International standards play an important role in global trading. For electricity metering, they are developed by IEC Technical Committee 13: Equipment for electrical energy measurement, tariff and load control. They are used by manufacturers, utilities, metering service providers, regulators and legal metrology bodies.

The scope of TC 13 covers all metering equipment for any applications. At present, more than 30 standards and technical reports are available. These are used as they stand, or are adapted by many regions and countries worldwide. To complete the picture, it is to be noted that in some parts of the world standards developed by ANSI are used, sometimes as alternatives to IEC standards (see Smart Energy International 2/2003).

TC 13 standards cover the most important aspects of metering and provide a sound basis for specifications, type approvals and acceptance testing. As infrastructures and installation conditions may vary from country to country, some mechanical aspects – such as meter size and connection arrangements – are left to national standards. To allow competition and innovation, functional requirements are generally not standardised. The standards have recently been rearranged in the IEC 6205X series, to facilitate their use and maintenance; all revised and new publications are published as part of this series.

WG 11 Standards

 

TYPE TEST AND ACCEPTANCE TEST – WG 11

WG 11 is responsible for establishing standards for type test and acceptance test for all kind of metering equipment.

IEC 62052-11 specifies general requirements and tests common to all meter types. It covers mechanical, climatic, electrical, and EMC aspects, to ensure that meters are suitable for the application, robust and safe. It replaces the general requirements and tests of earlier standards with a new, harmonised set. To meet new needs, EMC requirements have been made more severe. IEC 62052-21 specifies general requirements for tariff- and load-control equipment. IEC 62053-11, 3-21, 3-22, and 3-23 replace the earlier IEC 60521 / 60687 / 61036 / 61268 standards. They contain particular requirements and tests for the metrology, specifying error limits under reference conditions and the permissible effect of disturbances and influence quantities. They are to be used with part 2-11. Part 3-31 specifies the pulse interface for telemetering, part 3-52 defines graphical symbols for use on metering equipment, and part 3-61 specifies power consumption and voltage requirements for multienergy and multi-function meters.

IEC 62054-11 and 4-21, replacing IEC 61037 and 61038, specify particular requirements for ripple control receivers and time switches respectively. They are to be used with part 2-21.

IEC 60514 and 61358, covering acceptance testing procedures, are under revision. The new IEC 62058 series will take into account recent developments in quality assurance.

DEPENDABILITY – WG 13

Dependability is an important aspect for metering equipment, which is used for long periods without supervision and maintenance. Part 9-11 covers general principles of dependability, and part 9-21 provides a method for collecting dependability data from the field. A standard on reliability prediction, part 9-41, based on the parts stress method, will be published soon. The first draft of part 9-31, accelerated reliability testing, has been circulated recently. These standards should provide a solid basis for dependability specifications and field performance monitoring.

DATA EXCHANGE FOR METER READING, TARIFF AND LOAD CONTROL – WG 14

The main activity of WG 14 is to specify standards for data exchange for various communication media. It also took on the responsibility of compiling a glossary of terms. IEC 62051 covers the whole scope of TC 13. Part 51-1 covers terms related to the DLMS / COSEM specification (see later).

IEC 62056-21, replacing IEC 61107, covers local data exchange, adding a new mode for data exchange based on DLMS /COSEM.

Part 6-31 specifies a protocol stack for local area networks on twisted pair with carrier signalling. It is mainly used for reading of residential meters, and can be used with or without the Application+ layer protocol specified in part 6-51. Part 6-52 specifies the DLMS server, based on IEC 61334-4-41, established by IEC TC 57. Part 6-41 specifies the physical and data link layer protocols for meter data exchange over PSTN, mainly used for remote reading of high-end meters. It is to be used with the Application+ layer specified in part 6-51. These standards, based on the ISO/OSI layered protocol model, represent a significant move towards interoperability.

The real breakthrough, however, is brought by the DLMS/COSEM specification, defining an interface object model and communication protocols to carry the data.

COSEM OBJECT MODEL

The COSEM object model provides a view of the functionality of the meter as seen through its interfaces. The interface objects, like registers, profiles, clocks, schedules and associations, are specified in part 6–62. They are identified by the OBIS object identification system specified in part 6-61. The same identifiers are also used on the display. The object model allows the development of tailor-made meters to meet the needs from the simplest to the most complex applications, using standard elements.

The link between the model and the communication protocols is the xDLMS application service element of the COSEM application layer, specified in part 6-53. xDLMS provides services to access the attributes and methods of the objects in a manufacturer- and communication-media-independent way. It is an extended version of the DLMS ASE specified in IEC 61334-41. The application layer is supported by mediaspecific lower layers, based on widely accepted international standards specified in parts 6-47, 6-46 and 6-42 and Internet RFCs.

INTEROPERABILITY

Interoperability of implementation is testable using the Conformance Test Tool developed by the DLMS User Association – a liaison partner of WG14 – also acting as a Registration Authority and providing maintenance services.

DLMS/COSEM has proven to be a flexible and efficient solution for meter data exchange, which is reflected in the fast growth in the number of its users. It has also been taken over by CEN for the purposes of utility meters other than electricity.

WG 14 Standards

PREPAYMENT METERING SYSTEMS – WG 15

WG 15 works closely with the STS Association, located in South Africa. The first publication, IEC/PAS 62055-41, contains the Standard Transfer Specification (STS) for prepayment tokens. Part 5-21 provides a framework for specifying standards for prepayment systems. Using this framework, IEC/PAS 62055-41 is being transformed to full IEC standards, specifying an application and a physical layer protocol for transporting prepayment tokens. A new work item will cover virtual tokens. Part 5-31 specifies type tests for prepayment meters, based on parts 2-11 and 3-21.

GLOBAL PARTICIPATION TO CARVE OUT THE FUTURE

At present, TC 13 has 30 participating members and 11 observing members, involving national committees from all continents. They will meet on 18th October 2005 in Cape Town, South Africa, to review progress and to discuss current and future projects to ensure that the needs of the users of its standards are continually met in the new environment created by market liberalisation.

3 COMMENTS

  1. I’m don’t understand in IEC 62053-11 table 1 and table 2 (Power consumption). Why they a table 1 have watt and VA but table 2 VA only ?, And what it mean 3 watt and 12 VA in table 1 ? Please.
    Thank you

  2. g : IEC standard 62053-21 for energy meters Dear sir, Meters to this standard are used for measuring energy in 25 kv traction. I have carried out a research which show that the energy recorded by this meter in traction application has an error of 15%. I can share the details if you are interested. S P Khade