SIST EN ISO 10218-1:2011

SLOVENSKI STANDARD
oSIST ISO/DIS 10218-1:2009
01-december-2009
Roboti in robotske naprave - Varnostne zahteve - 1. del: Industrijski roboti
(ISO/DIS 10218-1:2009)
Robots and robotic devices - Safety requirements - Part 1: Industrial robots (ISO/DIS
10218-1:2009)
Robots pour environnements industriels - Exigences de sécurité - Partie 1: Robots
industriels (ISO/DIS 10218-1:2009)
Ta slovenski standard je istoveten z: prEN ISO 10218-1
ICS:
25.040.30 Industrijski roboti. Industrial robots.
Manipulatorji Manipulators
oSIST ISO/DIS 10218-1:2009 en
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.

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oSIST ISO/DIS 10218-1:2009

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oSIST ISO/DIS 10218-1:2009
DRAFT INTERNATIONAL STANDARD ISO/DIS 10218-1
ISO/TC 184/SC 2 Secretariat: SIS
Voting begins on: Voting terminates on:
2009-08-27 2010-01-27
INTERNATIONAL ORGANIZATION FOR STANDARDIZATION • МЕЖДУНАРОДНАЯ ОРГАНИЗАЦИЯ ПО СТАНДАРТИЗАЦИИ • ORGANISATION INTERNATIONALE DE NORMALISATION
Robots and robotic devices — Safety requirements —
Part 1:
Industrial robots
Robots pour environnements industriels — Exigences de sécurité —
Partie 1: Robot industriel
(Revision of first edition of ISO 10218-1:2006 and of ISO 10218-1:2006/Cor.1:2006)
ICS 25.040.30

ISO/CEN PARALLEL PROCESSING
This draft has been developed within the International Organization for Standardization (ISO), and
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This draft is hereby submitted to the ISO member bodies and to the CEN member bodies for a parallel
five-month enquiry.
Should this draft be accepted, a final draft, established on the basis of comments received, will be
submitted to a parallel two-month approval vote in ISO and formal vote in CEN.
In accordance with the provisions of Council Resolution 15/1993 this document is circulated in
the English language only.
Conformément aux dispositions de la Résolution du Conseil 15/1993, ce document est distribué
en version anglaise seulement.
To expedite distribution, this document is circulated as received from the committee secretariat.
ISO Central Secretariat work of editing and text composition will be undertaken at publication
stage.
Pour accélérer la distribution, le présent document est distribué tel qu'il est parvenu du
secrétariat du comité. Le travail de rédaction et de composition de texte sera effectué au
Secrétariat central de l'ISO au stade de publication.
THIS DOCUMENT IS A DRAFT CIRCULATED FOR COMMENT AND APPROVAL. IT IS THEREFORE SUBJECT TO CHANGE AND MAY NOT BE
REFERRED TO AS AN INTERNATIONAL STANDARD UNTIL PUBLISHED AS SUCH.
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©
International Organization for Standardization, 2009

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oSIST ISO/DIS 10218-1:2009
ISO/DIS 10218-1
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oSIST ISO/DIS 10218-1:2009
ISO/DIS 10218-1
Contents Page
Foreword .iv
Introduction.v
1 Scope.1
2 Normative references.1
3 Terms and definitions .2
4 Hazard identification and risk assessment.7
5 Design requirements and protective measures .8
5.1 General .8
5.2 General requirements .8
5.3 Actuating controls.9
5.4 Safety-related control system performance (hardware/software).10
5.5 Robot stopping functions.11
5.6 Reduced speed control.12
5.7 Operational modes.13
5.8 Pendant controls .14
5.9 Control of simultaneous motion .15
5.10 Collaborative operation requirements .16
5.11 Singularity protection .17
5.12 Axis limiting .17
5.13 Movement without drive power.19
5.14 Provisions for lifting.19
5.15 Electrical connectors .19
6 Information for Use .19
6.1 General .19
6.2 Instruction handbook.19
6.3 Marking.21
Annex A (normative) List of significant hazards .22
Annex B (normative) Stopping time and distance metric.24
Annex C (informative) Functional characteristics of 3-position enabling device .26
Annex D (informative) Optional features .27
Annex E (informative) Methods for labelling.29
Bibliography.30

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oSIST ISO/DIS 10218-1:2009
ISO/DIS 10218-1
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.
International Standards are drafted in accordance with the rules given in the ISO/IEC Directives, Part 2.
The main task of technical committees is to prepare International Standards. Draft International Standards
adopted by the technical committees are circulated to the member bodies for voting. Publication as an
International Standard requires approval by at least 75 % of the member bodies casting a vote.
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.
ISO 10218-1 was prepared by Technical Committee ISO/TC 184, Automation systems and integration,
Subcommittee SC 2, Robots and robotic devices.
This second edition cancels and replaces the first edition (ISO 10218-1:2006), which has been technically
revised.
This revised International Standard updates the document based on experience gained in developing the
Part 2 guidance on system and integration requirements and to ensure it remains in line with minimum
requirements of a harmonized type C standard for industrial robots. Revised technical requirements include,
but are not limited to, definition and requirements for singularity, safeguarding of transmission hazards, power
loss requirements, safety control circuit performance, addition of a category 2 stopping function, mode
selection, power and force limiting requirements, marking, and updated stopping time and distance metric and
features.
ISO 10218 consists of the following parts, under the general title Robots and robotic devices — Safety
requirements:
⎯ Part 1: Industrial robot
⎯ Part2: Industrial robot system and integration:
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oSIST ISO/DIS 10218-1:2009
ISO/DIS 10218-1
Introduction
ISO 10218 has been created in recognition of the particular hazards that are presented by industrial robots
and industrial robot systems.
This document is a type C standard as stated in ISO 12100-1.
The machinery concerned and the extent to which hazards, hazardous situations and events are covered are
indicated in the scope of this document.
When provisions of this type C standard are different from those which are stated in type A or B standards, the
provisions of this type C standard take precedence over the provisions of the other standards for machines
that have been designed and built according to the provisions of this type C standard.
Hazards associated with robots are well recognized, but the sources of the hazards are frequently unique to a
particular robot system. The number and type(s) of hazard(s) are directly related to the nature of the
automation process and the complexity of the installation. The risks associated with these hazards vary with
the type of robot used and its purpose and the way in which it is installed, programmed, operated and
maintained.
NOTE 1 Not all of the hazards identified by ISO 10218 apply to every robot and nor will the level of risk associated with
a given hazardous situation be the same from robot to robot. Consequently the safety requirements and/or protective
measures may vary from what is specified in ISO 10218. A risk assessment may be conducted to determine what the
protective measures should be.
In recognition of the variable nature of hazards with different uses of industrial robots, ISO 10218 is divided
into two parts; Part 1 provides guidance for the assurance of safety in design and construction of the robot.
Since safety in the application of industrial robots is influenced by the design and application of the particular
robot system integration, Part 2 will provide guidelines for the safeguarding of personnel during robot
integration, installation, functional testing, programming, operation, maintenance and repair.
NOTE 2 While audible noise is generally considered a hazard associated with the industrial environment, the robot as
defined in 3.18 cannot be considered the final machine, rather the robot system as defined in 3.20 is the machine for noise
consideration. Therefore the hazard due to noise will be dealt with in ISO 10218-2.
ISO 10218 is not applicable to robots which were manufactured prior to its publication date.
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oSIST ISO/DIS 10218-1:2009

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oSIST ISO/DIS 10218-1:2009
DRAFT INTERNATIONAL STANDARD ISO/DIS 10218-1

Robots and robotic devices — Safety requirements —
Part 1:
Industrial robots
1 Scope
This part of ISO 10218 specifies requirements and guidelines for the inherent safe design, protective
measures and Information for Use of industrial robots, as defined in Clause 3. It describes basic hazards
associated with robots and provides requirements to eliminate, or adequately reduce, the risks associated with
these hazards.
This part of ISO 10218 does not address the robot as a complete machine. Noise emission is generally not
considered a significant hazard of the robot alone, but will be fully covered in Part 2 for the robot system or the
complete machine.
This part of ISO 10218 does not apply to non-industrial robots although the safety principles established in
ISO 10218 may be utilized for these other robots. Examples of non-industrial robot applications include, but
are not limited to: undersea, military and space robots, tele-operated manipulators, prosthetics and other aids
for the physically impaired, micro-robots (displacement less than 1 mm), surgery or healthcare, and service or
consumer products.
NOTE 1 Requirements for robot systems, integration, and installation are covered in Part 2.
NOTE 2 Additional hazards may be created by specific applications (e.g. welding, laser cutting, machining). These
hazards may need to be considered during robot design.
2 Normative references
The following referenced documents are indispensable for the application 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 9283:1998, Manipulating industrial robots — Performance criteria and related test methods
ISO 12100-1, Safety of machinery — Basic concepts, general principles for design — Part 1: Basic
terminology, methodology
ISO 12100-2, Safety of machinery — Basic concepts, general principles for design — Part 2: Technical
principles
ISO 13849-1:2006, Safety of machinery — Safety-related parts of control systems — Part 1: General
principles for design
ISO 13850, Safety of machinery — Emergency stop — Principles for design
ISO 13855, Safety of machinery — Positioning of protective equipment with respect to the approach speeds of
parts of the human body
ISO 14121, Safety of machinery — Principles for risk assessment
IEC 60204-1, Safety of machinery — Electrical equipment of machines — Part 1: General requirements
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oSIST ISO/DIS 10218-1:2009
ISO/DIS 10218-1
IEC 62061:2005, Safety of machinery — Functional safety of safety-related electrical, electronic and
programmable control systems
IEC 61000-6-2, Electromagnetic compatibility (EMC) — Part 6-2: Generic standards — Immunity for industrial
environments
IEC 61000-6-4, Electromagnetic compatibility (EMC) — Part 6: Generic standards — Section 4: Emission
standard for industrial environments
3 Terms and definitions
For the purposes of this document, the terms and definitions given in ISO 12100-1 and the following apply.
3.1
actuating control
a) mechanical mechanism within a control device
EXAMPLE A rod which opens contacts.
b) device which initiates a (un)locking sequence
EXAMPLE Specialized key.
3.2
automatic mode
operating mode in which the robot control system operates in accordance with the task programme
[ISO 8373:1994, definition 5.3.8.1]
3.3
automatic operation
state in which the robot is executing its programmed task as intended
[ISO 8373:1994, definition 5.5]
3.4
collaborative operation
state in which purposely designed robots work in direct cooperation with a human within a defined workspace
3.5
collaborative workspace
workspace within the safeguarded space where the robot and a human can perform tasks simultaneously
during production operation
3.6
cycle
single execution of a task programme
[ISO 8373:1994, definition 6.22]
3.7
drive power
energy source or sources for the robot actuators
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oSIST ISO/DIS 10218-1:2009
ISO/DIS 10218-1
3.8
end-effector
device specifically designed for attachment to the mechanical interface to enable the robot to perform its task
EXAMPLES Gripper, nutrunner, welding gun, spray gun.
[ISO 8373:1994, definition 3.11]
3.9
energy source
any electrical, mechanical, hydraulic, pneumatic, chemical, thermal, potential, kinetic, or other sources of
power
3.10
hazardous motion
any motion that is likely to cause personal physical injury or damage to health
3.11
limiting device
device that restricts the maximum space by stopping or causing to stop all robot motion and is independent of
the control programme and the task programmes
3.12
local control
state of the system or portions of the system in which the system is operated from the control panel or
pendant of the individual machines only
3.13
manual mode
control state that allows the generation, storage, and playback of positional data points
[ISO 8373:1994, definition 5.3.8.2 modified]
3.14
pendant
teach pendant
hand-held unit linked to the control system with which a robot can be programmed or moved
[ISO 8373:1994, definition 5.8]
3.15 Programme
3.15.1
control programme
inherent set of instructions which defines the capabilities, actions, and responses of a robot system
NOTE This programme is fixed and usually not modified by the user.
[ISO 8373:1994, definition 5.1.2]
3.15.2
task programme
set of instructions for motion and auxiliary functions that define the specific intended task of the robot system
NOTE 1 This type of programme is normally generated by the user.
NOTE 2 An application is a general area of work, a task is specific within the application.
[ISO 8373:1994, definition 5.1.1]
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oSIST ISO/DIS 10218-1:2009
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3.15.3
task programming
act of providing the task programme (3.16.2)
[ISO 8373:1994, definition 5.2.1]
3.15.4
programmer
person designated to prepare the task programme
[ISO 8373:1994, definition 2.17]
3.15.5
programme path
path traced by the TCP during the execution of a task programme
3.15.6
programme verification
execution of a task programme for the purpose of confirming the robot path and process performance
NOTE Verification may include the total programme path or a segment of the path. The instructions may be executed
in a single instruction or continuous instruction sequence. Verification is used in new applications and in fine tuning/editing
of existing ones.
3.16
protective stop
type of interruption of operation that allows an orderly cessation of motion for safeguarding purposes and
which retains the programme logic to facilitate a restart
3.17
robot
industrial robot
automatically controlled, reprogrammable multipurpose manipulator, programmable in three or more axes,
which may be either fixed in place or mobile for use in industrial automation applications
NOTE 1 The robot includes:
⎯ the manipulator (including actuators);
⎯ the controller including teach pendant, and any communication interface (hardware and software).
NOTE 2 This includes any additional axes which are controlled by the robot controller.
NOTE 3 The following devices are considered industrial robots for the purpose of this part of ISO 10218:
— hand-guided robots;
— the manipulating portions of mobile robots;
— collaborating robots.
[ISO 8373:1994, definition 2.6 modified]
3.18
robot actuator
powered mechanism that converts electrical, hydraulic, or pneumatic energy to effect motion
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oSIST ISO/DIS 10218-1:2009
ISO/DIS 10218-1
3.19
robot system
industrial robot system
system comprising:
⎯ robot;
⎯ end-effector(s);
⎯ any machinery, equipment, devices, or sensors supporting the robot performing its task
NOTE The robot system requirements, including those for controlling hazards, are contained in ISO 10218-2.
[ISO 8373:1994, definition 2.14 modified]
3.20
Safety-rated
having a prescribed safety function suitable for its intended use
3.20.1
Safety-rated monitored speed
a limit placed either on the Cartesian speed of a point relative to the robot flange (e.g. the TCP) or on the
speed of one or more axes having a specified sufficient safety performance
3.20.2
Safety-rated reduced speed
a safety-rated monitored speed where the speed limit is set to the value specified for reduced speed
(250mm/s or less)
NOTE 1 The safety-rated reduced speed value is not necessarily the value set in the reduced speed control function.
NOTE 2 The difference between safety-rated monitored speed and safety-rated reduced speed is that safety-rated
monitored speed can result in speeds greater than 250mm/s. This could be used for example to ensure that stopping
distances are minimized.
3.20.3
Safety-rated soft axis and space limiting
Safety-rated soft limit
a limit placed on the range of motion of the robot by a software or firmware based system having a specified
sufficient safety performance. The safety-rated soft limit might be the point where a stop is initiated, or it might
ensure that the robot does not move beyond the limit
3.20.4
Safety-rated output
an output signal having a specified sufficient safety performance
3.20.5
Safety-rated zone output
a safety-rated output indicating the state of the robot position relative to a safety-rated soft limit (e.g. inside the
zone or outside the zone)
3.21
simultaneous motion
motion of two or more robots at the same time under the control of a single control station and which may be
coordinated or may be synchronous using common mathematical correlation
EXAMPLE 1 Example of a single control station may be a teach pendant.
EXAMPLE 2 Coordination can be done as master/slave.
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ISO/DIS 10218-1
3.22
single point of control
ability to operate the robot such that initiation of robot motion is only possible from one source of control and
cannot be overridden from another initiation source
3.23
singularity
condition where a set of robot axis velocities produces zero Cartesian velocity (translational or rotational) of
either the robot flange or the tool center point. Motions defined in Cartesian space that pass near singularities
can produce high axis speeds. These high speeds can be unexpected to an operator
3.24
reduced speed control
slow speed control
mode of robot motion control where the speed is limited to 250 mm/s or less to allow persons sufficient time to
either withdraw from the hazardous motion or stop the robot
3.25
space
three dimensional volume encompassing the movements of all robot parts through their axes
3.25.1
maximum space
space which can be swept by the moving parts of the robot as defined by the manufacturer, plus the space
which can be swept by the end-effector and the workpiece
[ISO 8373:1994, definition 4.8.1]
3.25.2
restricted space
portion of the maximum space restricted by limiting devices that establish limits which will not be exceeded
[ISO 8373:1994, definition 4.8.2 modified]
3.25.3
operating space
operational space
portion of the restricted space that is actually used while performing all motions commanded by the task
programme
[ISO 8373:1994, definition 4.8.3]
3.25.4
safeguarded space
space defined by the perimeter safeguarding devices
3.26
teach
teach programming
programming performed by
a) manually leading the robot end-effector; or
b) manually leading a mechanical simulating device; or
c) using a teach pendant to move the robot through the desired actions
[ISO 8373:1994, definition 5.2.3]
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3.27
teacher
person who provides the robot with a specific set of instructions to perform a task
NOTE See programmer (3.16.4).
3.28
tool centre point
TCP
point defined for a given application with regard to the mechanical interface coordinate system
[ISO 8373:1994, definition 4.9]
3.29
user
entity that uses robots and is responsible for the personnel associated with the robot operation
4 Hazard identification and risk assessment
Annex A contains a list of hazards that can be present with robots. A hazard analysis shall be carried out to
identify any further hazards that may be present.
A risk assessment shall be carried out on those hazards identified in the hazard identification. This risk
assessment shall give particular consideration to:
a) the intended operations at the robot, including teaching, maintenance, setting, and cleaning;
b) unexpected start-up;
c) access by personnel from all directions;
d) reasonably foreseeable misuse of the robot;
e) the effect of failure in the control system; and
f) where necessary, the hazards associated with the specific robot application.
Risks shall be eliminated or reduced first by design or by substitution, then by safeguarding and other
complementary measures. Any residual risks shall then be reduced by other measures (e.g. warnings, signs,
training).
The requirements contained in Clause 5 have been derived from the iterative process of applying
safeguarding measures, in accordance with Figures 1 and 2 of ISO 12100-1 and ISO 12100-2, to the hazards
identified in Annex A.
NOTE 1 ISO 12100 and ISO 14121 provide requirements and guidance in performing hazard identification and risk
reduction.
NOTE 2 Hazard identification and risk assessment requirements for robot systems, integration, and installation are
covered in Part 2.
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oSIST ISO/DIS 10218-1:2009
ISO/DIS 10218-1
5 Design requirements and protective measures
5.1 General
The robot shall be designed according to the principles of ISO 12100-1 for relevant hazards. Significant
hazards, such as sharp edges, are not dealt with by this document.
Robots shall be designed and constructed to comply with the following requirements.
NOTE 1 The requirements for this clause can be satisfied by methods of verification including but not limited to:
⎯ A: visual inspection;
⎯
...