Wärtsilä Works To ‘Future-Proof’ Engines With Hydrogen Research
05 May 2020
Wärtsilä is developing a combustion process for its gas engines to enable them to burn 100% hydrogen fuel.
The work is part of the company’s strategy to future-proof its engine technology in line with the global trend towards decarbonization of the energy and marine markets.
“The world is on a path towards 100% decarbonization, and Wärtsilä continues to support this trend with our research and development of future fuels, such as hydrogen,” said Marco Wiren, president, Wärtsilä Energy. “The market for hydrogen-fueled power plants will emerge along with regulations restricting the burning of fossil fuels. We are well-positioned to serve the power industry in its transition to 100% renewable electricity generation. Wärtsilä’s engines, capable of running on a variety of sustainable fuels, are offering a highly dynamic balancing power for these future generating systems.” Business.
Wärtsilä has researched hydrogen as a fuel for 20 years and has tested its engines with blends of up to 60% hydrogen and 40% natural gas. In addition to hydrogen, other potential renewable fuels are being studied for future applications, and Wärtsilä engines are already capable of combusting 100% synthetic carbon-neutral methane and methanol, the company said.
The company sees that during the energy sector’s transition to carbon neutrality, wind, solar, and battery storage will form an increasing share of power systems. There will, however, also be a need for renewable fuels to enable long-term storage in persistent low wind and solar weather conditions, the company said.
Such fuels will be burned in flexible, fast-starting power plants, and can be produced locally with curtailed wind and solar energy, using just water and air as the raw materials. Underground gas storage is used to store the gas for use during periods when reduced availability of renewables results in the battery storage being drained. The use of renewable fuels in flexible power plants dramatically reduces the required size of battery storage, improves power system efficiency, lowers generating costs, and provides high security of supply even during rare and unusual weather patterns.