Grid code explained

A grid code is a technical specification which defines the parameters a facility connected to a public electric grid has to meet to ensure safe, secure and economic proper functioning of the electric system. The facility can be an electricity generating plant, a consumer, or another network.[1] The grid code is specified by an authority responsible for the system integrity and network operation. Its elaboration usually implicates network operators (distribution or transmission system operators), representatives of users and, to an extent varying between countries, the regulating body.[2]

Contents of a grid code vary depending on the transmission company's requirements. Typically, a grid code will specify the required behavior of a connected generator during system disturbances. These include voltage regulation, power factor limits and reactive power supply, response to a system fault (e.g. short-circuit), response to frequency changes on the grid, and requirement to "ride through" short interruptions of the connection.

There is not a common grid code in all countries and each electric grid has its own grid code. Even in North America, there is no grid code that applies to all territories.

Independent power producers

All generators including Independent power producers like photovoltaic power stations[3] or wind farms[4] have to comply with the grid code.[5]

Categorizing

Grid code requirements can be divided into two categories: static and dynamic requirements.[6]

See also

References

External links

Notes and References

  1. Web site: GmbH . Next Kraftwerke . The Grid Code: Rules for the power network . Virtual Power Plant | Power Trader | Aggregator . 2019-02-13 . 2019-07-04.
  2. Web site: Grid Code . National Grid ESO . 2018-10-17 . 2019-07-04.
  3. Web site: Solar Energy Plants Grid Connection Code . 2019-07-04 . 2020-01-19 . https://web.archive.org/web/20200119090607/http://egyptera.org/Downloads/code%20w%20dalil/code/Egypt_gridcode_for_solar_plant_connection%20on%20MV%20and%20HV.pdf . dead .
  4. Book: An Improved Control Strategy for DFIG Low Voltage Ride-Through Using Optimal Demagnetizing method . 2019-06-18 . 10.1109/PEDSTC.2019.8697267 . 2019 10th International Power Electronics, Drive Systems and Technologies Conference (PEDSTC) . 464–469 . Harandi . Mahdi Jafari . Ghaseminejad Liasi . Sahand . Nikravesh . Esmail . Bina . Mohammad Tavakoli . 978-1-5386-9254-7 .
  5. http://eurosunmed.cnrs.fr/sites/default/files/documents/grid_codes_for_renewable_energy_h._svendsen_sintef.pdf Grid codes for renewable energy integration
  6. Web site: ABB Conversations > Standards and grid codes – the latest developments and trends . ABB Conversations . 2019-07-04 . 2019-07-04.