 | This article has multiple issues. Please helpimprove it or discuss these issues on thetalk page.(Learn how and when to remove these messages) (Learn how and when to remove this message)
|
Power-system automation is the act of automaticallycontrolling the power system via instrumentation and control devices.Substation automation refers to using data fromIntelligent electronic devices (IED), control and automation capabilities within the substation, and control commands from remote users to control power-system devices.
Since full substation automation relies on substation integration, the terms are often used interchangeably. Power-system automation includes processes associated with generation and delivery of power. Monitoring and control of power delivery systems in the substation and on the pole reduce the occurrence of outages and shorten the duration of outages that do occur. TheIEDs, communications protocols, and communications methods, work together as a system to perform power-system automation.The term “power system” describes the collection of devices that make up the physical systems that generate, transmit, and distribute power. The term “instrumentation and control (I&C) system” refers to the collection of devices that monitor, control, and protect the power system. Many power-system automation are monitored by SCADA.
Power-system automation is composed of several tasks.
In addition, another task is power-system integration, which is the act of communicating data to, from, or among IEDs in the I&C system and remote users. Substation integration refers to combining data from the IED's local to a substation so that there is a single point of contact in the substation for all of the I&C data.
Power-system automation processes rely on data acquisition; power-system supervision and power-system control all working together in a coordinated automatic fashion. The commands are generated automatically and then transmitted in the same fashion as operator initiated commands.
The instrument transformers with protective relays are used to sense the power-system voltage and current. They are physically connected to power-system apparatus and convert the actual power-system signals. The transducers convert the analog output of an instrument transformer from one magnitude to another or from one value type to another, such as from an ac current to dc voltage. Also the input data is taken from the auxiliary contacts of switch gears and power-system control equipment.
The I&C devices built using microprocessors are commonly referred to as intelligent electronic devices (IEDs). Microprocessors are single chip computers that allow the devices into which they are built to process data, accept commands, and communicate information like a computer. Automatic processes can be run in the IEDs. Some IEDs used in power-system automation are:
All lines and all electrical equipment must be protected against prolongedovercurrent. If the cause of the overcurrent is nearby then automatically that current is interrupted immediately. But if the cause of the overcurrent is outside the local area then abackup provision automatically disconnects all affectedcircuits after a suitable time delay.
Note that disconnection can, unfortunately, have acascade effect, leading to overcurrent in other circuits that then also must therefore disconnect automatically.
Also note thatgenerators that suddenly have lost their load because of such a protection operation will have to shut down automatically immediately, and it may take many hours to restore a proper balance betweendemand and supply in the system, partly because there must be propersynchronization before any two parts of the system can be reconnected.
Reclosing operations ofcircuit breakers usually are attempted automatically, and often are successful during thunderstorms, for example.
Asupervisory control and data acquisition system (SCADA) transmits and receives commands or data from process instruments and equipment. Power system elements ranging from pole-mounted switches to entire power plants can be controlled remotely over long distance communication links. Remote switching, telemetering ofgrids (showing voltage, current, power, direction, consumption inkWh, etc.), even automatic synchronization is used in some power systems.
Power utility companies protect high voltage lines by monitoring them constantly. Thissupervision requires the transmission of information between thepower substations in order to ensure correct operation while controlling every alarm and failure. Legacy telecom networks were interconnected with metallic wires, but thesubstation environment is characterized by a high level of electromagnetic fields that may disturb copper wires.
Authorities use a tele-protection scheme to enable substations to communicate with one another to selectively isolate faults onhigh voltage lines,transformers,reactors and other important elements of the electrical plants. This functionality requires the continuous exchange of critical data in order to assure correct operation. In order to warranty the operation the telecom network should always be in perfect conditions in terms of availability, performance, quality and delays.
Initially these networks were made of metallic conductive media, however the vulnerability of the 56–64 kbit/s channels toelectromagnetic interference, signalground loops, andground potential rise made them too unreliable for the power industry. Strong electromagnetic fields caused by the high voltages and currents inpower lines occur regularly in electric substations.
Moreover, during fault conditions electromagnetic perturbations may rise significantly and disturb those communications channels based on copper wires. The reliability of the communications link interconnecting theprotection relays is critical and therefore must be resistant to effects encountered in high voltage areas, such as high frequency induction and ground potential rise.
Consequently, the power industry moved tooptical fibers to interconnect the different items installed in substations. Fiber optics need not begrounded and are immune to the interferences caused by electrical noise, eliminating many of the errors commonly seen with electrical connections. The use of fully optical links from power relays to multiplexers as described by IEEE C37.94 became standard.
A more sophisticated architecture for the protection scheme emphasizes the notion offault tolerant networks. Instead of using a direct relay connection and dedicated fibers, redundant connections make the protection process more reliable by increasing the availability of critical data interchanges.
IEEE C37.94, full titleIEEE Standard for N Times 64 Kilobit Per Second Optical Fiber Interfaces Between Teleprotection and Multiplexer Equipment, is anIEEE standard, published in 2002, that defines the rules to interconnect tele-protection and multiplexer devices of power utility companies. The standard defines a data frame format for optical interconnection, and references standards for the physical connector formulti-mode optical fiber. Furthermore, it defines behavior of connected equipment on failure of the link, and the timing and opticalsignal characteristics.
Teleprotection systems must isolatefaults very quickly to prevent damage to the network and power outages. The IEEE committee defined C37.94 as a programmable n x 64 kbit/s (n=1...12) multimode optical fiber interface to provide transparent communications between teleprotection relays and multiplexers for distances of up to 2 km. To reach longer distances, the power industry later adopted asingle mode optical fiber interface as well.
The standard defines the protection and communications equipment inside a substation using optical fibers, the method for clock recovery, the jitter tolerances allowed in the signals, the physical connection method, and the actions the protection equipment must follow when any kind of network anomalies and faults occur. C37.94 was already implemented by manyprotection relay manufacturers such as ABB, SEL, RFL, and RAD; and tester manufacturers such as Net Research (NetProbe 2000), ALBEDO and VEEX. Teleprotection equipment once offered a choice of transmission interfaces, such as the IEEE C37.94 compliant optical fiber interface for transmission over fiber pairs, andG.703, 64 kbit/s co-directional andE1 interfaces.
