Kelenföldi Erőmű ranks as the 8th largest power generation facility in Hungary, making it a key player in the country's energy sector. With a capacity of 173 MW, this gas-fired power plant accounts for 2.75% of Hungary's total capacity of 6,291 MW, where natural gas is the dominant fuel. This significant share underscores its role in a landscape where reliance on gas-fired generation is crucial. Within a 50 km radius, Kelenföldi Erőmű is surrounded by several other gas facilities, including the Dunamenti Erőmű, which boasts an impressive capacity of 840.7 MW, and the Alpiq Csepel Erőmű at 401 MW. The Kispesti Erőmű, providing 109.2 MW, further complements this gas-dominated cluster, while a smaller solar facility, Dunai, adds 21 MW of renewable capacity to the mix. This concentration of gas plants highlights Hungary’s strategic focus on natural gas as a primary energy source, especially as the country seeks to diversify its energy portfolio. The Kelenföldi plant, with its advanced generation technology, is essential for ensuring grid reliability and meeting peak demand. Operated by a local entity, this facility has been integral to Hungary's energy infrastructure, reflecting the nation’s ongoing transition toward a more sustainable energy future. As Europe moves towards decarbonization, Kelenföldi Erőmű is likely to play a pivotal role in supporting Hungary's energy security while adapting to the changing landscape of energy production.
67 years old
Hungary, Europe
- Primary Fuel Type
- Gas
- Energy Source
- Non-Renewable
- Country
Hungary- Continent
- Europe
- Data Source
- Global Power Plant Database
Gas power generation is a significant component of the global energy landscape, characterized by the use of natural gas to produce electricity. This process typically involves either gas turbines or combined cycle gas plants. In a gas turbine, compressed air is mixed with natural gas and ignited, producing high-temperature exhaust gases that spin a turbine connected to a generator. Combined cycle plants enhance efficiency by utilizing both gas and steam turbines. After the gas turbine generates electricity, the waste heat is used to produce steam, which drives a steam turbine, thereby maximizing energy extraction from the fuel.
Help us improve our database by reporting any corrections or updates. Your contribution helps keep our global power plant data accurate and up-to-date.