Government-funded research into decarbonizing heavy industry using concentrated solar thermal (CST) yields results with the world’s first spin-off based on a new kind of high temperature solar receiver – the falling particle receiver.
Because of the simplicity and durability of particle-based CST, and its ability to operate at very high temperatures, international solar researchers have long believed that it could get to commercial readiness faster than other novel CST technologies under development…
Now it has.
FPR Energy – for Falling Particle Receiver Energy – is the world’s first startup based on this new kind of solar technology, that has been years in the making through international research.
Falling particle receivers are at the cutting edge of CST technologies in which heat is generated by thousands of mirrors that concentrate sunlight into a solar receiver atop a tower. To date, molten salt, a watery liquid, has been used to absorb and transfer the heat in this receiver to be stored to run a traditional steam cycle or deployed as direct heat.
But instead, in falling particle receivers, ceramic particles are used to absorb and transfer this highly concentrated solar heat. The particles fall as a thin curtain over a descending cascade forming the absorber surface of the solar receiver, transferring solar heat to a gas; like air, steam or s-CO2, to store and run a Brayton power cycle, or deployed as – much hotter – direct heat.
Particles enable a high temperature solar breakthrough
“Particle CST technology has no temperature limitation,”confirmed Jin-Soo Kim, who has led solar receiver research at CSIRO for six years as Principal Research Scientist.
“So this is not like the molten salt, which is limited by both high and low temperatures. We can see industrial decarbonization by providing the process heat, and also, depending on the process temperature, it can provide the heat for the thermal chemical reaction. So the application area is quite wide open, depending on the customer’s needs.”
The ceramic particles FPR Energy will use are already used in the gas fracking industry to prop rock fractures apart to liberate natural gas. They are spherical, so they flow like a liquid and have been shown to withstand being heated up to 1200°C and back to air temperature daily for years, making them a robust and durable way to absorb and transfer solar heat.
Tall silos can store the hot particles for firm, fully dispatchable power generation, or to provide consistent 24/7 heat for industrial processes or for producing liquid fuels using solar thermochemistry (see How solar fuels are made).
Record large investment in the first commercial falling particle receiver-based CST
FPR Energy’s three founding partners are the Australian science research institute CSIRO, which holds the IP; industry partner Osaka Gas, who have a long list of customers needing to decarbonize their businesses; and financial venture capital firm RFC Ambrian, which together have invested AUD 15 million, the most that any CSIRO spin-off has ever received.
“RFC Ambrian identified that no one else in the world is deploying particle technologies into a startup company yet. So we’re the first. And their view is the first movers usually have greater success,” said Wil Gardner, former Team Leader of the Solar Thermal Engineering team at the CSIRO solar research unit who is now COO at FPR Energy.
The new firm is now looking for its first pre-commercial pilot project.
The heated particles are stored in a tall silo, holding thermal energy for as long as necessary. When needed, the stored heat is transferred via the hot particles to output heat exchangers.
Falling particle receiver technology has been developed collaboratively over years of international research, in many cases by government-funded scientists. These researchers advanced particle-based solar heat transfer at Sandia National Laboratories in the US, DLR in Germany, and CSIRO in Australia.
Scientists on two continents came up with the initial concept
“Through some discussion around 2016, 2017 I myself and Cliff Ho at Sandia, we found that what we are thinking is quite similar, so we decided to go for a joint patent for one of the basic concepts of the particle receiver design,” Kim noted.
“But since then, each research group working on particle receivers has conducted its own independent research and development with no actual sharing of IP. International collaboration is always a part of government projects, but it is more like linking existing or upcoming independent research projects and sharing information.”
CSIRO moved fastest to advance the falling particle receiver
The US Department of Energy selected particle-based solar technology early on for research as the future of concentrated solar thermal energy. In 2018, Sandia National Laboratories was awarded the DOE Gen-3 funding to advance it and is currently building their fully-integrated two-megawatt demonstration system on their construction site in the US.
But CSIRO in Australia had already been demonstrating a smaller one-megawatt system at its research centre in Newcastle.
“With ARENA funding through ASTRI (Australian Solar Thermal Research Institute), CSIRO has further developed that IP with additional features to improve that flow and heat retention capability. Our two patents back in 2020 and 2021 were directly just with CSIRO for the two heat exchangers (input solar receiver, and output heat extraction),” said Gardner, who had previous startup experience at Ausra, before joining CSIRO.
“The primary heat exchanger is the solar receiver, where you have direct contact heat exchange from solar radiation into the particle media. It was based on developing a particle flow in a cascade to limit the velocity and give the particles resident time to absorb the energy. The second heat exchanger, which extracts heat from storage, has features that no one else has done in this particular arrangement.”
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