The Australian National University (ANU) has completed a global audit of 530,000 potential sites for pumped-hydro energy storage that can be used to support low-cost, secure, 100 per cent renewable electricity grids.
The zero-emission grids would mainly rely on solar photovoltaic (PV) and wind technology, with support from pumped-hydro storage and extra high voltage transmission between regions. Solar PV and wind constitute the largest and second largest respectively annual global net capacity additions.
Dr Matthew Stocks said the prospective short-term off-river pumped-hydro energy storage (STORES) sites combined had a global potential storage capacity of 22 million Gigawatt-hours (GWh) – which is hundreds of times more than the amount needed to support a global 100 per cent renewable electricity grid.
“Only a small fraction of the 530,000 potential sites we’ve identified would be needed to support a 100 per cent renewable global electricity system. We identified so many potential sites that much less than the best one per cent will be required,” said Dr Stocks from the ANU Research School of Electrical, Energy and Materials Engineering (RSEEME).
“The perception has been there are limited sites for pumped hydro around the world, but we have found hundreds of thousands.”
The audit of these STORES sites and the team’s analysis relies on geographic information system (GIS) algorithms, which were peer reviewed recently as part of a publication authored by Dr Stocks and his colleagues in the international journal Applied Energy.
The team developed the advanced GIS algorithms to locate prospective sites for off-river pumped hydro across a large land area such as a state or a country. Each identified site comprises an upper and lower reservoir pair plus a hypothetical tunnel route between the reservoirs, and includes data such as latitude, longitude, altitude, head (the minimum altitude difference between potential upper and lower reservoirs in the data set – a larger head is generally better), slope, water volume, water area, rock volume, dam wall length, water/rock ratio, energy storage potential and approximate relative cost (categories A-E).
The team’s assessment is based on appealing physical characteristics, but the 530,000 potential pumped-hydro sites identified would require detailed due diligence involving land ownership, engineering, hydrological, environmental and other considerations.
Pumped-hydro energy storage sites require pairs of reservoirs at different altitudes, typically with areas of a few hundred hectares, in hilly terrain and joined by a pipe or tunnel with a pump and turbine. Water is pumped uphill when wind and solar energy is plentiful, and electricity is available on demand by releasing the stored water through the turbine.In September 2017, the team identified 22,000 STORES upper reservoirs in Australia. The new work extends the previous work to the rest of the world. Additionally, it identifies both upper and lower reservoir pairs and a route for the connecting tunnel.
“Only the most promising 3,000 sites are retained in our audit of Australia,” Stocks said.
Co-researcher Professor Andrew Blakers said off-river pumped-hydro storage typically delivered maximum power from five to 25 hours, depending on the size of the reservoirs.
“Pumped-hydro energy storage can go from zero to full power extremely quickly – it takes only a few minutes,” he said.
Professor Blakers said annual water requirements of an electricity system built primarily on solar PV and wind would be much less than a fossil fuel system because wind and PV do not require cooling water.
Co-researcher and RSEEME colleague Bin Lu said the potential pumped hydro sites identified were outside national parks and urban areas, and each site has storage potential in the range two to 150 GWh.
“Pumped hydro accounts for 97 percent of energy storage worldwide, has a typical lifetime of 50 years and is the lowest cost large-scale energy-storage technology available,” Lu said.