Inactive-Reserved Standard

IEEE 367-2012

IEEE Recommended Practice for Determining the Electric Power Station Ground Potential Rise and Induced Voltage from a Power Fault

Guidance for the calculation of power station ground potential rise (GPR) and longitudinal induction (LI) voltages is provided, as well as guidance for their appropriate reduction from worst-case values, for use in metallic telecommunication protection design.

Sponsor Committee
PE/PSCC - Power System Communications and Cybersecurity
Learn More About PE/PSCC - Power System Communications and Cybersecurity
Status
Inactive-Reserved Standard
PAR Approval
2007-09-27
Superseding
367-1996
Board Approval
2012-03-29
History
Published:
2012-05-21
Inactivated Date:
2023-03-30

Working Group Details

Society
IEEE Power and Energy Society
Learn More About IEEE Power and Energy Society
Sponsor Committee
PE/PSCC - Power System Communications and Cybersecurity
Learn More About PE/PSCC - Power System Communications and Cybersecurity
Working Group
SC6-WG - Wireline Working Group
IEEE Program Manager
Tom Thompson
Contact Tom Thompson
Working Group Chair
John Fuller

Other Activities From This Working Group

Current projects that have been authorized by the IEEE SA Standards Board to develop a standard.


P367
Recommended Practice for Determining the Electric Power Station Ground Potential Rise and Induced Voltage from a Power Fault

This standard provides guidance for the calculation of power station ground potential rise (GPR) and longitudinally induced (LI) voltages and guidance for their appropriate reduction from worst-case values for use in metallic telecommunication protection design. Information is also included for the determination of the following: a) The fault current and the earth return current levels; their probability, waveform, and duration; and the impedance to remote earthing points used in these GPR and LI calculations as well as the effective X/R ratio. b) The zone of influence (ZOI) of the power station GPR. c) The calculation of the inducing currents, the mutual impedance between power and metallic telecommunication facilities, and shield factors. d) The channel time requirements for metallic telecommunication facilities where non-interruptible channels are required for protective relaying.

Learn More About P367

P487a
Standard for the Electrical Protection of Communications Facilities Serving Electric Supply Locations -- General Considerations Amendment: New Annex J- Guidance for Determining the Ground Potential Rise and Induced Voltages for the Design of Communications Installations at Electric Supply Locations

This informative annex provides applications and examples for the calculations of electric supply location power ground potential rise (GPR) and longitudinal induction (LI) voltages at electric supply locations.

Learn More About P487a

Standards approved by the IEEE SA Standards Board that are within the 10-year lifecycle.


1137-2018
IEEE Recommended Practice for the Implementation of Inductive Coordination Mitigation Techniques and Application

Guidance for controlling or modifying the inductive environment and the susceptibility of affected wire line telecommunications facilities in order to operate within the acceptable levels of steady-state or surge induced voltages of the environmental interface (probe wire) defined by IEEE Std 776(TM) is provided in this Recommended Practice. Procedures for determining the source of the problem are given. Mitigation theory and philosophy are discussed, and mitigation devices are described. The application of typical mitigation apparatus are addressed. Advice for determining the best engineering solution is offered, and general safety considerations are discussed.

Learn More About 1137-2018

487-2015
IEEE Standard for the Electrical Protection of Communications Facilities Serving Electric Supply Locations -- General Considerations

General considerations are presented for the electrical protection of telecommunications facilities serving electric supply locations. This standard contains material that is common to the IEEE 487(TM) family of standards (i.e., dot-series) including fundamental protection theory; basic electrical protection philosophy, concepts, and designs; protection apparatus; service types; reliability; service performance objective (SPO) classifications; and transmission considerations. In general, special protective measures, handling procedures, and administrative procedures are necessary to provide electrical protection against damage to telecommunications facilities and equipment, maintain reliability of service, and ensure the safety of personnel.

Learn More About 487-2015

487.1-2014
IEEE Standard for the Electrical Protection of Communication Facilities Serving Electric Supply Locations Through the Use of On-Grid Isolation Equipment

Workable methods for protecting wire-line telecommunication circuits entering electric supply locations are presented. The electric supply location environment; protection apparatus; service types, reliability, service performance objective classifications, and transmission considerations; protection theory and philosophy; protection configurations; installation and inspection; and safety are covered in this document.

Learn More About 487.1-2014

776-2018
IEEE Recommended Practice for Inductive Coordination of Electric Supply and Communication Lines

The inductive environment that exists in the vicinity of electric power and wire-line telecommunications systems and the interfering effects that may be produced are addressed. An interface that permits either party, without need to involve the other, to verify the induction at the interface by use of a probe wire is presented. This recommended practice does not apply to railway signal circuits.

Learn More About 776-2018

820-2021
IEEE Standard Telephone Loop Performance Characteristics

Common denominators for subscriber line performance, independent of facility types, construction processes or equipment, and circuit provisioning methods are provided in this standard.

Learn More About 820-2021

These standards have been replaced with a revised version of the standard, or by a compilation of the original active standard and all its existing amendments, corrigenda, and errata.


1137-1991
IEEE Guide for the Implementation of Inductive Coordination Mitigation Techniques and Application

Provides guidance for controlling or modifying the inductive environment and the susceptibility of affected wire line telecommunications facilities in order to operate within the acceptable levels of steady-state or surge induced voltages of the environmental interface (probe wire) defined by IEEE Std 776-1987. Procedures for determining the source of the problem are given. Mitigation theory and philosophy are discussed, and mitigation devices are described. The application of typical mitigation apparatus and techniques and installation, maintenance, and inspection of mitigation apparatus are addressed. Advice for determining the best engineering solution is offered, and general safety considerations are discussed.

Learn More About 1137-1991

1137-1991/Cor 1-2009
IEEE Guide for the Implementation of Inductive Coordination Mitigation Techniques and Applications--Corrigendum 1

IEEE Std 1137-1991 provides guidance for controlling or modifying the inductive environment and the susceptibility of affected wire line telecommunications facilities in order to operate within the acceptable levels of steady-state or surge induced voltages of the environmental interface (probe wire) defined by IEEE Std 776-1987. Procedures for determining the source of the problem are given. Mitigation theory and philosophy are discussed, and mitigation devices are described. The application of typical mitigation apparatus is addressed. Advice for determining the best engineering solution is offered, and general safety considerations are discussed. This corrigendum corrects Table 3–Longitudinal Balance Performance Thresholds and the first and last sentences of the third paragraph in 8.5 of IEEE Std 1137-1991.

Learn More About 1137-1991/Cor 1-2009

1590-2003
IEEE Recommended Practice for the Electrical Protection of Optical Fiber Communication Facilities Serving, or Connected to, Electrical Supply Locations

This Recommended Practice presents engineering design procedures for the electrical protection of optical fiber communication facilities serving, or connected to, electric supply locations. Other telecommunication alternatives, such as radio and cable with metallic members are excluded from this document. Project purpose: This Recommended Practice presents safe and reliable methods for providing telecommunication facilities serving electrical supply locations using optical fiber.

Learn More About 1590-2003

1590-2009
IEEE Recommended Practice for the Electrical Protection of Communication Facilities Serving Electric Supply Locations Using Optical Fiber Systems

The main emphasis of this recommended practice is the engineering design of optical fiber communication facilities serving, or connected to, electric supply locations. This document includes methods for providing telecommunication facilities serving electric supply locations using optical fiber cables, and their related electronic systems, extending across the zone of influence (ZOI). (IEEE Std 1590-2009 in its entirety, was replaced by IEEE Std 487.2 and IEEE Std 487.3.)

Learn More About 1590-2009

367-1996
IEEE Recommended Practice for Determining the Electric Power Station Ground Potential Rise and Induced Voltage from a Power Fault

Guidance for the calculation of power station ground potential rise (GPR) and longitudinal induction (LI) voltages is provided, as well as guidance for their appropriate reduction from worst-case values, for use in metallic telecommunication protection design.

Learn More About 367-1996

487-2000
IEEE Recommended Practice for the Protection of Wire-Line Communication Facilities Serving Electric Supply Locations

Workable methods for protecting wire-line communication circuits entering electric supply locations are presented. This document covers: the electric supply location environment; protection apparatus; services types, reliability, service performance objective classifications, and transmission considerations; protection theory and philosophy; protection configurations; installation and inspection; and safety.

Learn More About 487-2000

487-2007
IEEE Recommended Practice for the Protection of Wire-Line Communication Facilities Serving Electric Supply Locations

Workable methods for protecting wire-line communication circuits entering electric supply locations are presented. This document covers: the electric supply location environment; protection apparatus; service types, reliability, service performance objective classifications, and transmission considerations; protection theory and philosophy; protection configurations; installation and inspection; and safety.

Learn More About 487-2007

776-1992
IEEE Recommended Practice for Inductive Coordination of Electric Supply and Communication Lines

The inductive environment that exists in the vicinity of electric power and wire-line telecommunications systems and the interfering effects that may be produced are addressed. An interface that permits either party, without need to involve the other, to verify the induction at the interface by use of a probe wire is presented. This recommended practice does not apply to railway signal circuits.

Learn More About 776-1992

These standards have been removed from active status through a ballot where the standard is made inactive as a consensus decision of a balloting group.


No Inactive-Withdrawn Standards

These standards are removed from active status through an administrative process for standards that have not undergone a revision process within 10 years.


820-2005
IEEE Standard Telephone Loop Performance Characteristics

Common denominators for subscriber line performance, independent of facility types, construction processes or equipment, and circuit provisioning methods are provided in this standard.

Learn More About 820-2005

Subscribe to our Newsletter

Sign up for our monthly newsletter to learn about new developments, including resources, insights and more.