ISO/TS 13399-50:2013

TECHNICAL ISO/TS
SPECIFICATION 13399-50
Second edition
2013-12-01
Cutting tool data representation and
exchange —
Part 50:
Reference dictionary for reference
systems and common concepts
Représentation et échange des données relatives aux outils coupants —
Partie 50: Dictionnaire de référence pour les systèmes de coordonnées
et les concepts communs
Reference number
©
ISO 2013
© ISO 2013
All rights reserved. Unless otherwise specified, 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
Case postale 56 • CH-1211 Geneva 20
Tel. + 41 22 749 01 11
Fax + 41 22 749 09 47
E-mail copyright@iso.org
Web www.iso.org
Published in Switzerland
ii © ISO 2013 – All rights reserved

Contents Page
Foreword .iv
Introduction .vi
1 Scope . 1
2 Normative references . 2
3 Terms and definitions . 2
4 Abbreviated terms . 5
5 Representation of the ontology concepts as dictionary entries . 5
5.1 General . 5
5.2 Common concepts . 5
5.3 reference system .10
6 Properties for connection systems, reference systems and common features .15
Annex A (normative) Information Object Registration .19
Annex B (informative) Classification table.20
Annex C (informative) Class definitions .23
Annex D (informative) Property definitions for reference systems and common concepts .46
Annex E (informative) Illustrations of properties .118
Annex F (informative) Illustrations of reference systems
.......................................................................................................121
Bibliography .126
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. 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. 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 on the meaning of ISO specific terms and expressions related to conformity
assessment, as well as information about ISO’s adherence to the WTO principles in the Technical Barriers
to Trade (TBT) see the following URL: Foreword - Supplementary information
The committee responsible for this document is ISO/TC 29, Small Tools.
This second edition cancels and replaces the first edition (ISO/TS 13399-50:2007), which has been
technically revised.
ISO 13399 consists of the following parts, under the general title Cutting tool data representation and exchange:
— Part 1: Overview, fundamental principles and general information model
— Part 2: Reference dictionary for the cutting items [Technical Specification]
— Part 3: Reference dictionary for tool items [Technical Specification]
— Part 4: Reference dictionary for adaptive items [Technical Specification]
— Part 5: Reference dictionary for assembly items [Technical Specification]
— Part 50: Reference dictionary for reference systems and common concepts [Technical Specification]
— Part 60: Reference dictionary for connection systems [Technical Specification]
— Part 100: Definitions, principles and methods for reference dictionaries [Technical Specification]
— Part 150: Usage guidelines [Technical Specification]
— Part 301: Concept for the design of 3D models based on properties according to ISO/TS 13399‑3:Modelling
of thread‑cutting taps, thread‑forming taps and thread‑cutting dies [Technical Specification]
— Part 302: Concept for the design of 3D models based on properties according to ISO/TS 13399‑3:
Modelling of solid drills and countersinking tools [Technical Specification]
The following parts are under preparation:
— Part 51: Designation system for customer solution cutting tools
iv © ISO 2013 – All rights reserved

— Part 80: Concept for the design of 3D models based on properties according to ISO/TS 13399: Overview
and principles [Technical Specification]
— Part 201: Concept for the design of 3D models based on properties according to ISO/TS 13399‑2:
Modelling of regular inserts [Technical Specification]
— Part 202: Concept for the design of 3D models based on properties according to ISO/TS 13399‑2:
Modelling of irregular inserts [Technical Specification]
— Part 203: Concept for the design of 3D models based on properties according to ISO/TS 13399‑2:
Modelling of exchangeable inserts for drilling [Technical Specification]
— Part 204: Concept for the design of 3D models based on properties according to ISO/TS 13399‑2:
Modelling of inserts for reaming [Technical Specification]
— Part 303: Concept for the design of 3D models based on properties according to ISO/TS 13399‑3:
Modelling of end mills with non‑indexable cutting edges [Technical Specification]
— Part 304: Concept for the design of 3D models based on properties according to ISO/TS 13399‑3:
Modelling of milling cutters with arbor hole and non‑indexable cutting edges [Technical Specification]
— Part 307: Concept for the design of 3D models based on properties according to ISO/TS 13399‑3:
Modelling of end mills for indexable inserts [Technical Specification]
— Part 308: Concept for the design of 3D models based on properties according to ISO/TS 13399‑3:
Modelling of milling cutter with arbor hole for indexable inserts [Technical Specification]
— Part 309: Concept for the design of 3D models based on properties according to ISO/TS 13399‑3: Tool
holders for indexable inserts [Technical Specification]
— Part 311: Concept for the design of 3D models based on properties according to ISO/TS 13399‑3:
Modelling of solid reamers [Technical Specification]
— Part 312: Concept for the design of 3D models based on properties according to ISO/TS 13399‑3:
Modelling of reamers for indexable inserts [Technical Specification]
— Part 401: Concept for the design of 3D models based on properties according to ISO/TS 13399‑4:
Modelling of converting, extending and reducing adaptive items [Technical Specification]
— Part 405: Concept for the design of 3D models based on properties according to ISO/TS 13399‑4:
Modelling of collets [Technical Specification]
Introduction
This part of ISO 13399 defines the terms, properties and definitions for connection systems, coordinate
reference systems and other features and characteristics that are shared with several components of a
cutting tool with defined cutting edges. The purpose of this part of ISO 13399 is to provide a reference
dictionary to support the use of the general information model defined in ISO 13399-1.
A cutting tool with defined cutting edges is used on a machine to remove material from a workpiece by
a shearing action at the cutting edges of the tool. Cutting tool data that can be described by ISO 13399
(all parts) include, but are not limited to, everything between the workpiece and the machine tool.
1) 2) 3) 4) 5)
Information about inserts, solid tools, assembled tools, adaptors, components and their
relationships can be represented by this part of ISO 13399. Possible assemblies of the components of a
cutting tool are illustrated in Figure 1.
The objective of ISO 13399 (all parts) is to provide the means to represent the information that describes
cutting tools in a computer-sensible form that is independent from any particular computer system. This
representation will facilitate the processing and exchange of cutting tool data within and among different
software systems and computer platforms and support the application of these data in manufacturing
planning, cutting operations and the supply of tools. The nature of this description makes it suitable
not only for neutral file exchange, but also as a basis for implementing and sharing product databases
and for archiving. The methods used for these representations are those developed by ISO/TC 184,
Automation systems and integration, SC 4, Industrial data, for the representation of product data by using
standardized information models and reference dictionaries.
An information model is a formal specification of types of ideas, facts and processes, which together
describe a portion of interests of the real world and which provides an explicit set of interpretation
rules. Information is knowledge of ideas, facts and/or processes. Data are symbols or functions that
represent information for processing purposes. Data are interpreted to extract information by using
rules for how that should be done and a dictionary to define the terms that identify the data. Everyone
in a communication process is expected to use the same information model, the same set of explicit
rules and the same dictionary in order to avoid misunderstanding. If an information model and its
dictionary are written in a computer-sensible language, then there is the additional benefit that they
can be computer processable.
An engineering information model is therefore a specification for data that establishes the meaning of
that data in a particular engineering context. A model has to be developed by formal methods to ensure
that it meets the needs of the situation that it represents. An engineering information model defines:
the information objects that represent the concepts in an engineering application, the attributes of
the objects, their relationships and the constraints that add further meaning. An information model
is an abstract concept that can be used repeatedly for any example of the real-world situation that it
represents. An instance of the model is produced when it is populated with the data items and their
values that are applicable to a particular example of that situation.
This part of ISO 13399 uses the following International Standards developed by ISO/TC 184/SC 4:
a) the EXPRESS language defined in ISO 10303-11 for defining the information model;
b) the file format for data exchange derived from the model and defined in ISO 10303-21;
c) the data dictionary defined in the ISO 13584 series.
1) For example regular and irregular shaped replaceable cutting items.
2) For example solid drill and endmill.
3) For example boring bars, indexable drills and indexable milling cutters.
4) For example milling arbor and drilling chuck.
5) For example shims, screws and clamps.
vi © ISO 2013 – All rights reserved

The ISO 13399 series is intended for use by tool producers and vendors, manufacturers, and developers
of manufacturing software, among others. ISO 13399 provides a common structure for exchanging
data about cutting tools with defined cutting edges. The ISO 13399 series is intended to provide for, or
improve, several manufacturing activities, including
— the integration and sharing of data for cutting tools and assemblies between different stages for the
manufacturing cycle and between different software applications,
— the direct import of data from cutting tool suppliers into a customer’s database, and
— the management of cutting tool information from multiple sources and for multiple applications.
Different companies use different business models to determine their need for the communication of
information about their products. For example, one cutting tool manufacturer could regrind its customers’
tools while another could allow its customers to do the regrinding and provide the information to enable
them to do so. Therefore, the two cutting tool manufacturers could have a different set of cutting tool
properties to communicate using the information model and dictionaries provided in ISO 13399.
ISO 13399 defines only that information which could be communicated; it does not specify what
information shall be communicated.
Figure 1 — Possible assemblies of components of a cutting tool
Since the content of those dictionaries evolves according to industrial innovations and constant improvement
of technology in cutting tools, a Maintenance Agency has been established for the purposes of:
— correcting errors in the entries of existing classes and properties;
— adding new properties to existing classes;
— adding new classes and their properties;
— managing the status of those properties and classes;
— migrating the dictionary to subsequent editions of ISO 13399 (all parts).
The secretariat of this Maintenance Agency has been assigned to
Union de Normalisation de la Mécanique
F-92038 Paris La Défense CEDEX
France
by the ISO Technical Management Board.
The website of the Maintenance Agency is available at: http://www.unm.fr/main/core.php?pag_id=135
The reference dictionaries are available in the form of EXPRESS files on the website of the Maintenance
Agency. These files are considered complementary to this part of ISO 13399; they can be freely
downloaded and used for cutting tool data representation and exchange.
The following permission notice and disclaimer shall be included in all copies of this EXPRESS schema
(“the Schema”), and derivations of the Schema:
Permission is hereby granted, free of charge in perpetuity, to any person obtaining a copy of the Schema,
to use, copy, modify, merge and distribute free of charge, copies of the Schema for the purposes of
developing, implementing, installing and using software based on the Schema, and to permit persons to
whom the Schema is furnished to do so, subject to the following conditions:
THE SCHEMA IS PROVIDED “AS IS”, WITHOUT WARRANTY OF ANY KIND, EXPRESSED OR IMPLIED,
INCLUDING, BUT NOT LIMITED TO, THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A
PARTICULAR PURPOSE AND NON-INFRINGEMENT. IN NO EVENT SHALL ISO, OR ANY OTHER LICENSOR
THAT GRANTS THE RIGHT UNDER THE ABOVE PERMISSION TO USE THE SCHEMA, BE LIABLE FOR
ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR
OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SCHEMA OR THE USE OR OTHER
DEALINGS IN THE SCHEMA.
In addition, any modified copy of the Schema shall include the following notice:
THIS SCHEMA HAS BEEN MODIFIED FROM THE SCHEMA DEFINED IN ISO 13399, AND SHOULD NOT BE
INTERPRETED AS COMPLYING WITH THAT INTERNATIONAL STANDARD.
viii © ISO 2013 – All rights reserved

TECHNICAL SPECIFICATION ISO/TS 13399-50:2013(E)
Cutting tool data representation and exchange —
Part 50:
Reference dictionary for reference systems and common
concepts
1 Scope
This part of ISO 13399 specifies a reference dictionary for reference systems for cutting tools, together
with their descriptive properties and domains of values.
This part of ISO 13399 specifies a reference dictionary containing:
— definitions and identifications of the classes of reference systems for cutting tools, with an associated
classification scheme;
— definitions and identifications of the data element types that represent the properties of reference
systems for cutting tools;
— definitions and identifications of domains of values for describing the above-mentioned data
element types.
Each class, property or domain of values of this application domain constitutes an entry of the reference
dictionary defined in this part of ISO 13399. It is associated with a computer-sensible and human-
readable definition, and with a computer-sensible identification. Identification of a dictionary entry
allows unambiguous reference to it from any application that implements the information model defined
in ISO 13399-1.
Definitions and identifications of dictionary entries are defined by means of standard data that consist
of instances of the EXPRESS entity data types defined in the common dictionary schema, resulting from
a joint effort between ISO/TC 184/SC 4 and IEC SC3D, and in its extensions defined in ISO 13584-24 and
ISO 13584-25.
The following are within the scope of this part of ISO 13399:
— standard data that represent the various classes of connection systems for cutting tools;
— standard data that represent the various properties of connection systems for cutting tools;
— standard data that represent domains of values used for properties of connection systems for
cutting tools;
— standard data that represent the various classes of reference systems for cutting tools;
— standard data that represent the various properties of reference systems for cutting tools;
— standard data that represent domains of values used for properties of reference systems for
cutting tools;
— one implementation method by which the standard data defined in this part of ISO 13399 can
be exchanged.
NOTE 1 The implementation method by which the standard data defined in this part of ISO 13399 can be
exchanged is specified in ISO 10303-21.
The following are outside the scope of this part of ISO 13399:
— applications where these standard data might be stored or referenced;
— implementation methods other than the one defined in this part of ISO 13399 by which the standard
data might be exchanged and referenced;
— information model for cutting tools;
— definitions of classes and properties for cutting items;
— definitions of classes and properties for tool items;
— definitions of classes and properties for assembly items.
— definitions of classes and properties for connection systems for cutting tools.
NOTE 2 The information model for cutting tools is defined in ISO 13399-1.
NOTE 3 The definitions of classes and properties for cutting items, tool items, adaptive items, assembly items
and connection systems are provided in ISO/TS 13399-2, ISO/TS 13399-3, ISO/TS 13399-4, ISO/TS 13399-5 and
ISO/TS 13399-60, respectively.
2 Normative references
The following documents, in whole or in part, are normatively referenced in this document and are
indispensable for its application. For dated references, only the edition cited applies. For undated
references, the latest edition of the referenced document (including any amendments) applies.
ISO 1832:2012, Indexable inserts for cutting tools — Designation
ISO 3002-1, Basic quantities in cutting and grinding — Part 1: Geometry of the active part of cutting tools —
General terms, reference systems, tool and working angles, chip breakers
ISO 13399-1:2006, Cutting tool data representation and exchange — Part 1: Overview, fundamental
principles and general information model
ISO/TS 13399-2:2014, Cutting tool data representation and exchange — Part 2: Reference dictionary for
cutting items
ISO/TS 13399-100, Cutting tool data representation and exchange — Part 100: Definitions, principles and
methods for reference dictionaries
ISO 13584-1, Industrial automation systems and integration — Parts library — Part 1: Overview and
fundamental principles
3 Terms and definitions
For the purposes of this document, the terms and definitions given in ISO/TS 13399-100 (structure and
contents of the dictionary) and the following apply.
NOTE The main collection of the terms and their definitions, which relate to adaptive items and their
properties, is provided in Annexes B to D.
3.1
applicable property
property that is defined for some family of items and that shall apply to any member of this family
[SOURCE: ISO 13584-24:2003, 3.3]
2 © ISO 2013 – All rights reserved

3.2
basic semantic unit
entity that provides an absolute and universally unique identification of a certain object of the application
domain that is represented as a dictionary element
[SOURCE: ISO 13584-42:2010, 3.4]
3.3
chip
material removed from a workpiece by a cutting process
[SOURCE: ISO/TS 13399-2:2014, 3.3]
3.4
cutting tool
device or assembly of items for removing workpiece material through a shearing action at the defined
cutting edge or edges of the device
Note 1 to entry: A cutting tool could be an assembly of one or more adaptive items a tool item and several cutting
items on a tool item. See Figure 1.
[SOURCE: ISO 13399-1:2006, 3.1]
3.5
data
formal representation of facts, concepts or instructions suitable for communication, interpretation or
processing by human beings or by computers
[SOURCE: ISO 10303-1:1994, 3.2.14, modified — The definition has been amended.]
3.6
data element type
unit of data for which the identification, description and value representation have been specified
[SOURCE: ISO 13584-42:2010, 3.13]
3.7
data exchange
storing, accessing, transferring and archiving of data
[SOURCE: ISO 10303-1:1994, 3.2.15]
3.8
data type
domain of values
[SOURCE: ISO 10303-11:2004, 3.3.5]
3.9
dictionary
table consisting of a series of entries with one meaning corresponding to each entry in the dictionary
and one dictionary entry identifying a single meaning
[SOURCE: ISO 13584-511:2006, 3.1.9, modified — The definition has been amended from two
sentences to one.]
Note 1 to entry: In the ISO 13399 series, a dictionary is a formal and computer-sensible representation of an ontology.
3.10
entity
class of information defined by its attributes that establishes a domain of values defined by common
attributes and constraints
[SOURCE: ISO/TS 13399-2:2014, 3.10]
3.11
entity data type
representation of an entity
[SOURCE: ISO 13399-2:2014, 3.11]
3.12
entity instance
named unit of data that represents a unit of information within the class defined by an entity
Note 1 to entry: An entity instance is a member of the domain established by an entity data type.
[SOURCE: ISO/TS 13399-2:2014, 3.12]
3.13
family of products
set of products represented by the same characterization class
[SOURCE: ISO 13584-42:2010, 3.16]
3.14
implementation method
means for computers to exchange data
[SOURCE: ISO 13399-2:2014, 3.15]
3.15
information
facts, concepts or instructions
[SOURCE: ISO 10303-1:1994, 3.2.20]
3.16
information model
formal model of a bounded set of facts, concepts or instructions to meet a specific requirement
[SOURCE: ISO 10303-1:1994, 3.2.21]
3.17
machine side
identification of a direction pointing towards the machine
3.18
machined surface
desired surface produced by the action of the cutting tool
[SOURCE: ISO 3002-1:1982, 3.1.2]
3.19
ontology
explicit and consensual specification of concepts of an application domain independent of any use of
these concepts
[SOURCE: ISO 13584-511, 2006, 3.1.20]
Note 1 to entry: In the ISO 13399 series, a dictionary is the formal and computer-sensible representation of an ontology.
4 © ISO 2013 – All rights reserved

3.20
property
defined parameter suitable for the description and differentiation of products
[SOURCE: ISO 13584-42:2010, 3.37]
3.21
visible property
property that has a definition meaningful in the scope of a given characterization class, but that does not
necessarily apply to the various products belonging to this class
[SOURCE: ISO 13584-42:2010, 3.46]
3.22
workpiece
object on which a cutting action is performed
[SOURCE: ISO/TS 13399-2:2014, 3.24]
3.23
workpiece side
identification of a direction pointing towards the workpiece
4 Abbreviated terms
For the purposes of this document, the following abbreviated terms apply.
BSU basic semantic unit
DET data element type
5 Representation of the ontology concepts as dictionary entries
5.1 General
In the following subclauses, a concept in the ontology is identified by a name in lower-case characters.
The name of a class that represents the concept in the dictionary is identified by bold, lower-case
characters with multiple words linked by an underscore character.
EXAMPLE “chamfer” is the name of a concept in the ontology. Therefore, “chamfer” is the identifier of the
class in the dictionary that represents the concept.
Each classified item in the following subclauses is associated with its definition from the dictionary.
Each entry in the dictionary, either a class or a property, is identified with a numerical code (BSU) that
is generated at random when the dictionary is compiled. A BSU may be made unique by the addition of a
code, which is a reference to the supplier of the dictionary.
The structure of the classification is summarized in Annex B. The complete definitions of the classes in
this part of ISO 13399are provided in Annex C. The properties applicable to these classes are defined
in Annex D.
5.2 Common concepts
The following subclauses identify and define features of cutting tools shared between several types of
components of the cutting tool.
5.2.1 adjustment
An adjustment is a device for making an alteration to achieve a different position.
adjustment has the following subclasses:
— adjustment axial;
— adjustment radial.
5.2.1.1 adjustment_axial
An adjustment_axial is a device for making an alteration to achieve a different position in a direction
parallel to the longitudinal axis of a component.
5.2.1.2 adjustment_radial
An adjustment_radial is a device for making an alteration to achieve a different position in a direction
perpendicular to the longitudinal axis of the component.
5.2.1.3 bolt_hole_circle
A bolt_hole_circle is an arrangement of holes in a circle to enable a bolted connection.
5.2.2 Coolant_supply
A coolant_supply is a system of channels to supply a fluid to reduce the temperature of the cutting operation.
NOTE The fluid could be a liquid or a gas.
5.2.3 Cutting_operation
A cutting_operation is a generic family of actions, which remove material from a workpiece. The
actions included in the generic class are not exclusive and other actions are possible. The intention of
the ISO 13399 series is to avoid, if possible, the association of a particular type of tool with a particular
cutting operation. These concepts are included in the dictionary so that they can be referenced from
the information model defined in ISO 13399-1. Cutting_operation has the following simple subclasses:
— Boring;
— broaching circular;
— broaching linear;
— counterboring;
— countersinking;
— drilling;
— drilling deep hole;
— drilling step;
— grooving;
— milling face;
— milling profile;
— milling shoulder;
6 © ISO 2013 – All rights reserved

— milling slot;
— parting;
— reaming cylindrical;
— reaming profile;
— slitting;
— threading external;
— threading internal;
— trepanning;
— turning external;
— turning internal.
5.2.3.1 boring
Changing the diameter of an existing hole in a workpiece with one or more passes of a cutting tool.
5.2.3.2 broaching_circular
Changing the dimensions of an existing surface profile by a single circular motion of a cutting tool.
5.2.3.3 broaching_linear
Changing the dimensions of an existing surface profile by a single linear motion of a cutting tool.
5.2.3.4 counterboring
Creating an enlarged section of a hole to provide concentric holes with the transitory shoulder between
the holes at 90° to the axis of the holes.
5.2.3.5 countersinking
Creating an enlarged section of a hole to provide concentric holes with the transitory shoulder between
the holes at an angle to the axis of the holes.
5.2.3.6 drilling
Creating a new cylindrical hole in a workpiece where the depth of the hole is normally less than 10 times
the diameter of the hole.
NOTE Either the cutting tool or the workpiece can rotate.
5.2.3.7 drilling_deep_hole
Creating a new cylindrical hole in a workpiece where the depth of the hole is normally more than 10
times the diameter of the hole.
5.2.3.8 drilling_step
Creating a new hole with more than one diameter by a single operation.
5.2.3.9 grooving
Creating multiple connected surfaces on a circular section of a workpiece
5.2.3.10 milling_face
Creating a single flat external surface on a workpiece by a rotating tool.
NOTE The feed is achieved by the motion of the workpiece or by the motion of the cutting tool or by the
combination of both motions.
5.2.3.11 milling_profile
Creating curved surfaces on a workpiece by a rotating cutting tool
NOTE The feed is achieved by the motion of the workpiece or by the motion of the cutting tool or by the
combination of both motions
5.2.3.12 milling_shoulder
Creating perpendicular connected surfaces on a workpiece by a rotating cutting tool.
NOTE The feed is achieved by the motion of the workpiece or by the motion of the cutting tool or by the
combination of both motions.
5.2.3.13 Milling_slot
Creating multiple connected surfaces in the workpiece by a rotating cutting tool.
NOTE The feed is achieved by the motion of the workpiece or by the motion of the cutting tool or by the
combination of both motions.
5.2.3.14 parting
Separating a rotating workpiece into two parts with a stationary cutting tool.
5.2.3.15 reaming cylindrical
Changing the diameter of an existing cylindrical hole to achieve a close tolerance on the diameter and to
improve the surface finish.
5.2.3.16 reaming_profile
Changing the diameter of an existing profiled hole to achieve a close tolerance on the diameter and to
improve the surface finish.
5.2.3.17 slitting
Separating a stationary workpiece into two parts with a rotating tool.
5.2.3.18 threading_external
Creating a screw thread on the external surface of a workpiece with a cutting tool.
NOTE This operation includes: die threading, thread turning and thread milling operations.
8 © ISO 2013 – All rights reserved

5.2.3.19 Threading_internal
Creating a screw thread on an internal surface of a workpiece with a cutting tool.
NOTE This operation includes: tapping, thread turning and thread milling operations.
5.2.3.20 trepanning
Creating a new annular hole that leaves the central portion of the hole intact.
NOTE The central portion can be left attached to the workpiece or can be detached.
5.2.3.21 turning_external
Creation of a new external surface on a rotating workpiece with a stationary cutting tool.
5.2.3.22 turning_internal
Creating a new internal surface on a rotating workpiece by a stationary cutting tool.
5.2.4 Cutting_tool
A Cutting_tool is a device or assembly of items for removing workpiece material through a shearing
action at the edge or edges of the device.
NOTE A cutting tool could be an assembly of one or more adaptive items a tool item and several cutting items
on a tool item.
5.2.5 flange
A flange is a projecting rim or edge on the outside of an object.
5.2.6 keyway
A keyway is a slot in which a shaped piece of metal can be inserted to transfer torque between two
connected items.
5.2.7 locking_mechanism
A locking_mechanism is a device that can be actuated to secure the coupling of two items together.
5.2.8 runout_axial
A runout_axial is a variation in the location of the end surface of the cutting reference point of a rotating
tool item or the end surface of an adaptive item.
5.2.9 runout_radial
A runout_radial is a variation in the location of the circumference of a rotating tool item or adaptive item.
5.2.10 tool_thread_external
A tool_thread_external is a continuous and projecting helical ridge of uniform section on an external
cylindrical surface.
tool_thread_external has the following subclasses:
— thread_inch_external;
— thread_metric_external;
— thread_trapezoidal_external.
5.2.10.1 thread_inch_external
A thread_inch_external is an external tool thread with dimensions conforming to ISO 725.
5.2.10.2 thread_metric_external
A thread_metric_external is an external tool thread with dimensions conforming to ISO 724.
5.2.10.3 thread_trapezoidal_external
A thread_trapezoidal_external is an external tool thread with dimensions conforming to ISO 2904.
5.2.11 tool_thread_internal
A tool_thread_internal is a continuous and projecting helical ridge of uniform section on a cylindrical
or conical internal surface.
tool_thread_internal has the following subclasses:
— thread_inch_internal
— thread_metric_internal
— thread_trapezoidal_internal
5.2.11.1 thread_inch_internal
internal screw thread with dimensions conforming to ISO 725.
5.2.11.2 thread metric internal
internal screw thread with dimensions conforming to ISO 724.
5.2.11.3 thread trapezoidal internal
internal screw thread conforming to the dimensions in ISO 2904.
5.3 reference system
reference_system is a generic of family of items that provide a reference basis for the definitions
of properties.
NOTE The convention for all the reference systems is the tool-in-hand system.
reference system has the following subclasses:
— coordinate_axis_system;
— coordinate_system_workpiece_side;
— cutting_reference_point;
— feed_direction_primary;
— irregular_insert_position;
— master_insert;
10 © ISO 2013 – All rights reserved

— mirror_plane;
— prismatic_adaptive_item_position;
— prismatic_tool_item_position;
— regrinding;
— regular_insert_position;
— round_adaptive_item_position;
— round_tool_item_position;
— theoretical_sharp_point;
— tool_cutting_edge_plane;
— tool_feed_plane;
— tool_rake_plane;
— xy_plane;
— xyw_plane;
— xz_plane;
— xzw_plane;
— yz_plane;
— yzw_plane.
5.3.1 primary coordinate_axis_system
The coordinate_axis_system is a right-handed rectangular Cartesian system in three-dimensional
space with three principal axes labelled X, Y and Z.
5.3.2 coordinate_axis_system_workpiece_side
The coordinate_axis_system_workpiece_side is a right-handed rectangular Cartesian system in
three-dimensional space with three axes, labelled XW, YW and ZW, which are the intersections of the
xyw-plane, the xzw-plane and the yzw-plane, respectively.
5.3.3 cutting_reference_point
The cutting_reference_point is the theoretical point of the tool from which the major functional
dimensions are taken.
For the calculation of this point, the following cases apply.
a) Case 1: Tool cutting edge angle ≤ 90 - the point is the intersection of: the tool_cutting_edge_plane,
the tool_feed_plane, and the tool_rake_plane.
b) Case 2: Tool cutting edge > 90 - the point is the intersection of: the tool_feed_plane, a plane
perpendicular to tool feed plane and tangential to the cutting corner, and the tool rake plane.
c) Case 3: ISO tool styles D and V with only axial rake. The point is the intersection of: a plane
perpendicular to the primary feed direction and tangential to the cutting edge (tangential point), a
plane parallel to the feed direction through the tangential point, and the tool_rake_plane.
d) Case 4: Round inserts:
1) One feed direction parallel to the tool axis, primary used for turning tools. The point is the
intersection of: a plane perpendicular to the primary feed direction and tangential to the cutting
edge (tangential point), a plane parallel to the feed direction through the tangential point, and
the tool rake plane.
2) One feed direction perpendicular to the tool axis, primarily used for milling tools. The point is
the intersection of: a plane perpendicular to the primary feed direction and tangential to the
cutting edge (tangential point), a plane parallel to the feed direction through the tangential
point, and the tool rake plane.
3) Two feed directions, one parallel to the tool axis and one perpendicular to the tool axis with
two cutting reference points. Each point is the intersection of: a plane perpendicular to its
feed direction and tangential to the cutting edge (tangential point), a plane parallel to the feed
direction through the tangential point, and the tool rake plane.
REMARKS  In Case 3, the theoretical sharp corner of the insert and the cutting reference point are on
the plane that is perpendicular to the tool feed plane.
5.3.4 feed_direction_primary
A feed_direction_primary is a direction of movement of a cutting tool to achieve the main cutting
function of the tool.
5.3.5 irregular_insert_position
The irregular_insert_position is a location of an irregular cutting item on the coordinate axis system.
NOTE 1 The cutting edges are in the xy-plane with the insert located in the XY quadrant, the cutting profile is
pointing in the negative Y direction, the physical extremity of the cutting profile is on the positive x-axis and the
extreme physical point of the insert is on the y-axis.
NOTE 2 The definition applies to right-handed inserts. The position of left-handed inserts is as mirrored
through the xz-plane.
5.3.6 master_insert
A master_insert is a nominal replaceable cutting item used for defining the dimensions of a cutting tool.
NOTE A master insert can substitute for either a regular or an irregular insert and uses the position of the
item that it replaces.
REMARKS  Definitions making use of a master insert also apply to solid and brazed tools.
5.3.7 mirror_plane
A mirror_plane is the YZ-plane in the primary_coordinate_system.
5.3.8 prismatic_adaptive_item_position
A prismatic_adaptive_item_position is a location on the primary coordinate system of an adaptive
item with planar sides.
The following apply:
— the base of the adaptive item shall be coplanar with the XZ-plane;
— the normal for the base of the item shall be in the Y direction;
— the rear backing surface shall be coplanar with the YZ-plane;
12 © ISO 2013 – All rights reserved

— the normal for the rear backing surface shall be in the X direction;
— the end of the item shall be coplanar with the XY-plane;
— the normal for the end of the item shall be in the Z direction;
— if with a bore, then the vector of the bore of the item that points in the Z direction shall also point
towards the workpiece siderear backing surface shall be coplanar with the YZ-plane;
REMARKS  Applicable to right-handed adaptive items. Left-handed items are as defined for right-
handed items, but mirrored through the YZ-plane.
5.3.9 prismatic_tool_item_position
A prismatic_tool_item_position is a location on the primary coordinate system of a tool item with
planar sides.
The following apply:
— the base of the tool item shall be coplanar with the XZ-plane;
— the normal for the base of the item shall be in the Y-direction;
— the rear backing surface shall be coplanar with the YZ-plane;
— the end of the item shall be coplanar with the XY-plane;
— the normal for the end of the item shall be in the -Z direction;
— the rake face of the primary cutting item shall be completely visible in the XZ quadrant;
— for cartridges, the top of the axial adjustment screw shall be coincident with XY-plane.
REMARKS  Applies to right-handed tools. Left-handed items are as defined for right-handed items, but
mirrored through the YZ-plane.
5.3.10 regrinding
A regrinding is modifying the shape of a component of a cutting tool to restore the original shape or to
create a new shape.
5.3.11 regular_insert_position
A regular_insert_position is a location of a regular cutting item on the primary coordinate system.
NOTE 1 The cutting edges are placed on the XY-plane of the primary coordinate system with the insert located
in the XY quadrant; the major cutting edge is on the positive x-axis and the extreme theoretical sharp point of the
insert is on the y-axis.
NOTE 2 The definition applies to right-handed inserts. The position of left-handed inserts is as mirrored
through the YZ-plane.
REMARKS  The diagrams illustrate the positions for different shapes of inserts.
5.3.12 round_adaptive_item_position
A round_adaptive_item_position is a location on the primary coordinate system of an adaptive item
with a non-planar sided cross section.
The following apply:
— the axis of the adaptive item shall be colinear with the Z axis;
---------------------
...