Before deregulation and privatization swept over Iceland, HS ORKA was a municipal utility that generated electricity and provided heat to nearby communities on the Reykjanes peninsula. HS ORKA was eventually privatized and the communities leased the geothermal resource to the company. In turn they now receive royalties for the sale of electricity and heat.
The area around the plant at Svartsengi, or "black meadow" in Icelandic, was open to the public. There were no chain-link fences. No guards. And at one fumarole field, there was an open boardwalk for tourists. With the exception of the wind, the cold, and the gray sky, you could imagine you were in Yellowstone National Park.
Fumarole field on the Reykjanes peninsula, Iceland.
Originally the Svartsengi site was developed to heat the nearby harbor town of Grindavik after the oil crisis, but geologists found a much greater resource than expected and the plant has steadily grown.
The plant now produces 75 MW of electricity from 12 wells. Svartsengi also produces an equivalent amount of thermal fluids for district heating.
HS Orka pumps the waste geothermal fluids back in into 12 recharge wells, and of course, feeds some of the waste geothermal fluids to the popular Blue Lagoon.
The evaporation pond of the Blue Lagoon has become the pearl of Iceland, receiving some 500,000 visitors per year.
The Blue Lagoon is one of Iceland's most famous tourist attractions.
What is most striking to an American visitor is the appearance of the plants — not just the interior but also the exterior. The interiors of most power plants today are spotless, even polished. Managers — and, more importantly, insurers — learned that if you can't keep the floor clean, you're not likely to do much of anything else right, ultimately endangering employees and expensive equipment.
Iceland's power plants go beyond spotless. They are works of art.
Iceland takes architecture seriously, and this is evident in the most utilitarian of structures: their power plants.
Both Svartsengi and the nearby Reykanes plant are stunning examples of modern industrial architecture. Rather than being a blot on the landscape, they are literally shining examples that Iceland takes renewable energy and its place in the landscape seriously. It's a lesson that power-plant developers should take to heart outside Iceland.
Architectural feature of the Svartsengi geothermal power plant, Iceland.
While Iceland has become famous for generating electricity with its geothermal resources, it has achieved even greater success with using geothermal energy for heating.
We next met up with Einar Gunnlaugsson at Orkuveita Reykjavikur, the municipal utility serving Reykjavik with electricity and heat.
Geothermal heating in Reykjavik began at the Laugardalur hot springs, where women took their laundry.
To this day the main shopping street of the capital, Laugavegur, remains the "road to the hot springs," and is now a part of the city and the site of a major swimming, sport, and hotel complex, including the Hilton Nordica.
There are ten wells on ¼ km² centers providing low-temperature (120 C at an average flow rate of 330 l/s) water for the district. Here, the hot springs were at the surface, and geothermal development used the water directly, in the process drawing down the water table.
In the complex dance between surface springs and urban development, geothermal exploitation allowed the city to expand to new building sites. Now that the district is urbanized, the wells must continue pumping not only for the heat they provide, but now also for dewatering the district. Einar points this out as an illustration of the challenge faced by those who want to build sustainable cities.
Reykjavik has come a long way. In 1933 only 3% of the capital's population was served by a district heating system. Nearly everyone used coal to heat, and the sky was black as a result.
By the 1960s, says Einar, half of the city was heated by oil and the population was vulnerable when the oil crises hit in the 1970s.
Following the first oil crisis, most buildings were switched to the district heating system. One unexpected benefit was a dramatic drop in emissions. The fall in emissions continued into the 1990s as more of the city, and even rural areas converted to geothermal heating.
Einar proudly points to the near elimination of global warming gases in Iceland, noting that emissions of CO2 from electricity generation and heating are now only found in some off-gases from the city's newly developed high-temperature geothermal field.
No other city has developed district heating on the scale of Reykjavik. As a result, city residents benefit from low-cost heat at a stable price not dependent upon the volatility in the price of fossil fuels. Einar argues that the cost of heating in Reykjavik is one-fourth that of heating in Copenhagen. For example, he lives in a 180 m² (2,000 ft²) home and pays only 60,000 IKR (€400, $500 USD) per year for heat.
Of the geothermal fluids used for heating, 85% is used to heat buildings and the remainder for domestic hot water. Einar says that the volume of geothermal fluids used for heating has steadily decreased since the 1980s as Iceland tightens up building insulation standards.
Orkuveita Reykjavikur's stainless steel well enclosure in the Laugardalur district of Reykjavik.
Like their counterparts at HS Orka, Orkuveita Reykjavikur takes the architectural appearance of its well sites and power plants seriously. Only a well trained eye can detect a faint wisp of steam from its stainless-steel well enclosures in the Laugardalur hotel district.
Orkuveita Reykjavikur operates two plants in a large high-temperature geothermal field southeast of the capital: Nesjavellir, and Hellisheiði. Both plants generate electricity and in 2010 a 30-kilometer insulated pipeline was completed that carries geothermal fluids to Reykjavik.
The plants are big by geothermal standards and are continually being expanded. Two more units were added in 2011, bringing total electrical capacity to more than 300 MW, and an equivalent amount of geothermal heat for the capital.
Power House for Britain?
Iceland not only points to its success in meeting its own needs with renewables but also aggressively markets its renewable resources to energy-intensive industries. Now it wants to go even further — specifically, to the British Isles.
In an ambitious — some might say foolhardy — move, Iceland has injected itself into Britain's Electricity Market Reform debate by proposing an unprecedented 700 mile sub-sea cable to Scotland. The $2 billion project would carry 5 TWh of Iceland's renewable electricity to Britain's energy market reports Bloomberg. That's a third more electricity than produced in all of Iceland today and as much as all the currently developed geothermal on the island.
Iceland's proposal is roughly equivalent to the target of Britain's microgeneration feed-in tariff of 8 TWh per year, but is less than half that generated by wind in Britain in 2011. More controversial, the 5 TWh is also roughly equivalent to the output of a typical nuclear reactor and Britain is struggling to find a way to justify new reactors.
Whether such a project is technically feasible or economically viable remains to be seen. Iceland certainly has the untapped geothermal potential to do so. But it's an open questoin as to whether geothermal resources developed in Iceland and transmitted such a long distance would be cheaper than if Britain developed its own geothermal resources.
And if Britain launches its EMR as planned, what would be the "strike price" of Icelandic geothermal energy delivered to Britain? Would it be cheaper than new nuclear? Intriguing questions all.
Regardless of whether such a mega-project is feasible or whether Iceland's citizens would be willing to tolerate the financial risk of developing the project after all they've lost in the country's banking boondoggle, Iceland remains a model of what can be accomplished with renewable energy both in electricity generation — and equally as important in heating — when a nation puts its mind to it.