Concentrated solar thermal (electricity generated by the heat of the sun) with thermal storage 22%.
In a recent article on The Conversation, University of Melbourne Professor Emeritus Frank Larkins wrote that Australia’s targets to increase renewable energy will make electricity more expensive, thanks to problems with consistency and storage.
But Professor Larkins is several years behind developments in renewable energy and its integration into electricity grids. In fact, we already have technically feasible scenarios to run the Australian electricity industry on 100% renewable energy — without significantly affecting supply.
Professor Larkins states that hydro, wind energy, solar power depend on:
irregular weather patterns, which lead to uncertain and intermittent power output. This is a big challenge for electricity generators and retailers, and it can cost lots of money.
But the problem of “consistency” or variability of some renewable energy sources is now better understood, both from empirical experience with lots of wind power in electricity grids, and from hourly computer simulations of electricity supply and demand performed for many states, countries and global regions.
For instance, South Australia nominally has two coal-fired power stations, several gas-fired ones, and at least 15 operating wind farms. Wind now supplies an annual average of 27% of South Australia’s electricity generation. As a result, one of the coal stations is now shut down for half the year and the other for the whole year. And the state’s electricity supply system is operating reliably without the need for any additional non-renewable energy supply.
In Germany, the northern states of Schleswig-Holstein and Mecklenburg-Vorpommern have about 100% and 120%, respectively, of their electricity generated from the wind. Of course they use their transmission links with neighbouring states (including each other) to assist in balancing supply and demand with such high wind penetrations.
100% renewable — without supply problems
But Australia’s National Electricity Market (NEM) has no such links to other electricity supplies. How could it increase generation from renewable energy without hurting electricity supply?
Ben Elliston, Iain MacGill and I at UNSW have performed thousands of computer simulations of the hour-by-hour operation of the NEM with different mixes of 100% commercially available renewable energy technologies scaled up to meet demand reliably.
We use actual hourly electricity demand and actual hourly solar and wind power data for 2010 and balance supply and demand for almost every hour, while maintaining the required reliability of supply. The relevant papers, published in peer-reviewed international journals, can be downloaded from my UNSW website.
Using conservative projections to 2030 for the costs of renewable energy by the federal government’s Bureau of Resources and Energy Economics (BREE), we found an optimal mix of renewable electricity sources. The mix looks like this:
- Wind power 46%;
- Concentrated solar thermal (electricity generated by the heat of the sun) with thermal storage 22%;
- Photovoltaic solar 20% (electricity generated directly from sunlight);
- Biofuelled gas turbines 6%; and
- Existing hydro 6%.
So two-thirds of annual energy can be supplied by wind and solar photovoltaic — energy sources that vary depending on the weather — while maintaining reliability of the generating system at the required level. How is this possible?
It turns out that wind and solar photovoltaic are only unable to meet electricity demand a few times a year. These periods occur during peak demand on winter evenings following overcast days that also happen to have low wind speeds across the region.
Since the gaps are few in number and none exceeds two hours in duration, there only needs to be a small amount of generation from the so-called flexible renewables (those that don’t depend on the vagaries of weather): hydro and biofuelled gas turbines. Concentrated solar thermal is also flexible while it has energy in its thermal storage.
The gas turbines have low capital cost and, when operated infrequently and briefly, low fuel costs, so they play the role of reliability insurance with a low premium.
No need for batteries
Our research, together with similar extensive hourly computer simulations by others spanning up to a decade from Europe and the USA (reviewed in Chapter 3 of “Sustainable Energy Solutions for Climate Change”), refute Professor Larkins’ statement that “We need baseload electric power