An innovative nuclear reactor for electricity and desalination

Şahi̇n, Sümer; Şahi̇n, Hacı Mehmet; Al-Kusayer, Tawfik A.; Sefidvash, Farhang

doi:10.1002/er.1772

Cited by 28 publications

(23 citation statements)

References 6 publications

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“…The water vapor resulting from combustion (or electrochemical reaction) could then be condensed and purified by conventional water‐treatment technology to provide potable water. Such a cycle would of course need to be economically competitive with the conventional desalination approaches .…”

Section: Biotechnologymentioning

confidence: 99%

Green nanotechnology of trends in future energy: a review

Guo

2011

Int. J. Energy Res.

109

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It is well known that current fossil fuel usage is unsustainable and associated with greenhouse gas production. The amount of the world's primary energy supply provided by renewable energy technologies is urgently required. Therefore, the relevant technologies such as hydrogen fuel, solar cell, biotechnology based on nanotechnology, and the relevant patents for exploiting the future energy for the friendly environment are reviewed. At the same time, it is pointed out that the significantly feasible world's eco-energy for the foreseeable future should not only be realized, but also methods for using the current energy and their by-products more efficiently should be found correspondingly, alongside technologies that will ensure minimal environmental impact.

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Section: Biotechnologymentioning

confidence: 99%

Green nanotechnology of trends in future energy: a review

Guo

2011

Int. J. Energy Res.

109

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“…The development of the GEN‐IV nuclear reactors, including lead fast reactors, sodium fast reactors, and molten salt reactors, has been conducted worldwide, because they could potentially serve as future clean, safe, and massive energy sources by enhancing the utilization of uranium resources . The focuses of this generation are radioactive pollution minimization, reactor safety, and reactor size reduction . Small modular lead‐cooled fast reactors (SMLFRs) are among the alternatives satisfying these criteria, especially in safety, which requires the development of an entirely new approach based on heat removal by steady‐state natural circulation .…”

Section: Introductionmentioning

confidence: 99%

“…1 The focuses of this generation are radioactive pollution minimization, reactor safety, and reactor size reduction. [1][2][3] Small modular lead-cooled fast reactors (SMLFRs) are among the alternatives satisfying these criteria, especially in safety, which requires the development of an entirely new approach based on heat removal by steady-state natural circulation. 4 Natural circulation is used in the primary cooling system using lead-bismuth eutectic (LBE) coolant, which is composed of 44.5% lead and 55.5% bismuth at the full 100 MW t power of the reactor.…”

Section: Introductionmentioning

confidence: 99%

Development of innovative reactor-integrated coolant system design concept for a small modular lead fast reactor

Kwak

Kim

2018

Int J Energy Res

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Summary The report describes the development of an innovative magnetohydrodynamic (MHD) space‐integrated coolant system design concept for the small modular lead fast reactor called the ubiquitous, rugged, accident‐forgiving, nonproliferating, and ultralasting sustainer reactor. The coolant system efficiency was analyzed based on space‐integrated geometric and electromagnetic variables related to the circulation of lead‐bismuth eutectic (LBE) liquid metal coolant in a reactor with a thermal output of 100 MWt and using the MHD principle. The objective of the system is to optimize the circulation of the noncontacting liquid metal coolant without any internal structure, such as an impellor or sealing part, to transport the LBE with high electrical conductivity in the reactor. The concept was first applied to the pool‐type integral leading facility for lead‐alloy cooled advanced small modular reactor, which serves as a scaled‐down experimental facility for the ubiquitous, rugged, accident‐forgiving, nonproliferating, and ultralasting sustainer reactor, for characteristic analysis of the coolant system subject to the requirements of a developed pressure of 8456 Pa and a mass flow rate of 21.37 kg/second. The MHD core blanket, which was attached to the upper part of the pool‐type integral leading facility for lead‐alloy cooled advanced small modular reactor and wrapped it cylindrically from the outside to form an annular passage, was designed for the forced circulation of liquid LBE taking into account its internal space and the high operating temperature of 440°C. Design variable analysis provided the optimized geometric and electromagnetic parameters of the MHD driving system based on the electromagnetic characteristics in the coolant passage of the reactor. This forced cooling system concept based on MHD propulsion is structurally simple and will enable significant space reduction and increased power for small modular lead fast reactors. It was also determined that safe long‐term reactor operation could be ensured without requiring particular maintenance because the operation does not involve fluid contact.

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“…A conceptual design of a super-safe, small, and simple (4S) reactor was proposed by Toshiba Corp. and CRIEPI to meet design criteria such as negative temperature feedback reactivity coefficients including sodium void worth and a core lifetime longer than 10 years [9]. On the other hand, the SMR concept provides flexibility in design, siting, and the fuel cycle option, and it can be transported from the prelicensed factories to the remote plant sites [11][12][13]. On the other hand, the SMR concept provides flexibility in design, siting, and the fuel cycle option, and it can be transported from the prelicensed factories to the remote plant sites [11][12][13].…”

Section: Introductionmentioning

confidence: 99%

Design study of long-life small modular sodium-cooled fast reactor

Park

Tak

Kim

et al. 2016

Int. J. Energy Res.

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Summary This paper presents a new design for a small modular sodium‐cooled fast reactor core with an optimized lifetime and reactivity swing through the analysis of various breed‐and‐burn strategies and its neutronic analyses in terms of active core movements, isotopic mass balance, kinetic parameters, and inherent safety. The new core design aims at a power level of 260 MW with a long lifetime of 30 years without refueling and a reactivity swing smaller than 1000 pcm. Starting from five initial candidate cores with various breed‐and‐burn strategies, an optimum core was selected from a combination of the two candidates that shows a proper breeding behavior with the optimized uranium enrichment in the low‐enriched uranium region and the optimized size of the blanket region. The depletion analysis of the new core provides various reactor design parameters such as the core multiplication factor, breeding ratio, heavy metal mass change, power distribution, and summary of neutron balance. In addition, the perturbation analysis provides the reactor kinetic parameters and reactivity feedback coefficients for the inherent safety analysis of the core. The integral reactivity parameters of the quasi‐static reactivity balance analysis demonstrate that the new core is inherently safe in cases of unprotected loss of flow, unprotected loss of heat sink, and unprotected transient over power. Copyright © 2016 John Wiley & Sons, Ltd.

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An innovative nuclear reactor for electricity and desalination

Cited by 28 publications

References 6 publications

Green nanotechnology of trends in future energy: a review

Green nanotechnology of trends in future energy: a review

Development of innovative reactor-integrated coolant system design concept for a small modular lead fast reactor

Design study of long-life small modular sodium-cooled fast reactor

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