Floating solar power involves installing solar panels on floating structures on a body of water, such as a lake, fjord or ocean, or in a hydropower reservoir. This floating solar park will consist of four "rafts", each with a diameter of about 70 metres, covering a total of over 15 000 square metres with solar panels. Each raft has a plastic ring and a thin membrane, much like a giant inflatable children's pool.
It is this membrane and the large area that makes this concept unique. It was developed by the Norwegian company Ocean Sun. Although the membrane is only a few millimetres thick, it can easily withstand the weight of the solar panels and of personnel carrying out installation or maintenance tasks.
"The large rafts simplify the work involved in installing, anchoring and servicing the plant, which will hopefully prove cost-effective," says Olav Hølland, head of the project management unit in Statkraft's International Power business area.
(Video photos: Statkraft)
By the end of 2017, 250 MW of floating solar power was installed globally, and this is expected to grow to around 10 GW by 2030. This is a small amount compared to the total market for solar power, but every contribution is welcome in the renewable energy market.
Most of the existing floating solar plants are installed in Asia, where most of the growth is expected to continue, especially in countries such as India and South Korea.
"For Statkraft, this technology will be most relevant in countries where we're already established with hydropower reservoirs and where there is a lot of sunshine," says Hølland.
"Moreover, if the plant is placed in a hydropower reservoir, as we will test in Albania, it can make use of existing infrastructure. The plant will also reduce evaporation from the reservoir," says Tom Kristian Larsen, Statkraft's country manager in Albania.
This is the first time Statkraft is involved in floating solar energy, and while the goal is for the plant to be economically profitable, it is primarily an R&D project.
"We are interested in what we can learn. How will the rafts and moorings handle wind and varying water levels? What happens to the aquatic environment under the plant? How will it affect evaporation from the reservoir? How will the plant affect bird life? We want answers to these types of questions," says Tron Engebrethsen, senior vice president with responsibility for power plants in the International Power business area.
"There may be long-term effects or issues we are not presently aware of. So we will follow this project very carefully before we consider using the technology elsewhere," he says.
It is no secret that there is tough competition on price in the renewable energy market, and floating solar power is no exception. The key is to find solutions that can reduce costs.
"What makes this solution particularly interesting is that it requires little material per kilowatt of electricity produced. This can lead to lower costs per installed MW and is also good for the environment. Each unit basically consists of only a membrane, plastic floating rings and anchoring equipment, and the solar panels. Such a unit will have an installed capacity of 0.5 MWp (watt peak), and in principle you can just multiply with as many units as you need," says Hølland.
The membrane used in the reservoir of Statkraft's power plant in Banja, Albania is produced by a Norwegian company, but the other components are "off the shelf". This means that in the future, such a plant can easily be produced with local labour and materials.
"The floating ring consists of a 12-metre-long plastic pipe which is welded together on site. This time we sourced it from China, but in the future they can be bought locally. The use of local labour is also an important factor in the profitability of this project," says Larsen.
"We will use local labour for project management, installation and service. If we had produced this in Norway and had Norwegian installers put it together, it would never have been profitable. This model is also in line with Ocean Sun's vision. They want this to be a package solution where the membrane is shipped in a container while the rest is obtained locally," he says.
The first raft of the planned solar power plant will be delivered and installed in the third quarter of 2019. Then the rest of the plant will be completed in the summer of 2020, unless unexpected and unpleasant surprises emerge.