Co-founders of MGA Thermal, Dr Alex Post and Professor Erich Kisi
Co-founders of MGA Thermal, Dr Alex Post and Professor Erich Kisi

The missing block to build an all-renewable electric grid

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Peer-reviewed: This work was reviewed and scrutinised by relevant independent experts.

A new type of thermal storage material, housed in blocks like LEGO®, could see coal-fired power stations converted to run entirely fossil-fuel free. Coined Miscibility Gaps Alloy (MGA), the extraordinary blocks are capable of receiving energy generated by renewables, storing it cheaply and safely as thermal energy, then using it to run steam turbines at power stations instead of burning coal.

Organisation/s: The University of Newcastle

Funder: Australian Government Department of Industry, Innovation and Science Accelerating Commercialisation Grant

Media release

From: The University of Newcastle

A new type of thermal storage material, housed in blocks like LEGO®, could see coal-fired power stations converted to run entirely fossil-fuel free.

Coined Miscibility Gaps Alloy (MGA), the extraordinary blocks are capable of receiving energy generated by renewables, storing it cheaply and safely as thermal energy, then using it to run steam turbines at power stations instead of burning coal.

Patented by the University of Newcastle, a team of engineers spent years perfecting the innovation to effectively and affordably store thermal energy.  Their solution – 20cm x 30cm x 16cm blocks – can be retrofitted to retired power plants or introduced to existing power plants to help them transition from fossil fuels to renewables. Stackable like LEGO®, MGA blocks can be added or removed to scale the system up or down to meet market demand.

University of Newcastle Materials Scientist and lead researcher, Professor Erich Kisi, said the innovation enabled renewable energy to be used as reliable baseload power – providing a sought-after solution to transition from fossil fuels to renewable technology whilst maintaining existing infrastructure and associated workforces.

“We’re aiming to bridge the gap between cheap and abundant renewable energy, which is generated in peaks, and the ability to store and dispatch energy at any time of day or night, to meet consumer needs.”

“Unlike coal-fired power, which is regulated and controlled, renewable energy is a challenge because it is less predictable and inconsistent. The grid, which includes the poles and wires you see on streets connecting to houses and buildings, was not designed to receive large spikes associated with renewable energy,” Professor Kisi said.

“Redesigning the whole grid is simply too expensive so we’ve created MGA as an energy storage solution to marry with existing infrastructure.  We’ve made renewable energy compatible at grid-scale so that when the Sun doesn’t shine or wind drops the grid still delivers power on-demand.”

A boost for Australian manufacturing

With close to $1million combined funding from CP Ventures and an Australian Government Department of Industry, Innovation and Science Accelerating Commercialisation Grant, the MGA Thermal team are establishing a NSW-based manufacturing plant to scale production of their modular blocks to commercial levels.

Professor Kisi said the manufacturing facility would immediately create several full-time jobs.

“There’s potential for a whole new local industry, manufacturing high value thermal storage material for renewable energy projects,” said Professor Kisi.

“Our location in the Hunter is ideal. The region has a background as a strong centre for industry and there’s great access to raw materials.”

CP Ventures Co-Managing Partner, Emlyn Scott, said the MGA technology was unique in its key capabilities and scalability in large-scale energy storage.

“What’s really exciting is that as a viable energy storage solution it represents the missing component to renewable energy. We believe it has the potential to change the world,” Mr Scott said.

Safe and low cost

Professor Kisi said people often likened the MGA block to a battery as they both stored energy, however the MGA blocks were far cheaper, safer, lasted much longer and were more scalable than a battery.

“We’ve sourced abundant and readily available starting ingredients for our block so that it can be produced at a very low cost to accommodate for the scale of energy storage that’s required - they are 10 per cent of the cost of a lithium battery of the same size, yet produce the same amount of energy,” Professor Kisi said.

Able to store millions of kilowatt hours of energy, Professor Kisi said the technology was superior to existing solutions, enabling super-fast charging of the system.

“It offers near to 100 per cent conversion of electricity to heat and the lowest levelised cost of storing electricity - a measure of the total lifecycle cost of a facility compared to the amount of energy it is capable of storing.”

The blocks are made from non-toxic, 100 per cent recyclable material so there is no risk of explosion or combustion in hazardous environments.

How does MGA work?

Made from materials with high thermal conductivity, MGA blocks work by storing heat energy.

Professor Kisi said the source of that energy could be concentrated heat directly from the Sun, surplus electricity on the grid, renewable energy, or from industrial heat or waste heat.

“The MGA blocks are made of two components. One component melts when heated to store huge amounts of energy, and the other acts as a matrix, keeping the block in solid form and embedding the melting particles,” Professor Kisi said.

Engineering PhD student, Mark Copus, who is working on the project, likened the process to a choc-chip muffin being heated in the microwave.

“Imagine the matrix is the cake component, which holds everything in shape when heated and rapidly distributes that heat. The other particles, represented by the choc-chips, melt and store thermal energy through the solid to liquid change phase,” Mark said.

“This process of heating, storing energy, cooling and recovering energy can be repeated thousands of times in an MGA block.”

MGA blocks are capable of not only storing energy, but also heating water to form steam.

“The blocks can be designed with internal tubing or interact with other heat exchangers so that when water is pumped in, superheated steam is formed.  Much like a traditional coal-fired power station, the steam is then used to run turbines and generators,” Professor Kisi said.

European partnership

With more than 6,600 coal-fired power stations still operating around the world, Professor Kisi said the modular scalability of MGA blocks was ideal to help power stations gradually transition to coal-free operation.

“Emissions from coal-fired power plants account for the single largest source of greenhouse gases that cause global warming.  Transitioning coal-fired power plants is a win-win to deliver clean baseload power, while also helping to prevent job loss from power plant closures,” Professor Kisi said.

MGA Thermal has partnered with Swiss company, E2S Power AG, to design a technology to retrofit and repurpose retired and active coal-fired plants in Europe using MGA blocks.  E2S brings extensive power engineering expertise as well as their own patented IP and proprietary knowledge to the project.

Professor Kisi said the partnership paves the way to leverage trillions of dollars of stranded assets globally that are already decommissioned, or set to be.

“The cost of decommissioning a power plant is incredibly high, so their life-cycle management is a huge challenge. MGA blocks are an opportunity to re-deploy retired or stranded plants, turning a liability into a high value asset,” said Professor Kisi.

Full steam ahead

Professor Kisi and his team have established spin-out company MGA Thermal to continue to commercialise their MGA block technology licensed to it by the University. The company participated in the University of Newcastle’s Integrated Innovation Network (I2N) “Incubator Program”, that assists new ventures with the connections to business community, customers and capital.

Director at the University of Newcastle’s Knowledge Exchange and Enterprise, Dr Darren Cundy, said MGA Thermal was a tangible example of ground-up research migrating its way to market and delivering value for people and the planet.

“We are particularly pleased to see our researchers directly involved in the company taking a solution that could totally transform how we use renewables.  Their work is driving regional growth and opportunity - starting local but thinking global,” Dr Cundy said.

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LEGO® is a trademark of the LEGO Group of companies which does not sponsor, authorise or endorse this content.

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