Wear in particle based CSP systems from particle abrasion and attrition at high temperature Article Swipe

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Nipun Goel , Tessa Mei-lin Fong , John Shingledecker , Andrew Russell , Michael W. Keller , Siamack A. Shirazi , Todd Otanicar ·

YOU? · · 2021 · Open Access · · DOI: https://doi.org/10.2172/1807550

High temperature particle-based receivers offer distinct advantages over conventional molten salt receivers due to their ability to achieve temperatures above 700 ºC, direct absorption of solar energy as they fall through a beam of concentrated sunlight, and the relative ease of storage (and retrieval using a secondary working fluid) in insulated storage tanks. The use of particles, however, also raises concerns with material degradation from the flow of hot or cold particles through discharge hoppers or along the inner receiver surfaces and other system components (e.g. tubes, valves etc.), depending on operating mode of the receiver. The flow of particles over surfaces may result in loss of material from abrasive wear, impact erosion from impingement under gravitational fall and particle attrition as particles fall and move on top of each other. In the present study, the performance of candidate materials and particles were evaluated through a series of abrasion erosion and particle attrition experiments at room temperature as well as at 800 °C. Candidate materials were subject to abrasive wear from particles at low particle to material velocities inside a resistance heated kiln, and analyzed for changes in mass and surface morphology using cross-sectional scanning electron microscopy (SEM) and energy dispersive x-ray spectroscopy (EDS) tests. The wear rate for different specimens was noted to be largely driven by the strength of chromia scales built on the specimens from exposure to high temperature. Particle attrition measurements explored the susceptibility of particles to breakdown from particle to particle interaction and the generation of fines from this process. At the low velocities expected in particle based CSP plants, the particles tested exhibited near negligible breakdown. However, changes in the particle hardness at 800 ºC resulted in a significantly higher particle breakdown to sizes <40 microns raising potential environmental concerns. In addition to particle breakdown, it was also noted that the sample had oxides from the stainless steel test setup mixed in with the particles. Similar oxides can be expected to turn up in the utility scale particle based CSP plants as well. The presence of oxide was also noted to affect the solar absorptivity of the mixture compared to a clean initial specimen, potentially resulting in a change in the overall efficiency of the CSP plant.

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Abrasion (mechanical) Particle (ecology) Attrition Materials science Particle size Composite material Engineering Geology Chemical engineering Orthodontics Oceanography Medicine

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Type: article
Language: en
Landing Page: https://doi.org/10.2172/1807550
OA Status: green
Related Works: 10
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DOI: https://doi.org/10.2172/1807550

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Title: Wear in particle based CSP systems from particle abrasion and attrition at high temperature

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Language: en

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Publication year: 2021

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Publication date: 2021-04-19

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Authors: Nipun Goel, Tessa Mei-lin Fong, John Shingledecker, Andrew Russell, Michael W. Keller, Siamack A. Shirazi, Todd Otanicar

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Landing page: https://doi.org/10.2172/1807550

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Concepts: Abrasion (mechanical), Particle (ecology), Attrition, Materials science, Particle size, Composite material, Engineering, Geology, Chemical engineering, Orthodontics, Oceanography, Medicine

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abstract_inverted_index.hoppers	74
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abstract_inverted_index.exposure	228
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abstract_inverted_index.receivers	3, 11
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abstract_inverted_index.gravitational	116
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cited_by_percentile_year
countries_distinct_count	1
institutions_distinct_count	7
citation_normalized_percentile.value	0.27125948
citation_normalized_percentile.is_in_top_1_percent	False
citation_normalized_percentile.is_in_top_10_percent	False