Solar Incentives Slashed Under New Rules

The Baillieu government has cut incentives for rooftop solar panels for next year as part of a shake-up of how small-scale renewable energy is priced in the state.

The changes reduce the Victorian feed-in-tariff for solar to eight cents for each kilowatt hour fed into the grid in 2013 - down from the existing rate of 25 cents - and fulfils recommendations by the state's competition advisory body.

The changes will not affect customers with existing contracts and tariff rates. Households that have paperwork lodged by September 30 with electricity suppliers can also still get access to the existing 25-cent tariff.

A review released today by the Victorian Competition and Efficiency Commission recommends a six-to-eight cents a kilowatt hour tariff be put in place, with the government accepting the top end of that range for 2013.

The tariff will then be adjusted by the government each year in 2014, 2015 and 2016 based on the wholesale electricity price, before moving to a fully floating market price in 2017.

The tariff scheme will also be opened to other forms of renewable energy systems generating 100 kilowatts or less.

The changes fall short of calls by the renewable energy industry that a fair rate of tariff for solar was 12 to 16 cents per kilowatt-hour.

Announcing the changes this afternoon, Energy Minister Michael O'Brien said the falling costs of solar panel systems and rising power prices meant households were taking up solar without the need for over-generous subsidies from other power users.

He said an older 60-cents per kilowatt-hour tariff — closed by the Baillieu government last year — would cost Victorian households $41 million a year to 2024 through electricity bills in subsidies to homes with solar panels.

"People in public housing, tenants who cannot access solar, are paying higher electricity bills in order to subsidise the rooftop solar for other people. Now that wasn't sustainable at those rates, they were over generous," Mr O'Brien said.

Labor's energy spokeswoman, Lily D'Ambrosio, criticised the decision, saying thousands of Victorian families were installing solar panels to reduce their power bills amid increasing cost-of-living pressures.

''The Baillieu government has again shown it just doesn’t care about supporting families who want to reduce their energy costs while also doing their bit for the environment,'' she said.

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Fotowatio Plans to Build Australia’s Largest Solar-Power Project

Fotowatio Renewable Ventures, the solar-power plant developer backed by U.S. energy investor Denham Capital Management LP, won the right to build a 20-megawatt project near Australia’s capital.

Fotowatio will participate in the Australian Capital Territory’s feed-in tariff program, which rewards generators of solar power by paying above-market prices for the electricity, Simon Corbell, ACT minister for the environment and sustainable development, said today in a statement.

The Royalla solar farm, to be built about 25 kilometers (16 miles) south of Canberra, will become the largest in Australia by 2014, according to the statement. The venture will help in an effort to lower carbon emissions and shift away from fossil fuels, the ACT government said.

Fotowatio, which is based in the Netherlands, sought a new project in Australia after losing a competition earlier this year for federal government funds to build a large-scale solar plant in New South Wales state. Denham Capital in March reached an agreement with Fotowatio to invest $190 million in solar projects in markets including Australia.

Clean Energy With a Pinch of salt

A sodium-ion battery being developed in Australia is set to increase solar energy use and reduce our dependence on fossil fuels, according to researchers.

Although bulkier than commonly used lithium batteries, sodium-ion batteries will be cheaper, less toxic, and more environmentally friendly, said Manickam Minakshi, a chemistry and mineral scientist at Murdoch University, in Perth Australia.

“Our water-based sodium-ion battery has shown excellent potential for affordable, low-temperature storage,” he said.

Better batteries

Other batteries used for renewable energy storage – such as molten salt or molten sulphur – only work at high temperatures, making them expensive and impractical. Also, like lead-acid batteries, they are very corrosive and environmental pollutants, which aren't problems with sodium-ion batteries, said Minakshi.

The Murdoch team is now moving towards large-scale commercialisation, and the future could see these batteries connected to solar panels in every home. “This is a very exciting time,” said Minakshi.
The new sodium-ion battery has particular potential when coupled with the green power of solar energy. Widespread use of power from solar panels is limited because there are periods known as ‘non-generation’ times, when power cannot be produced. These include, for example, overcast weather or night-times.

Power in the dark

“Using solar energy panels to get power will only make sense when you can store the power when the Sun’s not shining,” said Stephen Thurgate, vice-president of program development partnerships at Sydney’s Macquarie University.

Murdoch’s new sodium-ion batteries could have applications in small networks with their own battery systems or ‘smart grids’ that use information and communication technology to reduce dependence on centralised power stations, said Thurgate.

While commonly used rechargeable lithium batteries have a higher voltage, making them more suitable for transport and vehicular power sources, they come with a lot of issues, said Minakshi.

Sodium: cheap and abundant

Lithium, for example, is more expensive and far less abundant than sodium in the Earth’s crust.
Another advantage of sodium-ion batteries is that they have a higher density, meaning they are able to store more energy for their weight. Combined with their low costs, they could open up affordable green energy to the developing world.

Lithium and sodium share similar chemical properties, but the sodium ion is 2.5 times the size of lithium, and a big challenge for the Murdoch researchers was finding a ‘host material’ for these large ions.

“Ions travel out of the cathode and into the anode to form a current,” said Minakshi. “As an imperfect analogy, you can think of them as mesh filters that ions pass through. We had to find materials with larger gaps in their mesh.”

Paving a path for alternative energy technology

Murdoch’s new development doesn’t spell the death of the lithium battery, which is still ideal for transportation because of its lighter weight, said Danielle Meyrick, deputy dean of the School of Chemical and Mathematical Sciences. “Sodium is slightly heavier and is much more suitable for stationary energy storage applications [such as] industry,” she said.

The sodium-ion technology could also enable the use of renewable energy in households, moving away from traditional energy generation sources.

“This kind of battery facilitates security of supply and continuity of electricity supply to households," said Meyrick. “It facilitates storage in times when there’s no sunlight, when there’s no wind, [and] when there’s no snow.”

Although there is more research to be done on finding the optimum scale of the battery and cell size, Thurgate said the findings were promising.

“The fact that [sodium-ion batteries are] based on readily available materials, that it’s an aqueous solvent [water-based] – so there’s no fear of the thing being flammable – [and] the fact the energy density is very high... are all great,” she said.