Wärtsilä joins new consortium to explore hydrogen-argon power cycle for net-zero power generation
27 November 2024
Technology group Wärtsilä is part of a new research project exploring innovative technology for cleaner, more energy-efficient engines utilizing a closed loop combustion cycle. The research will focus on the use of argon—a non-toxic ideal gas present in the atmosphere—to increase efficiency of balancing engines.
The co-innovation project is run by the Integrated Hydrogen-Argon Power Cycle (iHAPC) consortium, led by the University of Vaasa, in partnership with Business Finland and a wide network of partners.
In an internal combustion engine, the energy supplied by combusting fuel is directly converted into mechanical power by the controlled combustion of the fuel in an enclosed space. In the Argon Power Cycle, air, which is normally used to combust the fuel in an internal combustion engine, is now replaced by argon and oxygen. The research focuses on scaling up the Argon Power Cycle to medium-speed engines with full argon recovery. Argon enables a considerably higher thermodynamic efficiency due to its properties.
The principle of Argon Power Cycle (APC) with hydrogen as the fuel. Wang et al.
When using hydrogen, oxygen and argon as input the only product from the process is water and the inert argon. Argon is recycled from exhaust to inlet forming a closed loop combustion cycle. Hydrogen and oxygen, the only inputs in the integrated Hydrogen Argon Power Cycle, are both products of electrolysis, which increases the overall efficiency of the power-to-hydrogen-to-power process.
Balancing engines are a vital component of the transition to renewable energy systems, providing essential power to balance intermittent wind and solar power and ensure grid stability. The most efficient engines run on gas today but are ready to be converted to sustainable fuels such as hydrogen when they are available at scale. With sustainable fuel production forecast to reach 38 million tonnes by 2030 (a third more than current demand) this transition is expected to be possible within the next decade.
The three-year project is part of the WISE (Wide and Intelligent Sustainable Energy) program, led by Wärtsilä and funded by Business Finland, the official government agency for trade, investment promotion and innovation funding. The partners of the iHAPC project are University of Vaasa, University of Oulu, VTT Technical Research Centre of Finland, Parker Hannifin Manufacturing Finland Oy, Vahterus Oy, Vaisala Oyj and TotalEnergies.
Resources
Wang, Chenxu & Jin, Shaoye & Deng, Jun & Ding, Weiqi & Tang, Yongjian & Li, Liguang. (2023). Future High-Efficiency and Zero-Emission Argon Power Cycle Engines: A Review. International Journal of Automotive Manufacturing and Materials. 2. doi: 10.53941/ijamm.2023.100002.
There is no NOX because there's no nitrogen from the air you could get the oxygen from electrolysis of water this is a very interesting development.
Posted by: SJC | 27 November 2024 at 01:31 PM
Obtaining pure O2 seems like a cost adder and difficult in any mobile application.
Posted by: Steve Reynolds | 28 November 2024 at 01:49 PM
They could get it from the air they could get it from the sea water as long as you're making hydrogen and you're going to use electrolysis you liquefy the oxygen no problem
Posted by: SJC | 28 November 2024 at 01:56 PM
Interesting research project but I wonder about the economics. If this is for larger ships, I think it is time to take another look at nuclear power.
Posted by: sd | 29 November 2024 at 07:29 PM
Ships could use LNG and SOFC
Posted by: SJC | 01 December 2024 at 12:00 AM
SJC wrote: "Ships could use LNG and SOFC"
OK, what happens to the carbon in the natural gas (methane or CH4)? I would guess that it just ends up as CO2. So why not just burn the methane?
Posted by: sd | 01 December 2024 at 12:36 PM
You store the CO2 out of the SOFC you compress it and bring it back to Port then recycle into synthetic methane using renewable hydrogen.
Posted by: SJC | 02 December 2024 at 02:57 PM