Operation and Maintenance of a Gas Insulated Substation

A primary distinction between conventional Air Insulated Substations (AIS) and Gas Insulated Substations (GIS) lies in the configuration of the electrical components. In GIS, the SF gas-insulated components are enclosed within a grounded, pressurized metallic housing. This encapsulation fundamentally changes the operation of switchgear components such as circuit breakers, disconnectors, and earthing switches, as it eliminates the possibility of direct visual inspection or observation of the disconnector gap or earthing switch status in open or closed positions. In addition to this fundamental difference, GIS technology introduces several specialized operational characteristics. These include the use of viewports, cameras, and endoscopes for internal inspections, considerations regarding induced currents in metallic enclosures, various alarm systems, local control cubicles, remote control capabilities, mimic diagram schemes, gas compartment zoning, and the concept of unmanned substations. The maintenance section of this book draws from practical field experience with GIS systems that have been operational for several years. It discusses the types and origins of defects, their repair procedures, and the intricate planning involved. Standard maintenance techniques are outlined, including procedures to assess the quality of the SF insulating gas, visual and optical inspection methods, management of gas handling records, and routines for detecting gas leaks. Furthermore, the book explores specialized practices involving interlocks, gas zone configurations, spare parts management, and the use of dedicated maintenance equipment. Lessons learned from experience are shared regarding gas zone identification, secondary system interfaces, and wiring techniques. Preconstruction training of personnel, continuous condition monitoring, GIS retrofitting, and maintenance of busbar gas leaks are also addressed. The book also covers the GIS repair process in detail. It provides information on the types of defects that typically necessitate repair in GIS systems, the estimated duration of such repairs, and how service continuity is influenced by system design. Additionally, the book explains the procedures for extending a GIS installation after years of operation. It outlines the definition and configuration of the interface between two GIS systems of varying dimensions. It details the scope of work required when extension was not foreseen during the original design phase, how to maintain service continuity during the extension process, and the methods for verifying the new interface post-extension. Further, the book elaborates on the process of retrofitting GIS installations for upgrades. It discusses the challenges posed by aging switchgear systems and provides in-depth guidance on modernizing or upgrading existing substations. Particular focus is given to the replacement of circuit breakers within GIS installations to enhance switching capability. The issue of GIS equipment overloading is examined, along with the principles governing continuous current ratings under specified thermal and dielectric conditions in substation design. The book also addresses the determination of thermal limits in accordance with IEEE and IEC standards, discusses the maximum allowable continuous load current, short-term overload capacity, and includes equations necessary for calculating overload conditions.