2011
DOI: 10.3327/jnst.48.344
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Electromagnetic Pumps for Main Cooling Systems of Commercialized Sodium-Cooled Fast Reactor

Abstract: An electromagnetic pump (EMP) has superior potential to improve the economic performance and ease of maintenance of sodium-cooled fast reactors. This study investigates the adequateness of a modular-type EMP system for large-sized (1,500 MWe class) sodium-cooled fast reactors. A flow rate of over 500 m 3 /min is required for the main circulating pump of such reactors. There is concern that such a large EMP will cause flow instability. A modular-type EMP system can solve this issue since smaller EMPs are arrang… Show more

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Cited by 2 publications
(4 citation statements)
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“…A study on electromagnetic pumps (EMPs) for the main cooling systems of a commercialized fast reactor 54 shows that this fluid velocity is compatible with the EMP technology, which is reported to achieve a fluid velocity higher than 10 m/second. The maximum and average fuel temperatures and the peak cladding temperature and several coolant parameters at BOC, MOC, and EOC are summarized in Table 8.…”
Section: Thermal-hydraulic Analysismentioning
confidence: 96%
See 1 more Smart Citation
“…A study on electromagnetic pumps (EMPs) for the main cooling systems of a commercialized fast reactor 54 shows that this fluid velocity is compatible with the EMP technology, which is reported to achieve a fluid velocity higher than 10 m/second. The maximum and average fuel temperatures and the peak cladding temperature and several coolant parameters at BOC, MOC, and EOC are summarized in Table 8.…”
Section: Thermal-hydraulic Analysismentioning
confidence: 96%
“…The velocity of the coolant is calculated according to Equation and equals 0.464 m/second (which is less than the design limit of 2 m/second retained in Table ): normalv=Pth.Hcp.m.T where P th is the thermal power, H is the active core height, c p is the specific heat, m is the total coolant mass, and ∆T is the temperature gap (assumed equal to 100 K). A study on electromagnetic pumps (EMPs) for the main cooling systems of a commercialized fast reactor shows that this fluid velocity is compatible with the EMP technology, which is reported to achieve a fluid velocity higher than 10 m/second.…”
Section: Performance Analysismentioning
confidence: 99%
“…Although they are sometimes less efficient, they are an attractive technology owing to their relatively small size and structural simplicity. As they do not contain bearings or moving parts, they require less routine maintenance than mechanical pumps [1]. In addition, the working fluid in the electromagnetic pump has no possibility of leakage because there is no sealing of parts where working fluids, such as sodium (Na), can react strongly with air.…”
Section: Introductionmentioning
confidence: 99%
“…In addition, a large-capacity sodiumimmersed self-cooled electromagnetic pump (LEMP) with a flow rate of 160 m 3 /min and a developed pressure of 0.28 MPa was designed, built, and tested [9,10]. Further, parallel-module ALIP systems were studied to consider the flow instability for flow rates over 500 m 3 /min [1].…”
Section: Introductionmentioning
confidence: 99%