SIST IEC/TR 61000-5-2:1998
(Main)Electromagnetic compatibility (EMC) - Part 5: Installation and mitigation guidelines - Section 2: Earthing and cabling
Electromagnetic compatibility (EMC) - Part 5: Installation and mitigation guidelines - Section 2: Earthing and cabling
This technical report (type 3) covers guidelines for the earthing and cabling of electrical and electronic systems and installations aimed at ensuring electromagnetic compatibility among electrical and electronic apparatus or systems. More particularly, it is concerned with earthing practices and with cables used in industrial, commercial and residential installations. This technical report is intended for use by installers and users, and to some extent, manufacturers of sensitive electrical or electronic installations and systems, and equipment with high emission levels that could degrade the overall electromagnetic environment.
Compatibilité électromagnétique (CEM) - Partie 5: Guides d'installation et d'atténuation - Section 2: Mise à la terre et câblage
Ce rapport technique de type 3 présente des recommandations concernant la mise à la terre et le câblage des systèmes et installations électriques et électroniques, destinées à garantir la compatibilité électromagnétique entre les appareils ou systèmes électriques et électroniques. Il porte plus particulièrement sur les pratiques de mise à la terre et sur les câbles utilisés dans des environnements industriels, commerciaux et résidentiels. Ce rapport technique est destiné à être utilisé par les installateurs et les utilisateurs et, dans une certaine mesure, par les fabricants d'installations et de systèmes électriques ou électroniques sensibles, ainsi que d'équipements présentant des niveaux élevés d'émission susceptibles de dégrader l'environnement électromagnétique en général.
Electromagnetic compatibility (EMC) - Part 5: Installation and mitigation guidelines - Section 2: Earthing and cabling
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IEC 61504
®
Edition 2.0 2017-05
INTERNATIONAL
STANDARD
NORME
INTERNATIONALE
Nuclear facilities – Instrumentation and control systems important to safety –
Centralized systems for continuous monitoring of radiation and/or levels of
radioactivity
Installations nucléaires – Systèmes d’instrumentation et de contrôle-commande
importants pour la sûreté – Systèmes centralisés pour la surveillance en continu
des rayonnements et/ou des niveaux de radioactivité
IEC 61504:2017-05(en-fr)
---------------------- Page: 1 ----------------------
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---------------------- Page: 2 ----------------------
IEC 61504
®
Edition 2.0 2017-05
INTERNATIONAL
STANDARD
NORME
INTERNATIONALE
Nuclear facilities – Instrumentation and control systems important to safety –
Centralized systems for continuous monitoring of radiation and/or levels of
radioactivity
Installations nucléaires – Systèmes d’instrumentation et de contrôle-commande
importants pour la sûreté – Systèmes centralisés pour la surveillance en continu
des rayonnements et/ou des niveaux de radioactivité
INTERNATIONAL
ELECTROTECHNICAL
COMMISSION
COMMISSION
ELECTROTECHNIQUE
INTERNATIONALE
ICS 27.120.20 ISBN 978-2-8322-4222-3
Warning! Make sure that you obtained this publication from an authorized distributor.
Attention! Veuillez vous assurer que vous avez obtenu cette publication via un distributeur agréé.
® Registered trademark of the International Electrotechnical Commission
Marque déposée de la Commission Electrotechnique Internationale
---------------------- Page: 3 ----------------------
– 2 – IEC 61504:2017 IEC 2017
CONTENTS
FOREWORD . 4
INTRODUCTION . 6
1 Scope . 9
2 Normative references . 9
3 Terms and definitions . 11
4 Design requirements . 12
4.1 General . 12
4.1.1 Background . 12
4.1.2 General characteristics and lifecycle (IEC 61559-1:2009, 4.1.1) . 13
4.1.3 Safety classification and applicable standards (IEC 61559-1:2009, 4.1.2) . 13
4.1.4 System architecture and configuration (IEC 61559-1:2009, 4.1.3) . 13
4.1.5 Location of detector assemblies (IEC 61559-1:2009, 4.1.4) . 15
4.1.6 Failure mode . 16
4.1.7 Interlock functions . 16
4.1.8 Control functions . 16
4.1.9 Control of access . 16
4.1.10 Testability . 16
4.1.11 Maintainability . 17
4.1.12 Operator interface . 17
4.1.13 Data communication . 17
4.2 Design requirements for the subassemblies . 17
4.2.1 Detector assembly (IEC 61559-1:2009, 4.2.1) . 17
4.2.2 Processing assembly (IEC 61559-1:2009, 4.2.2) . 17
4.2.3 Alarm assembly (IEC 61559-1:2009, 4.2.3) . 18
4.2.4 Subsystem computer . 18
4.2.5 Operator console . 18
4.2.6 Interconnections . 18
4.3 Central computer . 18
4.3.1 General (IEC 61559-1:2009, 4.3.1) . 18
4.3.2 Functional requirements of the central computer (IEC 61559-1:2009,
4.3.2) . 18
4.3.3 Checking normal operation of the equipment (IEC 61559-1 4.3.3) . 19
4.3.4 Modifications . 20
4.3.5 Recommended features . 20
4.4 Electrical characteristics . 21
4.4.1 General (IEC 61559-1:2009, 4.4.1) . 21
4.4.2 Electromagnetic compatibility (IEC 61559-1:2009, 4.4.2) . 21
4.5 Radiation monitoring functions . 21
5 General test procedures . 21
5.1 General . 21
5.2 Test requirements (IEC 61559-1:2009, 5.1). 21
5.3 Test procedures for subassemblies . 21
5.3.1 Test procedures for the detector assembly (IEC 61559-1:2009, 5.2) . 21
5.3.2 Test procedures for the combination of processing, detector and alarm
assemblies (IEC 61559-1:2009, 5.3) . 21
5.3.3 Test procedures for subsystem computer. 22
5.3.4 Test procedures for operator consoles . 22
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IEC 61504:2017 IEC 2017 – 3 –
5.4 Test procedures for the central computer (IEC 61559-1:2009, 5.4). 22
5.5 Test procedures for effects of power supply and environmental variations
(IEC 61559-1:2009, 5.5) . 22
5.6 Test procedures for data communications . 22
5.7 System validation . 22
5.8 System installation and commissioning testing . 23
5.9 System qualification . 23
6 Documentation . 23
6.1 General . 23
6.2 Report on type testing (IEC 61559-1:2009, 6.1) . 23
6.3 Certification (IEC 61559-1:2009, 6.2) . 23
6.4 Operating and maintenance manual (IEC 61559-1:2009, 6.3) . 24
6.5 Additional documentation . 24
Annex A (informative) Cross-references for centralized system for radiation
monitoring standards . 25
Bibliography . 28
Figure 1 – Example of a typical centralized system configuration . 15
Table 1 – Overview of the standards covering the domain of radiation monitoring in
nuclear facilities . 7
Table 2 – Reference conditions and standard test conditions (unless otherwise
indicated by the supplier) . 24
Table A.1 – Cross-reference table for centralized system for radiation monitoring
standards . 25
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– 4 – IEC 61504:2017 IEC 2017
INTERNATIONAL ELECTROTECHNICAL COMMISSION
____________
NUCLEAR FACILITIES – INSTRUMENTATION AND CONTROL SYSTEMS
IMPORTANT TO SAFETY – CENTRALIZED SYSTEMS FOR CONTINUOUS
MONITORING OF RADIATION AND/OR LEVELS OF RADIOACTIVITY
FOREWORD
1) The International Electrotechnical Commission (IEC) is a worldwide organization for standardization comprising
all national electrotechnical committees (IEC National Committees). The object of IEC is to promote
international co-operation on all questions concerning standardization in the electrical and electronic fields. To
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8) Attention is drawn to the Normative references cited in this publication. Use of the referenced publications is
indispensable for the correct application of this publication.
9) Attention is drawn to the possibility that some of the elements of this IEC Publication may be the subject of
patent rights. IEC shall not be held responsible for identifying any or all such patent rights.
International Standard IEC 61504 has been prepared by subcommittee 45A: Instrumentation,
control and electrical systems of nuclear facilities, of IEC technical committee 45: Nuclear
instrumentation.
This second edition cancels and replaces the first edition of IEC 61504, published in 2000,
and the first edition of IEC 61559-2, published by subcommittee 45B in 2002, and constitutes
a technical revision.
This standard is to be read in conjunction with IEC 61559-1.
This edition includes the following significant technical changes with respect to the previous
edition:
a) It supplements IEC 61559-1 and integrates IEC 61559-2.
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IEC 61504:2017 IEC 2017 – 5 –
b) It describes integration of functions including equipment such as those covered by
IEC 60761-1, IEC 60761-2, IEC 60761-3, IEC 60761-4, IEC 60761-5, IEC 60768,
IEC 60861, IEC 60910, IEC 60951-1 IEC 60951-2, IEC 60951-3, IEC 60951-4,
IEC 60951-5, IEC 61031, IEC 61250, IEC 62302 and IEC 62303.
c) It establishes requirements for integration in centralized systems as defined by IEC 62705.
The text of this standard is based on the following documents:
FDIS Report on voting
45A/1135/FDIS 45A/1149/RVD
Full information on the voting for the approval of this International Standard can be found in
the report on voting indicated in the above table.
This document has been drafted in accordance with the ISO/IEC Directives, Part 2.
The committee has decided that the contents of this document will remain unchanged until the
stability date indicated on the IEC website under "http://webstore.iec.ch" in the data related to
the specific document. At this date, the document will be
• reconfirmed,
• withdrawn,
• replaced by a revised edition, or
• amended.
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– 6 – IEC 61504:2017 IEC 2017
INTRODUCTION
a) Technical background, main issues and organisation of the standard
Advances in distributed system technology have led to the introduction of centralized
programmable digital systems for radiation monitoring into nuclear facilities.
IEC 61559 was introduced in 1996 to address centralized systems for radiation monitoring
in non-reactor nuclear facilities. That standard primarily focused upon category C
functions, such as area monitoring and excluded nuclear power plant applications. As
IEC 61559 was being released, subcommittee 45A determined that it would be useful to
develop a similar standard to address nuclear power plant application of plant-wide
radiation monitoring systems, at that time. The intent was that IEC 61504 would parallel
IEC 61559 would integrate or directly reference the other nuclear power standards that are
relevant to plant-wide radiation monitoring. IEC 61504 was published on 2000-05.
As IEC 61559 was in the final release process, subcommittee 45B recognized the need to
broaden the scope of that standard to include other applications of centralized radiation
monitoring in nuclear facilities. These broader applications included, for example,
monitoring of plant discharges, interlock of control functions, and environmental
monitoring. IEC 61559-2 was developed to cover these broader functions, including
category B functions, in non-reactor nuclear facilities and was published on 2002-06.
In 2004, the scope of subcommittee 45A standards was extended from “Reactor
instrumentation” to “Instrumentation and control system of nuclear facilities”.
This Standard reflects this increased scope of application and merges the extant
requirements of IEC 61504 with those in IEC 61559-2. Hence this Standard comes to
cover not only nuclear power plants but also nuclear facilities other than nuclear power
plants.
b) Situation of the current Standard in the structure of the IEC SC 45A standard series
IEC 61504 is the third level in the hierarchy of SC 45A standards. This standard provides
centralized systems for radiation monitoring for nuclear facilities. This standard is
applicable to the centralized systems for radiation monitoring to be used for functions
important to safety in nuclear facilities.
IEC 62705 provides the guidance for the radiation monitoring system (RMS) on the
application of existing IEC/ISO standards covering design and qualification of system and
equipment for RMS. IEC 62705 is the supplements of IEC 61513 and it is not intended that
IEC 62705 limits the application of other IEC 61513 requirements to RMS lifecycle.
IEC 61513 is the first level standard of SC 45A standards, and provides general
requirements for I&C systems and equipment that are used to perform functions important
to safety in NPPs. IEC 61226 provides the criteria for classification of instrumentation and
control functions. Most modern RMSs contain programmable digital equipment. Hence
RMS should often be treated as programmable digital system. So the following standards
required for programmable digital system are generally applicable to RMS. IEC 60880
provides the software requirements for category A functions and IEC 62138 provides the
software requirements for Category B or C functions. IEC 60987 provides hardware design
requirements for programmable digital systems. IEC 62566 provides the requirements for
HDL-Programmed Device (HPD) for systems performing category A functions. For the
qualification testing, the following SC 45A standards are applicable. IEC/IEEE 60780-323
provides the guide for the environmental qualification and IEC 60980 provides the
guidance for seismic qualification for equipment performing category A or B
functions.IEC 62003 provides the requirements for electromagnetic compatibility testing. In
addition, IEC 61250 specifies the leak detection requirements by using RMS.
For radiation monitoring specific requirements, the following standards provide
requirements and guidance for RMS. The IEC 60951 series provides guidance on the
design and testing of radiation monitoring equipment used for accident and post-accident
conditions. The IEC 60761 series provide requirements for equipment for continuous off-
line monitoring of radioactivity in gaseous effluent in normal conditions. Some of the
SC 45B standards (e.g. Gas offline: IEC 62302, Tritium: IEC 62303) are now replacing the
IEC 60761 series. IEC 60861 provides requirements for equipment continuous off-line
monitoring of radioactivity in liquid effluent in normal conditions. IEC 60768 provides
---------------------- Page: 8 ----------------------
IEC 61504:2017 IEC 2017 – 7 –
requirements for equipment for continuous in-line and on-line monitoring of radioactivity in
process stream in normal and incident conditions. IEC 61031 provides requirements for
equipment for area radiation monitor in normal conditions in conjunction with IEC 60532.
IEC 61504 provides requirements for centralized system for plant-wide radiation
monitoring in conjunction with the IEC 61559 series which specifies the requirements for
centralized system. If the centralized system is a part of the safety parameter display
system, IEC 60960 provides the functional design criteria. ISO 2889 gives guidance on
gas and particulate sampling. The ISO 4037 series provides calibration methodology for
radiation monitors.
The relationship among these various standards is given in Table 1.
Table 1 – Overview of the standards covering
the domain of radiation monitoring in nuclear facilities
IEC
Developer ISO
SC 45A SC 45B
Accident and
Scope Sampling Calibration post accident Normal conditions
conditions
IEC 62302 /
Radioactive noble gas
ISO 4037-1, IEC 60951-1,
ISO 2889 N/A IEC 60761-1,
off-line monitoring ISO 4037-3 IEC 60951-2
IEC 60761-3
Radioactive aerosol off- ISO 4037-1, IEC 60951-1, IEC 60761-1,
ISO 2889 N/A
line monitoring ISO 4037-3 IEC 60951-2 IEC 60761-2
Radioactive iodine off- ISO 4037-1, IEC 60951-1, IEC 60761-1,
ISO 2889 N/A
line monitoring ISO 4037-3 IEC 60951-2 IEC 60761-4
Liquid off-line monitoring N/A N/A N/A N/A IEC 60861
IEC 62303 /
Tritium off-line
N/A N/A N/A N/A IEC 60761-1,
monitoring
IEC 60761-5
On-line or in-line
ISO 4037-1, IEC 60951-1,
N/A IEC 60768 N/A
monitoring ISO 4037-3 IEC 60951-4
ISO 4037-1, IEC 60951-1,
Area monitoring N/A IEC 61031 IEC 60532
ISO 4037-3 IEC 60951-3
Centralized system N/A N/A IEC 61504, IEC 60960 IEC 61559-1
IEC 61513, IEC 60880,
IEC 60987, IEC 61226,
Classification/basic
N/A N/A IEC 62138, IEC 62566, N/A
requirements
IEC 62645, IEC 61250,
IEC 61500, IEC 61504
IEC 60980, IEC 62003,
Qualification N/A N/A IEC 62706
IEC/IEEE 60780-323
For more details on the structure of the IEC SC 45A standard series, see item d) of this
introduction.
c) Recommendations and limitations regarding the application of this Standard
Where requirements are given in this standard, they refer generally to the need to apply
other IEC and ISO Standards and specific functional and technical requirements contained
in these Standards.
To ensure that the standard will continue to be relevant in future years, the emphasis has
been placed on issues of principle, rather than specific technologies.
d) Description of the structure of the IEC SC 45A standard series and relationships
with other IEC documents and other bodies documents (IAEA, ISO)
The top-level documents of the IEC SC 45A standard series are IEC 61513 and IEC 63046.
IEC 61513 provides general requirements for I&C systems and equipment that are used to
perform functions important to safety in NPPs. IEC 63046 provides general requirements
for electrical power systems of NPP; it covers power supply systems including the supply
---------------------- Page: 9 ----------------------
– 8 – IEC 61504:2017 IEC 2017
systems of the I&C systems. IEC 61513 and IEC 63046 are to be considered in
conjunction and at the same level. IEC 61513 and IEC 63046 structure the IEC SC 45A
standard series and shape a complete framework establishing general requirements for
instrumentation, control and electrical systems for nuclear power plants.
IEC 61513 and IEC 63046 refer directly to other IEC SC 45A standards for general topics
related to categorization of functions and classification of systems, qualification,
separation, defence against common cause failure, control room design, electromagnetic
compatibility, cybersecurity, software and hardware aspects for programmable digital
systems, coordination of safety and security requirements and management of ageing.
The standards referenced directly at this second level should be considered together with
IEC 61513 and IEC 63046 as a consistent document set.
At a third level, IEC SC 45A standards not directly referenced by IEC 61513 or by
IEC 63046 are standards related to specific equipment, technical methods, or specific
activities. Usually these documents, which make reference to second-level documents for
general topics, can be used on their own.
A fourth level extending the IEC SC 45A standard series, corresponds to the Technical
Reports which are not normative.
The IEC SC 45A standards series consistently implements and details the safety and
security principles and basic aspects provided in the relevant IAEA safety standards and
...
SLOVENSKI STANDARD
SIST IEC/TR 61000-5-2:1998
01-september-1998
Electromagnetic compatibility (EMC) - Part 5: Installation and mitigation guidelines
- Section 2: Earthing and cabling
Electromagnetic compatibility (EMC) - Part 5: Installation and mitigation guidelines -
Section 2: Earthing and cabling
Compatibilité électromagnétique (CEM) - Partie 5: Guides d'installation et d'atténuation -
Section 2: Mise à la terre et câblage
Ta slovenski standard je istoveten z: IEC/TR 61000-5-2
ICS:
33.100.99 Drugi vidiki v zvezi z EMC Other aspects related to
EMC
SIST IEC/TR 61000-5-2:1998 en
2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.
---------------------- Page: 1 ----------------------
SIST IEC/TR 61000-5-2:1998
---------------------- Page: 2 ----------------------
SIST IEC/TR 61000-5-2:1998
RAPPORT
CEI
TECHNIQUE – TYPE 3
IEC
61000-5-2
TECHNICAL
Première édition
REPORT – TYPE 3
First edition
1997-11
Compatibilité électromagnétique (CEM) –
Partie 5: Guides d’installation et d’atténuation –
Section 2: Mise à la terre et câblage
Electromagnetic compatibility (EMC) –
Part 5: Installation and mitigation guidelines –
Section 2: Earthing and cabling
IEC 1997 Droits de reproduction réservés Copyright - all rights reserved
Aucune partie de cette publication ne peut être reproduite ni No part of this publication may be reproduced or utilized in
utilisée sous quelque forme que ce soit et par aucun any form or by any means, electronic or mechanical,
procédé, électronique ou mécanique, y compris la photo- including photocopying and microfilm, without permission in
copie et les microfilms, sans l'accord écrit de l'éditeur. writing from the publisher.
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Telefax: +41 22 919 0300 e-mail: inmail@iec.ch IEC web site http: //www.iec.ch
CODE PRIX
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PRICE CODE
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Pour prix, voir catalogue en vigueur
For price, see current catalogue
---------------------- Page: 3 ----------------------
SIST IEC/TR 61000-5-2:1998
61000-5-2 © IEC:1997 – 3 –
CONTENTS
Page
FOREWORD . 9
INTRODUCTION . 13
Clause
1 Scope . 17
2 Reference documents . 17
3 Definitions. 17
4 General EMC considerations on installation of earthing and cabling systems . 23
4.1 General . 23
4.2 EMC and safety (insulation) installation requirements. 25
4.3 Equipment and installation ports . 25
5 Earthing and bonding . 25
5.1 Requirements concerning safety. 25
5.2 Requirements concerning EMC. 27
5.3 Design of the earthing system. 29
6 Bonding . 41
6.1 General . 41
6.2 Bonding straps . 43
6.3 Connections . 45
6.4 Bonding of specific equipment . 47
6.5 Procedures for users . 49
7 Cables and wires . 51
7.1 General . 51
7.2 Differential and common mode circuit, transfer impedance Z . 53
t
7.3 Set of EMC rules for cable and wire installation. 57
7.4 Types of cables and their use with regard to EMC. 61
7.5 Types of parallel-earthing conductor (PEC) . 63
7.6 Connecting and earthing of cables and parallel earthed conductors. 69
7.7 General routing of cables. 71
7.8 Cable bundles . 77
7.9 Cables serving power ports. 79
7.10 Cables serving signal and control ports. 81
8 Additional interference mitigation methods . 87
8.1 Common-mode ferrite choke. 87
8.2 Electrical separation . 89
9 Measuring and testing methods. 93
9.1 Earthing and bonding. 93
9.2 Cables and installation. 95
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Page
Figures
1 Demonstration of the fallacy of the “equipotentiality” concept as a universal rule . 27
2 Schematic plan view of a typical earth electrode . 31
3 Misconception of “dedicated”, “independent”, or “isolated” earth electrodes . 31
4 The concept of a single earth electrode . 33
5 Recommended configuration for the earth electrodes and earthing network . 33
6 Loops involving signal cables and earthing network . 35
7 A three-dimensional schematic of the recommended approach
for the earthing network . 37
8 General principles for bonding of various apparatus or systems
to the earthing network. 39
9 Simplified representation of a bonding strap . 41
10 A more realistic representation of an installed bonding strap. 43
11 Typical bonding straps . 45
12 Relative inductance of flat and round conductors . 45
13 Relative inductance of round, flat and double bonding straps . 45
14 Example of protected removable connection of a bonding strap . 47
15 Example of optimal bonding of a shielded cable to the enclosure . 49
16 Schematic of interconnected chassis. 49
17 Differential mode and common mode circuits with bonding strips and signal cables . 53
18 Effect of the configuration of a parallel-earthing conductor
on the transfer impedance. 63
19 Slits in conduits and cable trays . 65
20 Recommended configuration for cable trays with branches . 67
21 Recommended cable positions parallel to an H-shaped beam
from the EMC point of view . 67
22 Penetration of a shielded cable through an enclosure wall . 69
23 Tray with partition. 75
24 Example of stacking for conduits or trays . 75
25 Topology of circuits containing switches . 81
26 Undesirable connection of a coaxial cable . 85
27 Typical implementations of common-mode ferrite chokes . 87
28 Limitations in the effectiveness of an isolation transformer . 91
29 Parasitic coupling at high frequencies. 93
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Annexes
A – Examples of earthing systems and cable implementation . 97
B – Applying cable theory to enhance EMC . 109
C – Benefits of additional conductors parallel to a cable. 125
D – Bibliography . 1 35
Annex figures
A.1 – Example of topology for a hybrid earthing system. 99
A.2 – EMC cabinet for the protection of sensitive electronics. 101
A.3 – Earthing system for a drive with converter and associated electronics . 103
A.4 – Earthing configuration for a power supply system with associated electronics . 103
A.5 – Initial arrangement of the power and control cables. 105
A.6 – Improved design with appropriate shield connections . 107
B.1 – Unbalanced transport of signals. 109
B.2 – Behaviour of Z' as function of frequency for several coaxial cable configurations . 111
t
B.3 – Unbalanced transmission system connected to earth at one end . 113
B.4 – Balanced transmission system . 113
B.5 – Current paths in a coaxial cable . 115
B.6 – Differential-mode voltage induced by a magnetic field in a cable
with braided shield . 117
B.7 – Currents in the outer conductor of a coaxial cable . 119
B.8 – A two-lead cable perturbed by a nearby lead at the voltage U . 123
ext
C.1 – Coaxial cables with parallel-earthing conductors . 125
C.2 – A coaxial cable with two outer conductors . 127
C.3 – Transfer impedances in a shielded balanced pair . 129
C.4 – Example of transfer impedance for an aluminum conduit as a function of frequency 131
C.5 – Mutual inductance and magnetic field for a conduit or cable tray . 131
C.6 – Insulated covers over a conduit . 133
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INTERNATIONAL ELECTROTECHNICAL COMMISSION
_________
ELECTROMAGNETIC COMPATIBILITY (EMC) –
Part 5: Installation and mitigation guidelines –
Section 2: Earthing and cabling
FOREWORD
1) The IEC (International Electrotechnical Commission) is a worldwide organization for standardization comprising
all national electrotechnical committees (IEC National Committees). The object of the IEC is to promote
international co-operation on all questions concerning standardization in the electrical and electronic fields. To
this end and in addition to other activities, the IEC publishes International Standards. Their preparation is
entrusted to technical committees; any IEC National Committee interested in the subject dealt with may
participate in this preparatory work. International, governmental and non-governmental organizations liaising
with the IEC also participate in this preparation. The IEC collaborates closely with the International Organization
for Standardization (ISO) in accordance with conditions determined by agreement between the two
organizations.
2) The formal decisions or agreements of the IEC on technical matters express, as nearly as possible, an
international consensus of opinion on the relevant subjects since each technical committee has representation
from all interested National Committees.
3) The documents produced have the form of recommendations for international use and are published in the form
of standards, technical reports or guides and they are accepted by the National Committees in that sense.
4) In order to promote international unification, IEC National Committees undertake to apply IEC International
Standards transparently to the maximum extent possible in their national and regional standards. Any
divergence between the IEC Standard and the corresponding national or regional standard shall be clearly
indicated in the latter.
5) The IEC provides no marking procedure to indicate its approval and cannot be rendered responsible for any
equipment declared to be in conformity with one of its standards.
6) Attention is drawn to the possibility that some of the elements of this International Standard may be the subject
of patent rights. The IEC shall not be held responsible for identifying any or all such patent rights.
The main task of IEC technical committees is to prepare International Standards. In
exceptional circumstances, a technical committee may propose the publication of a technical
report of one of the following types:
• type 1, when the required support cannot be obtained for the publication of an
International Standard, despite repeated efforts;
• type 2, when the subject is still under technical development or where for any other
reason there is the future but no immediate possibility of an agreement on an International
Standard;
• type 3, when a technical committee has collected data of a different kind from that
which is normally published as an International Standard, for example "state of the art".
Technical reports of types 1 and 2 are subject to review within three years of publication to
decide whether they can be transformed into International Standards. Technical reports of
type 3 do not necessarily have to be reviewed until the data they provide are considered to be
no longer valid or useful.
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IEC 61000-5-2, which is a technical report of type 3, has been prepared by subcommittee 77B:
High frequency phenomena, of IEC technical committee 77: Electromagnetic compatibility.
The text of this technical report is based on the following documents:
Committee draft Report on voting
77B/168/CDV 77B/183/RVC
Full information on the voting for the approval of this technical report can be found in the report
on voting indicated in the above table.
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INTRODUCTION
IEC 61000-5 is part of the IEC 61000 series, according to the following structure:
Part 1: General
General considerations (introduction, fundamental principles)
Definitions, terminology
Part 2: Environment
Description of the environment
Classification of the environment
Compatibility levels
Part 3: Limits
Emission limits
Immunity limits (insofar as they do not fall under the responsibility of the product
committees)
Part 4: Testing and measurement techniques
Measurement techniques
Testing techniques
Part 5: Installation and mitigation guidelines
Installation guidelines
Mitigation methods and devices
Part 6: Generic standards
Part 9: Miscellaneous
Each part is further subdivided into sections which are published either as international
standards or as technical reports.
These sections of IEC 61000-5 will be published in chronological order and numbered
accordingly.
The recommendations presented in this technical report address the EMC concerns of the
installation, not the safety aspects of the installation nor the efficient transportation of power
within the installation. Nevertheless, these two prime objectives are taken into consideration in
the recommendations concerning EMC. These two primary objectives can be implemented
concurrently for enhanced EMC of the installed sensitive apparatus or systems without conflict
by applying the recommended practices presented in this technical report and the relevant
safety requirements such as those of IEC 60364. As each installation is unique, it is the
responsibility of the designer to select the relevant recommendations most appropriate to a
particular installation, with corresponding implementation by the installer.
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It is important to note that the recommendations presented in this technical report do
not seek to preclude existing installation practices, when they have been shown to
perform satisfactorily. Special mitigation methods might not be necessary when the
equipment satisfy applicable emissions and immunity standards. In particular, some
installation practices such as a "Star Network" or "Isolated Bonding Network" for earthing are
based on different approaches to EMC that have been found satisfactory for specific
installations when correctly applied and the topology maintained by competent specialists.
Nevertheless, the approach recommended here is more generally applicable to all types of
facilities, especially when signals are exchanged between different apparatus.
Clauses 1-3 provide the usual general information of the IEC 61000 documents on EMC.
Clause 4 provides an overview and introduction of the general approach to applying EMC
concepts in the design of installations.
Clause 5 provides recommendations on the design and implementation of the earthing system,
including the earth electrode and the earthing network.
Clause 6 provides basic information on the design and implementation of bonding for
apparatus or systems to earth or to the earthing network.
Clause 7 provides recommendations on the selection, erection, and connection practices for
cables used for low-voltage a.c. and d.c. power supply, for input and output signals serving
control and command, as well as those used for other communications within the premises.
Clause 8 provides information on related mitigation techniques.
Clause 9 provides information on verification and test methods.
Informative annexes provide information on the supporting concepts, including bibliographic
citations, from which the recommendations of this technical report have been drawn.
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ELECTROMAGNETIC COMPATIBILITY (EMC) –
Part 5: Installation and mitigation guidelines –
Section 2: Earthing and cabling
1 Scope
This technical report (type 3) covers guidelines for the earthing and cabling of electrical and
electronic systems and installations aimed at ensuring electromagnetic compatibility (EMC)
among electrical and electronic apparatus or systems. More particularly, it is concerned with
earthing practices and with cables used in industrial, commercial, and residential installations.
This technical report is intended for use by installers and users, and to some extent,
manufacturers of sensitive electrical or electronic installations and systems, and equipment
with high emission levels that could degrade the overall electromagnetic (EM) environment. It
applies primarily to new installations, but where economically feasible, it may be applied to
extensions or modifications to existing facilities.
2 Reference documents
IEC 60050(161):1990, International Electrotechnical Vocabulary (IEV) – Chapter 161:
Electromagnetic compatibility
IEC 60050(826):1982, International Electrotechnical Vocabulary (IEV) – Chapter 826: Electrical
installations of buildings
Amendment 1: 1990
Amendment 2: 1995
IEC 61000-2-5:1995, Electromagnetic compatibility (EMC) – Part 2: Environment – Section 5:
Classification of electromagnetic environments – Basic EMC publication
IEC 61000-5-1:1996, Electromagnetic compatibility (EMC) – Part 5: Installation and mitigation
guidelines – Section 1: General considerations – Basic EMC publication
IEC 61024-1:1990, Protection of structures against lightning – Part 1: General principles
ISO/IEC 11801:1995, Information technology – Generic cabling for customer premises
Note that other documents are listed in the Bibliography in informative annex D. This
bibliographic listing includes documents that were used in developing the present report,
documents cited in support of a recommendation, and documents suggested as further reading
for complementary information.
3 Definitions
For the purposes of this technical report, the definitions given in IEC 60050(161) and
IEC 60050(826) apply, as well as the definitions listed below.
A list of acronyms is provided at the end of this clause.
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3.1
bonding
the act of connecting together exposed conductive parts and extraneous conductive parts of
apparatus, systems, or installations that are at essentially the same potential [new WG2]
NOTE – For safety purposes, bonding generally involves (but not necessarily) a connection to the immediately
adjacent earthing system.
3.2
common mode voltage
the mean of the phasor voltages appearing between each conductor and a specified reference,
usually earth or frame [IEV 161-04-09]
3.3
common mode conversion
the process by which a differential mode voltage is produced in response to a common mode
voltage [IEV 161-04-10]
3.4
common mode circuit
the full current loop or closed circuit for the CM current, including the cable, the apparatus, and
the nearby parts of the earthing system [new WG2]
3.5
differential mode voltage
the voltage between any two of a specified set of active conductors [IEV 161-04-08]
3.6
differential mode circuit
the full current loop or closed circuit for the intended signal or power, including a cable and the
apparatus connected to it at both ends [new WG2]
NOTE – Instead of “differential mode”, the terms “normal mode” and “serial mode” are sometimes used.
3.7
(electromagnetic) disturbance level
the level of an electromagnetic disturbance existing at a given location, which results from all
contributing disturbance sources [IEV 161-03-29]
3.8
equipotential bonding
electrical connection putting various exposed conductive parts and extraneous conductive parts
at a substantially equal potential [IEV 826-04-09]
3.9
earth; ground (USA)
the conductive mass of the earth, whose electric potential at any point is conventionally taken
as equal to zero [IEV 826-04-01]
3.10
earth electrode
a conductive part or a group of conductive parts in intimate contact with and providing an
electrical connection with earth [IEV 826-04-02]
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3.11
earthing network
conductors of the earthing system, not in contact with the soil, connecting apparatus, systems,
or installations to the earth electrode or to other means of earthing [new WG2]
3.12
earthing
the act of connecting exposed conductive parts of apparatus, systems or installations to the
earth electrode or other elements of the earthing system [new WG2]
3.13
earthing system
the three-dimensional electrical circuit which performs the earthing [new WG2]
NOTE – The earthing system includes two parts: the earth electrode and the earthing network.
3.14
electrically independent earth electrodes
earth electrodes located at such a distance from one another that the maximum current likely
to traverse one of them does not significantly affect the potential of the others [IEV 826-04-04]
3.15
(electromagnetic) compatibility level
the specified electromagnetic disturbance level used as a reference level for co-ordination in
the setting of emission and immunity limits [IEV 161-03-10]
3.16
facility
something (as a hospital, factory, machinery.) that is built, constructed, installed or
established to perform some particular function or to serve or facilitate some particular end
[new WG2]
3.17
immunity margin
the ratio of the immunity limit to the electromagnetic compatibility level [IEV 161-03-16]
3.18
immunity level
the maximum level of a given electromagnetic disturbance, incident in a specified way on a
particular device, equipment or system, at which no degradation of operation occurs
[IEV 161-03-14]
3.19
parallel-earthing conductor (PEC)
a conductor usually laid along the cable route to provide a low-impedance connection between
the earthing arrangements at the ends of the cable route [new WG2]
3.20
port
specific interface of the specified apparatus with the external electromagnetic environment
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3.21
surface transfer impedance (of a coaxial line)
the quotient of the voltage induced in the centre conductor of a coaxial line per unit length by
the current on the external surface of the coaxial line [IEV 161-04-15]
3.22
transfer impedance (Z )
t
the ratio of the voltage coupled into one circuit to the current appearing in another circuit or
another part of the same circuit [New WG2]
NOTE 1 – For the purposes of this technical report, the separate circuits may be physically separated but closely
spaced cables, or the same cables operating in different modes.
NOTE 2 – Different localized contributions stem from the cable proper and from the apparatus.
3.23
acronyms
a.c. alternating current HF high frequency
CM common mode IM intermediate mode
d.c. direct current LF low frequency
DM differential mode PE protective earth
EM electromagnetic PEC parallel-earthing conductor
EMC electromagnetic compatibility
4 General EMC considerations on installation of earthing and cabling systems
4.1 General
Different types of standards are available to define conditions for compliance with EMC
requirements for electrical and electronic products, ranging from basic standards to dedicated
product standards. However, these standards might not be sufficient, or appropriate, when
EMC for sensitive installations is concerned. Therefore, installation guidelines are necessary to
adapt to a maximum of situations. Mitigation methods might not be necessary when the
equipment themselves have sufficiently high immunity levels.
Three main areas can be considered with regard to EMC:
– emitters: the source of the disturbances, influenced by the apparatus design;
– coupling paths: influenced by installation practices;
– susceptors: the potential victims, influenced by the apparatus design.
In order to assure EMC, three types of steps should be applied as necessary:
– at the source of disturbances: reduction of emissions;
– at the coupling: reduction of coupling;
– at the victim: increase of immunity.
This technical report addresses principally the mitigation achievable by reduction of the
coupling through appropriate practices on the implementation of earthing and bonding, and the
selection and installation of the various cables used in the facility.
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4.2 EMC and safety (insulation) installation requirements
Attention is drawn to the fact that EMC protection and insulation/safety requirements can have
common aspects, such as earthing and protection against overvoltages and lightning. It is
important to bear in mind that the safety aspects procedures for personnel protection take
precedence over EMC protection procedures. In some cases, there might be an alleged conflict
between safety-related procedures and EMC-related procedures. Safety must always prevail,
so that in such cases alternate EMC-related measures must be sought.
4.3 Equipment and installation ports
To provide a transition from the overall concept of coupling between e
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