Design Summary of the Mark-I Pebble-Bed, Fluoride Salt–Cooled, High-Temperature Reactor Commercial Power Plant

Andreades, Charalampos; Cisneros, Anselmo T.; Choi, Jeongmoon J.; Chong, Alexandre Y. K.; Fratoni, Massimiliano; Hong, S. K.; Huddar, Lakshana; Huff, Kathryn D.; Kendrick, James; Krumwiede, D. L.; Laufer, Michael; Munk, Madicken; Scarlat, Raluca O.; Zweibau, Nicolas

doi:10.13182/nt16-2

Cited by 106 publications

(64 citation statements)

References 8 publications

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“…The analysis was conducted for thermal storage integration with existing and future generation NPPs based on the plant design data from literature (Doster et al, 2012;Ball, 2004;Andreades and Peterson, 2014). The study reveals that there are various possible options to store thermal energy of next generation NPPs efficiently, but the options for existing NPPs are limited.…”

Section: Resultsmentioning

confidence: 99%

“…The PB-FHR design is a 236 MW (th) reactor system, with a corresponding electrical power rating of 100 MW(e) at the base-load operation. Operating conditions and RC properties are provided in Table 2 for the PB-FHR (Andreades and Peterson, 2014). Similar to design philosophy of the two reactors described above, all the RC system components remain within the containment and TES layout will be outside the reactor building.…”

Section: Pebble-bed Fluoride-salt-cooled High-temperature Reactormentioning

confidence: 99%

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Exergy analysis of thermal energy storage options with nuclear power plants

Edwards

Bindra

Sabharwall

2016

Annals of Nuclear Energy

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a b s t r a c tStoring excess thermal energy in a storage media, that can later be extracted during peak-load times is one of the better economic options for nuclear power in future. Thermal energy storage integration with light-water cooled and advanced nuclear power plants is analyzed to assess technical feasibility of different options. Various choices of storage media considered in this study include molten salts, synthetic heat transfer fluids, and packed beds of solid rocks or ceramics. Due to limitations of complex process conditions and safety requirements there are only few combinations which have potential integration possibilities. In-depth quantitative assessment of these integration possibilities are then analyzed using exergy analysis and energy density models. The exergy efficiency of thermal energy storage systems is quantified based on second law thermodynamics. This study identifies, examines, and compares different energy storage options for integration with modular NPPs, with the calculated values of energy density and exergy efficiency. The thermal energy storage options such as synthetic heat transfer fluids perform well for light-water cooled NPPs, whereas liquid storage salt show better performance with advanced NPPs as compared to other options.

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Section: Resultsmentioning

confidence: 99%

Section: Pebble-bed Fluoride-salt-cooled High-temperature Reactormentioning

confidence: 99%

Exergy analysis of thermal energy storage options with nuclear power plants

Edwards

Bindra

Sabharwall

2016

Annals of Nuclear Energy

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“…However, the project did not result in actually building and operating an HTGR. In the case of energy neutral mineral processing, though it may be realized, HTGRs could be the first choice over other emerging HTR technology [131][132][133], such as the compact high temperature reactor (CHTR) [134,135], fluoride salt-cooled, high-temperature reactor (FHR) [136][137][138][139], gas-cooled fast reactor (GFR) [140][141][142], lead-cooled fast reactor (LFR) [143][144][145], molten salt reactor (MSR) [146] and others that may deliver process heat at temperatures higher than or equal to 600 °C. Five countries: Great Britain, the U.S., Germany, Japan and China have experience with operating and thus licensing HTGRs.…”

Section: Identified Challengesmentioning

confidence: 99%

On the Sustainability and Progress of Energy Neutral Mineral Processing

et al. 2018

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A number of primary ores such as phosphate rock, gold-, copper-and rare earth ores contain considerable amounts of accompanying uranium and other critical materials. Energy neutral mineral processing is the extraction of unconventional uranium during primary ore processing to use it, after enrichment and fuel production, to generate greenhouse gas lean energy in a nuclear reactor. Energy neutrality is reached if the energy produced from the extracted uranium is equal to or larger than the energy required for primary ore processing, uranium extraction, -conversion, -enrichment and -fuel production. This work discusses the sustainability of energy neutral mineral processing and provides an overview of the current progress of a multinational research project on that topic conducted under the umbrella of the International Atomic Energy Agency.

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“…Few experiments can be adopted to validate the modified Relap5 Mod3 in simulating the transient responses of FHRs or the fluoride salt systems. The Mark1 pebble bed fluoride‐salts‐cooled high‐temperature reactor (MK1 PB‐FHR) preconceptual design has been preliminarily finished in the University of California, Berkeley . The MK1 PB‐FHR is aimed at providing a detailed design for passive residual heat removal system and increasing the inherent safety characteristics of FHRs.…”

Section: Benchmark and Application Of The Modified Relap5 Mod3 Codementioning

confidence: 99%

“…The Mark1 pebble bed fluoride-salts-cooled high-temperature reactor (MK1 PB-FHR) preconceptual design has been preliminarily finished in the University of California, Berkeley. 47 The MK1 PB-FHR is aimed at providing a detailed design for passive residual heat removal system and increasing the inherent safety characteristics of FHRs. Zweibaum et al 6 built a thermal-hydraulic model of MK1 PB-FHR and performed a transient analysis on the protected loss of forced cooling (PLOFC) accident using the INL-developed Relap5-3D.…”

Section: Mark1 Pebble Bed Fluoride-saltscooled High-temperature Reamentioning

confidence: 99%