside the scope of this document. Such performance evaluation involves traceability issues, is
strongly influenced by machine tool geometric accuracy and can, in addition to the machine tool probing
system tests specified in this document, be evaluated according to ISO 10360-2 and ISO 10360-5.
Descriptions of test procedures in this document are referred to machining centres. However, tests
apply in principle to most NC machine tools.
2 Normative references
The following documents are referred to in the text in such a way that some or all of their content
constitutes requirements of this document. For dated references, only the edition cited applies. For
undated references, the latest edition of the referenced document (including any amendments) applies.
ISO 230-1:2012, Test code for machine tools — Part 1: Geometric accuracy of machines operating under
no-load or quasi-static conditions
ISO 230-3:2020, Test code for machine tools — Part 3: Determination of thermal effects
3 Terms and definitions
For the purposes of this document, the following terms and definitions apply.
ISO and IEC maintain terminological databases for use in standardization at the following addresses:
— IEC Electropedia: available at https:// www .electropedia .org/
— ISO Online browsing platform: available at https:// www .iso .org/ obp
NOTE In measuring mode, machine tools are used like CMMs. Therefore, definitions for probing systems
performance tests for CMMs apply also to machine tools. However, since not all machine tool users are familiar
with the use of CMMs, this document provides definitions specifically with machine tools in mind, making sure
that they do not create any conflicts with CMM definitions.
1
© ISO 2021 – All rights reserved PROOF/ÉPREUVE

---------------------- Page: 7 ----------------------
ISO 230-10:2021(E)
3.1 General terms
3.1.1
machine coordinate system
MCS
coordinate system fixed with respect to physical or calculated axes of a machine tool
[SOURCE: ISO 10360-1:2000, 2.5 — modified, reference to "machine tool" instead of "machine coordinate
system".]
3.1.2
workpiece coordinate system
WCS
coordinate system fixed with respect to a workpiece
[SOURCE: ISO 10360-1:2000, 2.4]
3.1.3
measuring volume
three-dimensional space encompassing all linear coordinates that are accessible for measurement on
the machine tool
3.2 Terms relating to the probing system
3.2.1
probe
device that senses a surface and generates the signal(s) during probing
Note 1 to entry: There are several types of probes used on machine tools and they use different technologies to
achieve the same aim.
Note 2 to entry: Probes can either be “switching” types or “proportional” types. These can be available as either
“contacting” or “non-contacting” systems.
[SOURCE: ISO 10360-1:2000, 3.1 — modified, Note 1 to entry and Note 2 to entry have been added.]
3.2.1.1
contacting probe
probe (3.2.1) that needs material contact with a surface being measured (detected) in order to function
EXAMPLE Electrical circuit breakage, strain gauge.
Note 1 to entry: The contacting feed speed applied to obtain the material contact can influence the performance
of such probes. Proper contacting feed speed is specified in the manufacturer/supplier instructions.
Note 2 to entry: For best performance, the contacting feed speed applied during measurement is the same as the
feed speed applied during probe qualification.
Note 3 to entry: Typical contacting probes that operate in the − X, + X, − Y, + Y and − Z directions, and in any
combination of such directions, are sometimes referred to as 2,5D probes. These contacting probes do not allow
for (or allow for very limited) operation in the + Z direction.
Note 4 to entry: Measurement in the + Z direction capability can be obtained by the use of stylus systems
equipped with multiple styli, as depicted in Figure 1, where stylus tip 2 (moving in the + Z direction) contacts
the workpiece surface and causes the probe to generate the signal as a consequence of the deflection in the − Z
direction.
3.2.1.2
non-contacting probe
probe (3.2.1) that needs no material contact with a surface being measured in order to function
EXAMPLE Optical and laser systems, inductive and capacitive systems.
2
PROOF/ÉPREUVE © ISO 2021 – All rights reserved

---------------------- Page: 8 ----------------------
ISO 230-10:2021(E)
Note 1 to entry: In this document, only laser light barrier systems as a non-contacting probing system is included.
3.2.1.3
switching probe
touch trigger probe
probe (3.2.1) that gives a binary signal as a result of detection of a surface
3.2.1.4
laser light barrier principle
principle utilising a laser light transmitter and an opto-electronic receiver to detect light interruption
for performing non-contacting measurement tasks
3.2.2
probing
to probe
measurement action that results in the determination of values (e.g., coordinate values, length values,
false/true values)
Note 1 to entry: Probing associated with the measurement of cutting tools does not necessarily result in the
determination of coordinate values.
Note 2 to entry: Probing associated with tool breakage detection results in the determination of a false/true
state.
[SOURCE: ISO 10360-1:2000, 2.7 — modified, definition has been partly modified by explaining “values”,
Note 1 to entry and Note 2 to entry have been added.]
3.2.2.1
1D probing
measurement allowing only for probing motion parallel to one machine coordinate system axis or to
one workpiece coordinate system axis
3.2.2.2
2D probing
measurement allowing for probing motion along a vector in a plane
Note 1 to entry: Independent qualification for stylus tip 1 and for stylus tip 2, and additional tests, are specified
in ISO 10360-5.
3
© ISO 2021 – All rights reserved PROOF/ÉPREUVE

---------------------- Page: 9 ----------------------
ISO 230-10:2021(E)
Key
1 stylus tip 1 4 tool holder
2 stylus tip 2 5 probe
3 spindle 6 workpiece
Figure 1 — Probing-tool equipped with 2 styli
3.2.2.3
3D probing
measurement allowing for probing motion along any vector in space
3.2.3
probing system
system consisting of a probe (3.2.1), contacting probe (3.2.1.1) or non-contacting probe (3.2.1.2), signal
transmission system (e.g. optical, radio, wire), signal conditioning hardware, the probing hardware and
software and, where present, probe extensions, probe changing system, stylus and stylus extensions,
when used in conjunction with a suitable numerically controlled machine tool
Note 1 to entry: Some of the tests specified in this document are referred to probing systems consisting of
contacting probes equipped with a single stylus system that is parallel to the machine tool spindle axis average
line, as depicted in Figure 2. For applications using stylus systems equipped with multiple styli (see Figure 1),
and for application where measurement is performed by using multiple orientations of the spindle axis average
line with respect to the WCS, additional tests are specified in ISO 10360-5.
[SOURCE: ISO 10360-1:2000, 2.6 — modified, Note 1 to entry has been added.]
3.2.4
probing system qualification
establishment of the parameters of a probing system (based on manufacturer/supplier instructions)
necessary for subsequent measurements
Note 1 to entry: Effective stylus tip diameter (3.2.6) and location of the stylus tip centre with respect to spindle
axis average line are typical parameters established by probing system qualification.
Note 2 to entry: Suppliers’ technical literature sometimes refers to probing system qualification with the
expression “probing system calibration”; this expression is not appropriate.
[SOURCE: ISO 10360-1:2000, 3.7 — modified, Note 1 to entry and Note 2 to entry have been added.]
4
PROOF/ÉPREUVE © ISO 2021 – All rights reserved

---------------------- Page: 10 ----------------------
ISO 230-10:2021(E)
3.2.5
pre-travel
distance between the point of first material contact of the probe stylus tip with the surface being
detected and the point where the probe signal is generated
Note 1 to entry: Pre-travel is affected by probe construction, probing direction, probing speed, switching force,
stylus system length and compliance, time delay between probing signal and machine tool position transducer
read-out, etc.
Note 2 to entry: Pre-travel variation (commonly referred to as “lobing”), under specified probing conditions, is a
very important probing system characteristic.
Note 3 to entry: Some probe qualification techniques can significantly reduce the effects of probing system pre-
travel variation.
3.2.6
effective stylus tip diameter
effective stylus tip size
stylus tip dimension used by some probing software to determine feature size from the measurement
data
Note 1 to entry: The effective stylus tip diameter (size) is associated with probing system performance and is
determined by appropriate probing system qualification, rather than by simply measuring the stylus tip size.
3.2.7
stylus tip
physical element that establishes the contact with the object to measure
[SOURCE: ISO 10360-1:2000, 4.2 — modified, "workpiece" replaced with "object to measure".]
3.2.8
stylus system
system composed of a stylus and stylus extension(s) (if any)
[SOURCE: ISO 10360-1:2000, 4.4 — modified, Note 1 to entry has been added.]
Note 1 to entry: Stylus extensions can reduce stylus system stiffness and can adversely influence probing system
performance. Therefore, performance tests are carried out using the particular stylus extension(s) of interest.
3.2.9
stylus system length
distance from the centre of the stylus tip to the feature interfacing with the probe
of the stylus system (3.2.8)
Note 1 to entry: See Figure 2.
Note 2 to entry: Some probing systems (3.2.3) establish the stylus system length as the distance from the centre
of the stylus tip and others from the most protruding point of the stylus tip.
5
© ISO 2021 – All rights reserved PROOF/ÉPREUVE

---------------------- Page: 11 ----------------------
ISO 230-10:2021(E)
Key
1 stylus tip (3.2.7)
2 stylus
3 stylus extension (3.2.9)
a stylus system length
Figure 2 — Stylus system length
3.2.10
probing-tool
device consisting of a probe and its stylus system (3.2.8), attached to a tool holder
Note 1 to entry: See Figure 2.
3.2.11
probing-tool length
distance from the most protruding point of the stylus tip to the machine tool spindle reference surface
or gauge line that connects to the probing-tool (3.2.10)
Note 1 to entry: See Figure 3.
Note 2 to entry: Some probing systems establish the probing-tool length as the distance from the centre of the
stylus tip to the machine tool spindle reference surface that connects to the probing-tool and others from the
most protruding point of the stylus tip to the machine tool spindle reference surface that connects to the probing-
tool.
Note 3 to entry: For solid-shank-type tool holders, the spindle reference surface is at the spindle cone gauge line.
For other tool holders (hollow shank), the spindle reference surface is the spindle face.
Note 4 to entry: Typically, the probing system is handled by the machine controller as a tool, therefore, the overall
length is considered.
Note 5 to entry: The procedure for establishing the length of the probing-tool is specif
...

Questions, Comments and Discussion

Ask us and Technical Secretary will try to provide an answer. You can facilitate discussion about the standard in here.

This May Also Interest You

ISO
ISO 230-12:2022(Main)
Test code for machine tools — Part 12: Accuracy of finished test pieces

This document specifies methods for defining machining tests for manufacturing accurate test pieces, and for evaluating the influence of quasi-static geometric errors of linear axes and rotary axes, and the influence of the synchronization error of simultaneously controlled multiple axes. Although quasi-static geometric errors are often major contributors for geometric errors of finished test pieces, other factors, e.g. the dynamic contouring error, can also have significant influence. This document describes examples of test piece geometry applicable to individual machine tools, possible contributors to machining error, deviations to be measured and measuring instruments. By clarifying possible contributors to machining error in each machining test, this document gives a guidance to machine tool manufacturers or users such that proper machining tests can be chosen to evaluate a machine tool’s machining performance in specified machining applications. Machining tests to evaluate the geometric accuracy of a single surface are described in Clause 5, and those to evaluate geometric relationship of multiple machining features are described in Clause 6. Clause 7 presents machining tests for other objectives: machining tests for evaluation of short-term capability (7.2), and machining tests for evaluation of thermal influence (7.3).

  • Standard
    46 pages
    English language
    sale 15% off
  • Standard
    50 pages
    French language
    sale 15% off
ISO
ISO 26303:2022(Main)
Machine tools — Short-term capability evaluation of machining processes on metal-cutting machine tools

This document specifies procedures for acceptance of metal-cutting machine tools based on the tests of their capability in machining a specified workpiece (i.e. indirect testing). It gives recommendations for test conditions, applicable measurement systems and the requirements for machine tools. This document is consistent with ISO 22514 (all parts) describing statistical methods for process management and deals with the specific application of those methods to machine tools and machining of a sample batch of test pieces. This document covers neither functional tests, which are generally carried out before testing the accuracy performance, nor the testing of the safety conditions of the machine tool. Annex A gives additional information related to statistical evaluation, Annexes B and C provide agreement and evaluations forms for short-term capability tests, while Annex D gives an example. NOTE 1 Direct testing aims to investigate individual machine tool properties, such as geometric or positioning accuracy. Short-term capability evaluation is meant to prove that a machine tool has the capability to fulfil a specific process task. It is, therefore, important to recognize that the short-term capability test is focused only on the manufactured product. This means that direct testing methods are more suited for the determination of error sources on the machine tool and for deriving constructive improvements of a machine tool that is used in a wide production spectrum; a short-term capability test is less suited for detection of error sources of the machine tool. Therefore, it is expected that short-term capability evaluation for the acceptance of metal-cutting machine tools in machining processes be primarily carried out on workpiece-dependent special-purpose machines, e.g. working stations of transfer lines, with a process-determined cycle time of less than 10 min, so that at least 50 workpieces are manufactured in one shift as the statistical uncertainty increases strongly for a smaller number. In principle, short-term capability evaluation can also be performed on universal machine tools, such as machining centres used for large batch production if they meet the above-mentioned statistical requirements. NOTE 2 The term “short-term capability”, which is a widely used term in machine tool industry, corresponds to the term “process performance index” specified in ISO 3534-2:2006 for normal distribution.

  • Standard
    45 pages
    English language
    sale 15% off
  • Standard
    48 pages
    French language
    sale 15% off
  • Standard
    48 pages
    French language
    sale 15% off
ISO
ISO 230-3:2020(Main)
Test code for machine tools — Part 3: Determination of thermal effects

This document defines four tests: — an environmental temperature variation error (ETVE) test; — a test for thermal distortion caused by rotating spindles; — a test for thermal distortion caused by moving linear axes; — a test for thermal distortion caused by rotary motion of components. The tests for thermal distortion caused by moving linear axes (see Clause 7) are applicable to numerically controlled (NC) machines only and are designed to quantify the effects of thermal expansion and contraction as well as the angular deformation of structures. For practical reasons, the test methods described in Clause 7 apply to machines with linear axes up to 2 000 mm in length. If they are used for machines with axes longer than 2 000 mm, a representative length of 2 000 mm in the normal range of each axis is chosen for the tests. The tests correspond to the drift test procedure as described in ISO/TR 16015:2003, A.4.2, applied for machine tools with special consideration of thermal distortion of moving linear components and thermal distortion of moving rotary components. On machine tools equipped with compensation for thermal effects these tests demonstrate any uncertainty in nominal thermal expansion due to uncertainty of coefficient of thermal expansion and any uncertainty of length due to temperature measurement.

  • Standard
    50 pages
    English language
    sale 15% off
  • Standard
    55 pages
    French language
    sale 15% off
  • Draft
    49 pages
    English language
    sale 15% off
  • Draft
    50 pages
    English language
    sale 15% off
  • Draft
    56 pages
    French language
    sale 15% off
  • Draft
    56 pages
    French language
    sale 15% off
ISO
ISO/TR 17243-3:2020(Main)
Machine tool spindles — Evaluation of machine tool spindle vibrations by measurements on spindle housing — Part 3: Gear-driven spindles with rolling bearings operating at speeds between 600 r/min and 12 000 r/min

This document provides information on how to assess the severity of machine tool spindle vibrations measured on the spindle housing. It gives specific guidance for assessing the severity of vibration measured on the spindle housing at customer sites or at the machine tool manufacturer's test facilities. Its vibration criteria apply to gear-driven spindles intended for stationary machine tools with nominal operating speeds between 600 r/min and 12 000 r/min. It is applicable to those spindles of the rolling bearing types only, to spindles assembled on metal cutting machine tools, and for testing, periodic verification, and continuous monitoring. It does not address: — geometrical accuracy of axes of rotation (see ISO 230‑7); — unacceptable cutting performance with regards to surface finish and accuracy; — vibration severity issues of machine tool spindles operating at speeds below 600 r/min or exceeding 12 000 r/min (due to lack of supporting vibration data); or — frequency domain analyses such as fast Fourier transform (FFT) analyses, envelope analyses or other similar techniques. Annex A presents an introduction to alternative bearing condition assessment techniques.

  • Technical report
    17 pages
    English language
    sale 15% off
  • Technical report
    20 pages
    French language
    sale 15% off
ISO
ISO/TR 230-11:2018(Main)
Test code for machine tools — Part 11: Measuring instruments suitable for machine tool geometry tests

The aim of this document is to document the characteristics of precision measuring instruments for testing the geometric accuracy of machine tools, operating either under no-load or under quasi-static conditions. Where necessary, reference is made to the appropriate International Standards. The measuring instruments for operational testing of machine tools [vibrations (ISO/TR 230‑8), noise (ISO 230‑5), stick-slip motion of components, etc.] as well as instruments for checking of other characteristics of machine tools (speeds, feeds, temperature) are not covered in this document. The measuring instruments for checking of workpiece geometry (size, form, etc.) are not covered by this document either. This document has list style construction for ease of search and identification of each instrument's characteristics. Sources of uncertainty of instruments and measurements are described in this document for more accurate measurement procedures.

  • Technical report
    127 pages
    English language
    sale 15% off
  • Technical report
    131 pages
    French language
    sale 15% off
ISO
ISO/TR 17243-2:2017(Main)
Machine tool spindles — Evaluation of spindle vibrations by measurements on non-rotating parts — Part 2: Direct-driven spindles and belt-driven spindles with rolling element bearings operating at speeds between 600 r/min and 30 000 r/min

ISO/TR 17243-2:2017 information on how to assess the severity of machine tool spindle vibrations measured on the spindle housing. It gives specific guidance for assessing the severity of vibration measured on the spindle housing at customer sites or at the machine tool manufacturer's test facilities. Its vibration criteria apply to direct-driven spindles and belt-driven spindles intended for stationary machine tools with nominal operating speeds between 600 r/min and 30 000 r/min. It is applicable to those spindles of the rolling element bearing types only, to spindles assembled on metal cutting machine tools, and for testing, periodic verification, and continuous monitoring. It does not address - geometrical accuracy of axes of rotation (see ISO 230‑7), - unacceptable cutting performance with regards to surface finish and accuracy, - vibration severity issues of machine tool spindles operating at speeds below 600 r/min or exceeding 30 000 r/min (due to lack of supporting vibration data and limitations in many vibration measurement instruments), or - frequency domain analyses such as fast Fourier transform (FFT) analyses, envelope analyses or other similar techniques. Annex A presents an introduction to alternative bearing condition assessment techniques.

  • Technical report
    18 pages
    English language
    sale 15% off
  • Technical report
    20 pages
    French language
    sale 15% off
ISO
ISO 230-2:2014/Amd 1:2016(Amendment)
Test code for machine tools — Part 2: Determination of accuracy and repeatability of positioning of numerically controlled axes — Amendment 1
  • Standard
    3 pages
    English language
    sale 15% off
  • Standard
    3 pages
    English language
    sale 15% off
  • Standard
    3 pages
    French language
    sale 15% off
ISO
ISO 230-7:2015(Main)
Test code for machine tools — Part 7: Geometric accuracy of axes of rotation

ISO 230-7:2015 is aimed at standardizing methods of specification and test of the geometric accuracy of axes of rotation used in machine tools. Spindle units, rotary heads, and rotary and swivelling tables of machine tools constitute axes of rotation, all having unintended motions in space as a result of multiple sources of errors. ISO 230-7:2015 covers the following properties of rotary axes: - axis of rotation error motion; - speed-induced axis shifts. The other important properties of rotary axes, such as thermally induced axis shifts and environmental temperature variation-induced axis shifts, are dealt with in ISO 230‑3. ISO 230-7:2015 does not cover the following properties of spindles: - angular positioning accuracy (see ISO 230‑1 and ISO 230‑2); - run-out of surfaces and components (see ISO 230‑1); - tool holder interface specifications; - inertial vibration measurements (see ISO/TR 230‑8); - noise measurements (see ISO 230‑5); - rotational speed range and accuracy (see ISO 10791‑6 and ISO 13041‑6); - balancing measurements or methods (see ISO 1940‑1 and ISO 6103); - idle run loss (power loss); - thermal effects (see ISO 230‑3).

  • Standard
    72 pages
    English language
    sale 15% off
  • Standard
    79 pages
    French language
    sale 15% off
ISO
ISO/TR 16907:2015(Main)
Machine tools — Numerical compensation of geometric errors

ISO/TR 16907:2015 provides information for the understanding and the application of numerical compensation of geometric errors for numerically controlled machine tools including: - terminology associated with numerical compensation; - representation of error functions output from different measuring methods; - identification and classification of compensation methods as currently applied by different CNCs; - information for the understanding and application of different numerical compensations. ISO/TR 16907:2015 does not provide a detailed description of geometric errors measurement techniques that are specified in ISO 230 (all parts) and in machine tool specific performance evaluation standards and it is not meant to provide comprehensive theoretical and practical background on the existing technologies. ISO/TR 16907:2015 focuses on geometric errors of machine tools operating under no-load or quasi-static conditions. Errors resulting from the application of dynamic forces as well as other errors that might affect the finished part quality (e.g. tool wear) are not considered in this Technical Report. Deformations due to changing static load by moving axes are considered in 7.4.2.

  • Technical report
    35 pages
    English language
    sale 15% off
  • Technical report
    30 pages
    English language
    sale 15% off
ISO
ISO/TR 17243-1:2014(Main)
Machine tool spindles — Evaluation of machine tool spindle vibrations by measurements on spindle housing — Part 1: Spindles with rolling element bearings and integral drives operating at speeds between 600 min-1 and 30 000 min-1

ISO/TR 17243-1: 2014 provides information on how to assess the severity of machine tool spindle vibrations measured on the spindle housing. The vibration criteria provided in this part of ISO/TR 17243 apply to spindles with integral drive intended for stationary machine tools with nominal operating speeds between 600 min−1 and 30 000 min−1. This part of ISO/TR 17243 only applies to spindles with rolling element bearing types. ISO/TR 17243-1: 2014 applies to spindles assembled on metal cutting machine tools. ISO/TR 17243-1: 2014 is applicable for testing, periodic verification, and continuous monitoring. Spindles with bearing types other than rolling element bearings are excluded from this part of ISO/TR 17243. ISO/TR 17243-1: 2014 does not address geometrical accuracy of axes of rotation (see ISO 230‑7). ISO/TR 17243-1: 2014 does not address unacceptable cutting performance with regards to surface finish and accuracy. ISO/TR 17243-1: 2014 does not address vibration severity issues of machine tool spindles operating at speeds below 600 min−1 or exceeding 30 000 min−1 due to lack of supporting vibration data and limitations in many vibration measurement instruments. Also, due to lack of data, machine tool spindles with bearing types other than rolling element bearings are excluded from this part of ISO/TR 17243. ISO/TR 17243-1: 2014 does not address frequency domain analyses such as fast fourier transform (FFT) analyses, envelope analyses, or other similar techniques.

  • Technical report
    18 pages
    English language
    sale 15% off
  • Technical report
    20 pages
    French language
    sale 15% off