supercritical thermodynamics has been with us for two centuries and just now we are tackling using CO2. doing this has been obvious for a long time.
Two major gains. we gat a jump in thermodynamic efficiency from 40 % to 50 % or a real jump of 25%. We also get a thermal response time of minutes compared to an hour or so and this really matterrs for load resonse. this nicely competes with natural gas turbines.
The other giant gain is a massive loss in system mass. look at that picture and we are likely displacing a room sized machine. this is huge.
better late than never.
Supercritical CO2 pilot aims to make steam turbines obsolete
By Loz Blain
October 31, 2023
The 10 MW supercritical carbon dioxide turbine at the heart of the STEP pilot facility in Texas
Southwest Research Institute
Steam turbines still produce most of the world's power, but supercritical carbon dioxide promises to be much cheaper, and 10% more efficient as a medium than water, using 10X smaller turbines. A US$155-million pilot plant is now complete in San Antonio.
Ribbons were cut at the Supercritical Transformational Electric Power (STEP) pilot plant in Texas on October 27 as it was declared "mechanically complete" by project partners Southwest Research Institute (SwRI), GTI Energy, GE Vernova, and the U.S. Department of Energy.
The device in the image above is the world's first supercritical carbon dioxide turbine. Roughly the size of a desk, is a 10-megawatt turbine capable of powering around 10,000 homes. Ten megawatts is pretty small potatoes in the energy business, but to do it with a turbine this tiny? That could prove to be a revolutionary feat.
Carbon dioxide goes supercritical when the temperature and pressure are above about 31 °C (88 °F) and 74 bar (1,070 psi), respectively. At this point, it stops acting like a gas or a liquid, and instead starts acting something like a gas with the density of a liquid. Past this point, relatively small changes in temperature can cause significant changes in density.
Water can of course go supercritical too – it just takes a lot more energy, requiring a temperature and pressure over 373 °C (703 °F) and 220 bar (3,191 psi).
The STEP facility in San Antonio has been declared "mechanically complete" and is due for commissioning in 2024
Southwest Research Institute
The properties of this supercritical CO2 fluid make it ideal for energy extraction in a closed-loop system, and back in 2016, General Electric announced it would start building a pilot plant to prove the idea in a commercially relevant installation, expecting to achieve 10 MW at an extraction efficiency of 50% – around 10% better than current steam turbines, which operate in the mid-40s – using a turbine about one-tenth the size.
Such a turbine could significantly reduce the capital cost of setting up any power generator reliant on heat and turbines; not only will the smaller turbines be cheaper, but they're so much more compact that you'll need less land for a given power plant. It'd also produce more power from a given heat source, and by default reduce the per-unit carbon emissions even of coal and gas-based generators.
And on top of that, it'll be much faster to start up and switch on. Running at around 700 °C (1,292 °F), GE's prototypes take about two minutes to start generating, where steam turbines take at least half an hour. So these CO2 turbines will be much quicker to respond to load demands, making them even more useful in a renewables-based grid.
Once proven, the tech could scale up to utility-relevant sizes and start displacing steam turbines in power plants. That includes fossil-fueled plants, as well as certain nuclear, geothermal, concentrated solar, and other installations.
There's still work to go before the pilot plant is commissioned, but the consortium expects it'll start operating in 2024.
“STEP will undoubtedly change the way we think about power generation,” said SwRI President and CEO Adam Hamilton, in a press release. “It’s exciting to officially launch this pilot plant, which is home to potentially revolutionary technology developed right here at SwRI.”
Source: Southwest Research Institute
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