Low enriched uranium and thorium fuel utilization under once‐through and offline reprocessing scenarios in small modular molten salt reactor

Zhu, Guifeng; Zou, Yang; Yan, Rui; Tan, Meng-Lu; Zou, Chunyan; Kang, Xuzhong; Chen, Jingen; Dai, Ye

doi:10.1002/er.4676

Cited by 24 publications

(20 citation statements)

References 29 publications

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“…Small modular‐MSRs 18‐20 are small power level MSRs combined with modular technology for multi‐purposed applications, such as electricity generation, seawater desalination, hydrogen production, supply of supercritical steam for industrial use, and the production of medical radionuclides. One of the modular philosophies is to integrate the high radioactive primary loop into a power module with advantages of easy transportation, assembly, and disassembly in remote regions.…”

Section: Small Modular Molten Salt Reactorsmentioning

confidence: 99%

“…Compared with the fuel salt channel in the center of one prismatic graphite block, this structure benefits the lateral connection between channels and block gaps, and further favors the heat conduction from narrow gaps. The salt VF in active core is near 10% according to the analysis of fuel utilization and TRC 18 . As a result, even a 3% averaged volume shrink of graphite will have an about 30% volume increase of fuel salt in active core.…”

Section: Small Modular Molten Salt Reactorsmentioning

confidence: 99%

“…In addition, the spatially dependent change of fuel salt may make power density distribution more centralized and hence reduce the time interval between graphite replacements. Those phenomena could be significant in small modular MSR (SM‐MSR), 18‐20 in which the best fuel salt VF in active core is only about 10%, lower than ~20% VF in MSBR. Therefore, it is necessary to take the dimensional change into account either in neutronic or thermal‐hydraulic analysis.…”

Section: Introductionmentioning

confidence: 99%

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Neutronic effect of graphite dimensional change in a small modular molten salt reactor

et al. 2020

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Summary Graphite is an excellent moderator widely used in fission nuclear reactors. However, the component dimensions and physical properties of graphite will be apparently affected by neutron radiation during the reactor operation. In molten salt reactors (MSRs), graphite dimensional change will not only cause the structural integrity issue, but also have obvious impacts on neutronic and thermal‐hydraulic behaviors due to the volume fraction (VF) change of fuel salt in the active core. Considering these effects synthetically, we have developed a multi‐physical coupling burnup code, including fuel management, neutron transportation, thermal‐hydraulic calculation, and dimensional change. Then we analyze the effects of graphite dimensional change in a small modular MSR (SM‐MSR). It can be concluded that the averaged shrink ratio of graphite in SM‐MSR is about 1.0% ΔL/L at the end of life while the lifespan of graphite can be more than 10 years with 66 MW/m3 power density. Although the dimensional change has a little effect on the neutronic properties, such as fuel burnup and temperature reactivity coefficients because of the limited change of averaged fuel salt VF from 10% to less than 12%, the local distributions, such as power density, temperature, mass flow, and fast neutron flux, have been affected by 10% to 30%, which cannot be neglected in practical engineering design. Finally, we have compared the fuel burnup and lifespan of graphite under different sizes of graphite components, and we recommend that the distance across flats of graphite block should be limited between 10 and 20 cm.

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Section: Small Modular Molten Salt Reactorsmentioning

confidence: 99%

Section: Small Modular Molten Salt Reactorsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Neutronic effect of graphite dimensional change in a small modular molten salt reactor

et al. 2020

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“…With many remarkable characteristics such as inherent safety, excellent neutron economy, no fuel fabrication, online refueling and reprocessing, and so on, MSR can attain high burnup and is considered to have the ability to operate in a thorium–uranium fuel cycle and the potential to burn transuranic elements 16‐19 . Up to now, many different types of MSR have been designed to serve as the burner, converter, or breeder in any of the thermal, epithermal, or fast spectrum reactors using enriched U‐235, U‐233, or transuranic elements as the fissile fuel 20‐24 . In 2011, China initiated a pioneer program of research and development (R&D) for thorium‐based molten salt reactors (TMSRs) at the Shanghai Institute of Applied Physics, Chinese Academy of Science (SINAP, CAS) 25,26 .…”

Section: Introductionmentioning

confidence: 99%

Parametric study on minor actinides transmutation in a graphite‐moderated thorium‐based molten salt reactors

Zou

et al. 2021

Int J Energy Res

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Summary Transmutation of minor actinides (MAs) is an effective solution to reduce the long‐term radiotoxicity of nuclear waste. Online refueling and no fuel rod fabrication in thorium‐based molten salt reactors (TMSR) are two remarkable advantages of MA transmutation. However, MA solubility limit of the fuel salt and the neutron spectrum in the core are two key parameters that have a strong impact on MA transmutation capability. In this paper, three types of carrier salt with different MA solubility limits and various salt volume fractions (SVFs) are introduced in a TMSR core to evaluate the MA transmutation characteristics. The results indicate that the Flibe salt with the best neutron economy can obtain the highest MA transmutation rate (TR), while the Flinak salt with the largest MA inventory can achieve the highest specific MA transmutation consumption (STC). STC and TR for the case with the Flibe salt and 5% SVF are about 200 kg/GWth.yr and 82%, respectively, which indicates that it can consume the annual MA yields from about 3.37 typical pressurized water reactors (PWRs). Meanwhile, the STC and TR for the case with the Flinak salt and 40% SVF are about 366 kg/GWth.yr and 75%, respectively, which indicates that it can consume the annual MA yields from about 50 typical PWRs. In addition, the total radiotoxicity of MAs after 50‐year operation in TMSR can be lowered by as high as about 50%. The significant production of Pu isotopes can be reused as nuclear fuel in fast reactors. In particular, Pu‐238, with the mass fraction of more than 60% in Pu isotopes, is a useful material for many nuclear applications. In conclusion, it is feasible to transmute MAs in TMSR and thus achieve the goals of reduction of MA's long‐term radioactive hazards.

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“…With the development of nuclear energy, the utilization of thorium has been discussed in various types of reactors with varying intensity, particularly in pressurized water reactors (PWRs), boiling water reactors, heavy water reactors, Canadian deuterium natural uranium reactors, molten salt reactors (MSRs), hybrid systems, accelerator‐driven systems, high temperature reactors (HTRs), breeder reactors, as well as in fast reactors . Thorium has gained considerable amount of interest because of its many advantages that;characterize it as fuel.…”

Section: Introductionmentioning

confidence: 99%

Comparison of homogeneous and heterogeneous thorium fuel blocks with four drivers in advanced high temperature reactors

et al. 2020

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Thorium is an attractive potential fuel owing to its abundance and unique thermal, neutronic, and chemical properties. One way to utilize thorium in block-type advanced high temperature reactors (AHTRs) is to homogenously mix the driver fuel (eg, U-233) with thorium in every fuel kernel of the tristructural-isotropic particles in a fuel block, which is the mixed oxide fuel (MOX) concept. Application of the seed and blanket (S&B) concept, that is, driver fuel in the seed region of a fuel block and thorium in the blanket region, is also another method to utilize thorium. To investigate the differences in the utilization of thorium using the MOX and S&B concepts in AHTRs, their multiplication factors (k ∞ ), discharge burnups, conversion ratios, and reactivity temperature coefficients are compared. The investigated drivers include U-233 (U3), weapons-grade uranium (WU), weapons-grade plutonium (WPu), and reactor-grade plutonium (RPu). The results demonstrate that the MOX block with plutonium drivers has a higher discharge burnup in comparison with the S&B block. When the heavy metal mass is 6 kg and the initial mass of the fissile materials is 0.65 kg per block, the MOX block achieves 27% higher discharge burnup than the S&B block with the RPu driver. In contrast, the S&B block achieves higher discharge burnup in the case of uranium drivers (U3 and WU). The MOX block achieves a higher conversion ratio for all the drivers. Furthermore, the MOX block achieves a stronger negative moderator temperature coefficient of reactivity than the S&B block for all the driver fuels.

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Low enriched uranium and thorium fuel utilization under once‐through and offline reprocessing scenarios in small modular molten salt reactor

Cited by 24 publications

References 29 publications

Neutronic effect of graphite dimensional change in a small modular molten salt reactor

Neutronic effect of graphite dimensional change in a small modular molten salt reactor

Parametric study on minor actinides transmutation in a graphite‐moderated thorium‐based molten salt reactors

Comparison of homogeneous and heterogeneous thorium fuel blocks with four drivers in advanced high temperature reactors

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