Coupled neutronic/thermal-hydraulic hot channel analysis of high power density civil marine SMR cores

Alam, Syed Bahauddin; Oliveira, Rodrigo G.G. de; Goodwin, Cameron S.; Parks, Geoffrey T.

doi:10.1016/j.anucene.2018.12.031

Cited by 31 publications

(8 citation statements)

References 20 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…A higher enrichment was expected due to the lower UO 2 volume and the higher thermal neutron absorption of fertile 232 Th 11 . The use of duplex pellet designs also improves the ratio of neutron capture in fertile material to neutron absorption in fissile material which leads to an extended fuel burnup and core lifetime 11,57,58 . This has been demonstrated by previous work on duplex pellet utilization in PWR combined with axial pellet arrangement and checkboard rod configuration, which shows a 15% increase in burnup 14 .…”

Section: Thorium Seed‐and‐blanket Methodsmentioning

confidence: 78%

See 1 more Smart Citation

Review of the microheterogeneous thoria‐urania fuel for micro‐sized high temperature reactors

2020

View full text Add to dashboard Cite

Summary This paper presents a systematic review of the micro‐modular thorium‐fueled high temperature reactors (HTR) loaded with duplex fuel pellet design. Specifically, each unique criterion of the design is discussed separately in an attempt to understand the combined advantages of the proposed reactor. Micro modular HTRs have great potential as a source of electricity or industrial heat in the future. The use of thorium not only improves its economic performance and safety, but also prolongs its operation. Nevertheless, the traditional seed‐and‐blanket configuration would not be able to maximize the thorium fuel burnup. As such, a new tristructural‐isotopic (TRISO) fuel based on duplex pellet designs were proposed instead. It should be noted that these duplex pellets were not practical for pressurized water reactor (PWR) technology due to its uneven power distribution which possibly leads to a very high local pellet temperature. However, this unorthodox inherent characteristics of the duplex pellets may actually suit the HTR burnup profile better due to its substantially higher thermal margin ‐ thus possibly enabling a relatively long operation of the HTR. The paper shall thereby provide a reasonably sound justification for the detailed technical investigations of the proposed reactor design.

show abstract

Section: Thorium Seed‐and‐blanket Methodsmentioning

confidence: 78%

“…This indicates a higher breeding capacity, smaller core reactivity swing and longer core cycle 11 . The duplex is also used for the design of the SMR core with a high power density of 100 MW/m 3 58 …”

Section: Thorium Seed‐and‐blanket Methodsmentioning

confidence: 99%

Review of the microheterogeneous thoria‐urania fuel for micro‐sized high temperature reactors

2020

View full text Add to dashboard Cite

show abstract

“…• High power density SMR cores (Alam et al, 2019f) experience a core life penalty due to the associated reduction in fuel mass. Since this mixed coolant exhibits promise in offering longer core lifetime than the H 2 O coolant (Alam et al, 2019c), it has the potential to compensate this core life penalty.…”

Section: Discussionmentioning

confidence: 99%

Neutronic feasibility of civil marine small modular reactor core using mixed D2O+H2O coolant

Alam

Almutairi

Kumar

et al. 2020

Nuclear Engineering and Design

Self Cite

View full text Add to dashboard Cite

In an effort to decarbonize the marine sector, there are growing interests in replacing the contemporary, traditional propulsion systems with nuclear propulsion systems. The latter system allows freight ships to have longer intervals before refueling; subsequently, lower fuel costs, and minimal carbon emissions. Nonetheless, nuclear propulsion systems have remained largely confined to military vessels. It is highly desirable that a civil marine core not to use highly enriched uranium, but it is then a challenge to achieve long core lifetime while maintaining reactivity control and acceptable power distributions in the core. The objective of this study is to design a civil marine core type of single batch small modular reactor (SMR) with low enriched uranium (LEU) (<20% 235 U enrichment), a soluble-boron-free (SBF) and using mixed D 2 O+H 2 O coolant for operation period over a 20 years life at 333 MWth. Changing the coolant properties is the way to alter the neutron energy spectrum in order to achieve a self-sustaining core design of higher burnup. Two types of LEU fuels were used in this study: micro-heterogeneous ThO 2 -UO 2 duplex fuel (18% 235 U enriched) and all-UO 2 fuel (15% 235 U enriched). 2D Assembly designs are developed using WIMS and 3D whole-core model is developed using PANTHER code. The duplex option shows greater promise in the final burnable poison design with high thickness ZrB 2 integral fuel burnable absorber (IFBA) while maintaining low, stable reactivity with minimal burnup penalty. For the final poison design with ZrB 2 , the duplex contributes ∼2.5% more initial

show abstract

“…The major challenge for the micro-heterogeneous duplex fuel arrangements is to meet the thermal-hydraulic margins since the most severe situation will be in the duplex pellet case where most of the power is generated in the UO 2 part of the fuel pellet. In order to confirm that all the thermal-hydraulic constraints are satisfied for the duplex fuel, 3D neutronic/thermal-hydraulic coupling of hybrid monte carlo MONK with sub-channel analysis COBRA-EN (Basile, 1999) code for hot channel analysis (Alam et al, 2019d) has been performed to evaluate key TH parameters such as: minimum departure from nucleate boiling ratio (MDNBR), heat flux, cladding, inner surface and fuel centreline temperatures, and pressure drop. Our study confirmed that thermal-hydraulic design requirements for the duplex fuel can be met and there will be no melting in the UO 2 region of the duplex pellet.…”

Section: Practical Considerations For the Duplex Fuelmentioning

confidence: 99%

Small modular reactor core design for civil marine propulsion using micro-heterogeneous duplex fuel. Part II: whole-core analysis

Alam

Ridwan

Kumar

et al. 2019

Nuclear Engineering and Design

Self Cite

View full text Add to dashboard Cite

In an e↵ort to de-carbonise commercial freight shipping, there is growing interest in the possibility of using nuclear propulsion systems. In this reactor physics study, we seek to design a soluble-boron-free (SBF) and low-enriched uranium (LEU) (<20% 235 U enrichment) civil nuclear marine propulsion small modular reactor (SMR) core that provides at least 15 e↵ective full-power-years (EFPY) life at 333 MWth using 18% 235 U enriched micro-heterogeneous ThO 2 -UO 2 duplex fuel and 15% 235 U enriched homogeneously mixed all-UO 2 fuel. We use WIMS to develop subassembly designs and PANTHER to examine whole-core arrangements.The assembly-level behaviours of candidate burnable poison (BP) materials and control rods are investigated. We examine gadolinia (Gd 2 O 3 ), erbia (Er 2 O 3 ) and ZrB 2 integral fuel burnable absorber (IFBA) as BPs. We arrive at a design with the candidate fuels loaded into 13⇥13 assemblies using IFBA pins for reactivity control. Taking advantage of self-shielding e↵ects, this design maintains low and stable assembly reactivity with relatively little burnup penalty. Thorium-based duplex fuel o↵ers better performance than all-UO 2 fuel with all BP options considered. Duplex fuel has ⇠20% lower reactivity swing and, in consequence, lower initial reactivity than all-UO 2 fuel. The lower initial reactivity and smaller reactivity swing make the task of reactivity control through BP design easier in the thorium-rich duplex core. For control rod design, we examine boron carbide (B 4 C), hafnium, and Ag-In-Cd alloy. All the candidate materials exhibit greater rod worth for the duplex design. For both fuels, B 4 C has the highest rod worth. In particular, one of the major objectives of this study is to o↵er/explore a thorium-based candidate alternative fuel platform for the proposed marine core. It is proven by literature reviews that the ability of the duplex fuel was never explored in the context of a single-batch, LEU, SBF, long-life SMR core. In this regard, the motivation of this paper is to observe the neutronic performance of the proposed duplex fuel with respect to the UO 2 fuel and 'open the option' of designing the functional cores with both the duplex and UO 2 fuel cores.A companion paper will examine key physics and core safety analysis parameters in the whole-core environment.

show abstract

Coupled neutronic/thermal-hydraulic hot channel analysis of high power density civil marine SMR cores

Cited by 31 publications

References 20 publications

Review of the microheterogeneous thoria‐urania fuel for micro‐sized high temperature reactors

Review of the microheterogeneous thoria‐urania fuel for micro‐sized high temperature reactors

Neutronic feasibility of civil marine small modular reactor core using mixed D2O+H2O coolant

Small modular reactor core design for civil marine propulsion using micro-heterogeneous duplex fuel. Part II: whole-core analysis

Contact Info

Product

Resources

About