NREL investigates coatings needed for concentrating solar power

September 18, 2017, National Renewable Energy Laboratory
Researcher Judith Gomez-Vidal determined the coatings needed to allow concentrating solar power plants to store and use molten salts. Credit: Dennis Schroeder, NREL 45088

Next-generation concentrating solar power (CSP) plants require high-temperature fluids, like molten salts, in the range of 550-750 degrees Celsius to store heat and generate electricity. At those high temperatures, however, the molten salts eat away at common alloys used in the heat exchangers, piping, and storage vessels of CSP systems. New research at the U.S. Department of Energy's National Renewable Energy Laboratory (NREL) is aimed at mitigating corrosion levels in CSP plants with nickel-based coatings.

"We are very excited about the potential implications of this research to provide corrosion-resistant coatings for CSP applications that could improve the economic viability of these systems," said Johney Green, associate laboratory director for mechanical and thermal engineering sciences.

CSP plants with low-cost thermal storage enable facilities to deliver electricity whenever it is needed, helping to support grid reliability. Molten salts are commonly used for both the heat-transfer fluid and because they can withstand and retain the collected solar heat for many hours.

To commercially use molten salt mixtures containing sodium chloride, potassium chloride, and magnesium chloride, the corrosion rate in the storage tanks must be slow—less than 20 micrometers per year—so that a concentrating solar power plant can achieve a 30-year life.

Bare stainless steel alloys tested in a molten chloride corroded as fast as 4,500 micrometers per year. The solution to the corrosion problem could lie in research conducted by NREL's Judith Gomez-Vidal and published in the npj Materials Degradation journal article, "Corrosion Resistance of MCrAlX Coatings in a Molten Chloride for Thermal Storage in Concentrating Solar Power Applications."

Gomez-Vidal applied different types of nickel-based coatings, which are commonly used for reducing oxidation and corrosion, to stainless steel. One such , with the chemical formula NiCoCrAlYTa, showed the best performance so far. It limited the corrosion rate to 190 micrometers per year—not yet at the goal but a large improvement compared to the uncoated steel by a 96% reduction in the corrosion rate. That particular coating was pre-oxidized over a 24-hour period, during which a uniform and dense layer of aluminum oxide was formed and served to further protect the stainless steel from corrosion.

"The use of surface protection is very promising to mitigate corrosion in in particular to those surfaces exposed to chlorine-containing vapor," said Gomez-Vidal, who holds a Ph.D. in metallurgical and materials engineering. "However, the rates of corrosion are still considerably high for CSP. This effort highlights the relevance of testing materials durability in applications. More R&D is needed to achieve the target level needed, which could include the synergy of combining surface protection with chemical control of the molten salt and the surrounding atmosphere."

Additional tests will require evaluation of the coatings under thermal cycling and the introduction of oxygen-containing atmospheres to increase the oxidation potential of the systems. The addition of oxygen ensures the formation of protective scales that could reform in the presence of oxygen if cracks appear during operation. Gomez-Vidal has recently published other work in which such aluminum oxide layers were able to grow and remained adhered to the surface in the presence of air during thermal cycling of samples.

Explore further: New technique for investigating the action of molybdate on carbon steel

More information: Judith C. Gomez-Vidal. Corrosion resistance of MCrAlX coatings in a molten chloride for thermal storage in concentrating solar power applications, npj Materials Degradation (2017). DOI: 10.1038/s41529-017-0012-3

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Parsec
not rated yet Sep 19, 2017
Seems easier to me to change the coolant t6o something less corrosive. Is this particular combination of metal halides truly the best possible? Why?
antialias_physorg
not rated yet Sep 19, 2017
Salts can go to very high temperatures and can store the energy for a long time at very low cost (which is important, because the volume of salt in a concentrated solar power plant is considerable)

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