The ac/dc substation control equipment, pole control equipment, protection equipment, and auxiliary secondary equipment of high-voltage direct-current (HVDC) transmission systems are the focus of this guide. Based on analyzing the existing HVDC transmission projects, specifications for structure, configuration, performance and test of HVDC control and protection equipment, which could be applied to HVDC transmission system with the voltage range up to and including 800 kV are provided in this guide.
- Sponsor Committee
- BOG/CAG - Entity Collaborative Activities Governance Board
- Status
- Active Standard
- PAR Approval
- 2016-06-30
- Board Approval
- 2017-02-14
- History
-
- ANSI Approved:
- 2018-07-02
- Published:
- 2017-06-28
Working Group Details
- Society
- Sponsor Committee
- BOG/CAG - Entity Collaborative Activities Governance Board
- Working Group
-
wg-uhvdc-tcp - Working group for establishing Basic Requirements for ultra high-voltage direct-current (UHVDC) transmission control and protection
- IEEE Program Manager
- Soo Kim
Contact Soo Kim - Working Group Chair
- Hong Rao
Other Activities From This Working Group
Current projects that have been authorized by the IEEE SA Standards Board to develop a standard.
P1899
Guide for Basic Requirements for Line Commutated Converter High Voltage (800 kV and below) Direct Current Transmission Protection and Control Equipment
This guide specifies the basic norms for protection and control equipment of High-Voltage Direct Current (HVDC) transmission systems that have the voltage range up to and including 800 kV. It also defines and specifies requirements for control and protection equipment used in the design, manufacturing, research and testing of HVDC control and protection equipment. These guidelines apply to the control and protection equipment for LCC (line commutated converter) HVDC systems with the main circuit structure of one 12-pulse converter or two series 12-pulse converters per station pole. This guidance can also be used as reference for HVDC applications with other topologies like back-to-back links and parallel converter systems.
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