Tapping natural sources of hot water deep underground is allowing the Hungarian city of Szeged to quit its Russian gas habit to heat homes.
At plants painted with birds and hedgehogs, hot water from deep underground is being channeled to produce energy and heat for thousands of households in Hungary's third largest city Szeged.
Experts say the project—billed as Europe's biggest urban heating system overhaul—can serve as a model for other cities across the continent as EU nations scramble to wean themselves off Russian gas after Moscow's invasion of Ukraine.
"Geothermal energy is local, accessible and renewable so why not use it," geologist Tamas Medgyes told AFP beside a recently completed well in the middle of a residential neighborhood.
The city of 160,000 people, located some 170 kilometers (110 miles) south of Budapest, is one of 12 in the landlocked central European country with geothermal district heating.
When the system is fully built out next year, 27 wells and 16 heating plants will push geothermally heated water through 250 kilometers of pipes to heat 27,000 flats and 400 non-residential consumers.
'Blueprint'
This will make it Europe's biggest geothermal urban heating system outside of Iceland.
But unlike in the Icelandic capital, Szeged's heating systems were built to run on gas.
EU member Hungary covers 65 percent of its oil needs and 80 percent of its gas needs with imports from Russia.
Underground water near the boiling point brought to the surface to heat water running though municipal heating pipes to buildings.
"This housing project was built in the 1980s. Since then we have burnt millions of cubic meters of imported Russian gas to heat cold water in these apartments," Medgyes said.
But now, "we drilled down and got the hot water beneath our feet," he said about the project, whose cost of more than 50 million euros ($51 million) is partially covered by EU funds.
He added the project can be a "blueprint" for cities in parts of France, Germany, Italy or Slovakia that are rich in geothermal deposits.
Experts says geothermal energy is an underutilized source of renewable heat in Europe.
"The geothermal urban heating development in Szeged is an easy-to-adopt example in many regions of Europe," said Ladislaus Rybach, an expert at the Institute of Geophysics in Zurich, Switzerland.
Lajos Kerekes of the Regional Center of Energy Policy Research told AFP that more than 25 percent of the EU's population lives in areas suitable for geothermal district heating.
"This housing project was built in the 1980s. Since then we have burnt millions of cubic meters of imported Russian gas to heat cold water in these apartments," Medgyes said.
But now, "we drilled down and got the hot water beneath our feet," he said about the project, whose cost of more than 50 million euros ($51 million) is partially covered by EU funds.
He added the project can be a "blueprint" for cities in parts of France, Germany, Italy or Slovakia that are rich in geothermal deposits.
Experts says geothermal energy is an underutilized source of renewable heat in Europe.
"The geothermal urban heating development in Szeged is an easy-to-adopt example in many regions of Europe," said Ladislaus Rybach, an expert at the Institute of Geophysics in Zurich, Switzerland.
Lajos Kerekes of the Regional Center of Energy Policy Research told AFP that more than 25 percent of the EU's population lives in areas suitable for geothermal district heating.
Researchers say more than a quarter of Europeans live in areas where geothermal energy could be tapped.
Long before the Ukraine war, Balazs Kobor, director at Szeged heating firm Szetav, began exploring how cities can use geothermal energy and "knocking on doors of decision-makers".
In 2015, the city municipality appointed him and Medgyes to initiate the integration of renewables into district heating.
"To heat the city annually the firm was burning 30 million cubic meters of gas and producing around 55,000 metric tons of carbon emissions every year," said Kobor.
"The city itself was its biggest carbon emitter," he added.
Replacing gas by geothermal energy will slash the city's greenhouse gas emissions by 60 percent—around 35,000 tons—annually, according to Kobor.
If similar small-to-medium-sized cities switched their district heating to geothermal it would be "a major step towards a carbon neutral, sustainable Europe," he said.
Long before the Ukraine war, Balazs Kobor, director at Szeged heating firm Szetav, began exploring how cities can use geothermal energy and "knocking on doors of decision-makers".
In 2015, the city municipality appointed him and Medgyes to initiate the integration of renewables into district heating.
"To heat the city annually the firm was burning 30 million cubic meters of gas and producing around 55,000 metric tons of carbon emissions every year," said Kobor.
"The city itself was its biggest carbon emitter," he added.
Replacing gas by geothermal energy will slash the city's greenhouse gas emissions by 60 percent—around 35,000 tons—annually, according to Kobor.
If similar small-to-medium-sized cities switched their district heating to geothermal it would be "a major step towards a carbon neutral, sustainable Europe," he said.
Up to three months is needed to drill far enough down to tap the hot water.
2,000 meters below ground
Surrounded by the Carpathian and Alps mountain ranges, Hungary and especially the area around Szeged forms a basin where 92-93 degree Celsius (198-199 degree Fahrenheit) hot water collects as deep as 2,000 meters (6,600 feet) below ground.
In facilities adjacent to the wells, "heat exchangers" comprising hundreds of metal panels transfer the heat to water in pipeline circuits that serve different neighborhoods.
The geothermal water itself does not enter the circuits but re-enters the earth through a "reinjection" well nearby, explained Medgyes.
2,000 meters below ground
Surrounded by the Carpathian and Alps mountain ranges, Hungary and especially the area around Szeged forms a basin where 92-93 degree Celsius (198-199 degree Fahrenheit) hot water collects as deep as 2,000 meters (6,600 feet) below ground.
In facilities adjacent to the wells, "heat exchangers" comprising hundreds of metal panels transfer the heat to water in pipeline circuits that serve different neighborhoods.
The geothermal water itself does not enter the circuits but re-enters the earth through a "reinjection" well nearby, explained Medgyes.
Residents don't notice any changes in their heating or hot water.
In another neighborhood, a noisy drill is gradually working its way deeper and deeper into the ground, adding sections of pipe as it goes.
The drilling period takes around three months, said Medgyes.
And while residents can see and hear the drills as they work, after the work is done, they don't notice the change of heat source in their homes.
"The radiators and tap water are as warm as before. I don't feel any difference," Gabriella Maar Pallo, a 50-year-old clerk, told AFP in her nearby apartment.
In another neighborhood, a noisy drill is gradually working its way deeper and deeper into the ground, adding sections of pipe as it goes.
The drilling period takes around three months, said Medgyes.
And while residents can see and hear the drills as they work, after the work is done, they don't notice the change of heat source in their homes.
"The radiators and tap water are as warm as before. I don't feel any difference," Gabriella Maar Pallo, a 50-year-old clerk, told AFP in her nearby apartment.
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